Tag Archives: Amazon QuickSight

Amazon S3 Storage Lens adds performance metrics, support for billions of prefixes, and export to S3 Tables

2025-12-02 Veliswa Boya

Post Syndicated from Veliswa Boya original https://aws.amazon.com/blogs/aws/amazon-s3-storage-lens-adds-performance-metrics-support-for-billions-of-prefixes-and-export-to-s3-tables/

Today, we’re announcing three new capabilities for Amazon S3 Storage Lens that give you deeper insights into your storage performance and usage patterns. With the addition of performance metrics, support for analyzing billions of prefixes, and direct export to Amazon S3 Tables, you have the tools you need to optimize application performance, reduce costs, and make data-driven decisions about your Amazon S3 storage strategy.

New performance metric categories
S3 Storage Lens now includes eight new performance metric categories that help identify and resolve performance constraints across your organization. These are available at organization, account, bucket, and prefix levels. For example, the service helps you identify small objects in a bucket or prefix that can slow down application performance. This can be mitigated by batching small objects or using the Amazon S3 Express One Zone storage class for higher performance small object workloads.

To access the new performance metrics, you need to enable performance metrics in the S3 Storage Lens advanced tier when creating a new Storage Lens dashboard or editing an existing configuration.

Metric category	Details	Use case	Mitigation
Read request size	Distribution of read request sizes (GET) by day	Identify dataset with small read request patterns that slow down performance	Small request: Batch small objects or use Amazon S3 Express One Zone for high-performance small object workloads
Write request size	Distribution of write request sizes (PUT, POST, COPY, and UploadPart) by day	Identify dataset with small write request patterns that slow down performance	Large request: Parallelize requests, use MPU or use AWS CRT
Storage size	Distribution of object sizes	Identify dataset with small small objects that slow down performance	Small object sizes: Consider bundling small objects
Concurrent PUT 503 errors	Number of 503s due to concurrent PUT operation on same object	Identify prefixes with concurrent PUT throttling that slow down performance	For single writer, modify retry behavior or use Amazon S3 Express One Zone. For multiple writers, use consensus mechanism or use Amazon S3 Express One Zone
Cross-Region data transfer	Bytes transferred and requests sent across Region, in Region	Identify potential performance and cost degradation due to cross-Region data access	Co-locate compute with data in the same AWS Region
Unique objects accessed	Number or percentage of unique objects accessed per day	Identify datasets where small subset of objects are being frequently accessed. These can be moved to higher performance storage tier for better performance	Consider moving active data to Amazon S3 Express One Zone or other caching solutions
FirstByteLatency (existing Amazon CloudWatch metric)	Daily average of first byte latency metric	The daily average per-request time from the complete request being received to when the response starts to be returned
TotalRequestLatency (existing Amazon CloudWatch metric)	Daily average of Total Request Latency	The daily average elapsed per request time from the first byte received to the last byte sent

How it works
On the Amazon S3 console I choose Create Storage Lens dashboard to create a new dashboard. You can also edit an existing dashboard configuration. I then configure general settings such as providing a Dashboard name, Status, and the optional Tags. Then, I choose Next.

Next, I define the scope of the dashboard by selecting Include all Regions and Include all buckets and specifying the Regions and buckets to be included.

I opt in to the Advanced tier in the Storage Lens dashboard configuration, select Performance metrics, then choose Next.

Next, I select Prefix aggregation as an additional metrics aggregation, then leave the rest of the information as default before I choose Next.

I select the Default metrics report, then General purpose bucket as the bucket type, and then select the Amazon S3 bucket in my AWS account as the Destination bucket. I leave the rest of the information as default, then select Next.

I review all the information before I choose Submit to finalize the process.

After it’s enabled, I’ll receive daily performance metrics directly in the Storage Lens console dashboard. You can also choose to export report in CSV or Parquet format to any bucket in your account or publish to Amazon CloudWatch. The performance metrics are aggregated and published daily and will be available at multiple levels: organization, account, bucket, and prefix. In this dropdown menu, I choose the % concurrent PUT 503 error for the Metric, Last 30 days for the Date range, and 10 for the Top N buckets.

The Concurrent PUT 503 error count metric tracks the number of 503 errors generated by simultaneous PUT operations to the same object. Throttling errors can degrade application performance. For a single writer, modify retry behavior or use higher performance storage tier such as Amazon S3 Express One Zone to mitigate concurrent PUT 503 errors. For multiple writers scenario, use a consensus mechanism to avoid concurrent PUT 503 errors or use higher performance storage tier such as Amazon S3 Express One Zone.

Complete analytics for all prefixes in your S3 buckets
S3 Storage Lens now supports analytics for all prefixes in your S3 buckets through a new Expanded prefixes metrics report. This capability removes previous limitations that restricted analysis to prefixes meeting a 1% size threshold and a maximum depth of 10 levels. You can now track up to billions of prefixes per bucket for analysis at the most granular prefix level, regardless of size or depth.

The Expanded prefixes metrics report includes all existing S3 Storage Lens metric categories: storage usage, activity metrics (requests and bytes transferred), data protection metrics, and detailed status code metrics.

How to get started
I follow the same steps outlined in the How it works section to create or update the Storage Lens dashboard. In Step 4 on the console, where you select export options, you can select the new Expanded prefixes metrics report. Thereafter, I can export the expanded prefixes metrics report in CSV or Parquet format to any general purpose bucket in my account for efficient querying of my Storage Lens data.

Good to know
This enhancement addresses scenarios where organizations need granular visibility across their entire prefix structure. For example, you can identify prefixes with incomplete multipart uploads to reduce costs, track compliance across your entire prefix structure for encryption and replication requirements, and detect performance issues at the most granular level.

Export S3 Storage Lens metrics to S3 Tables
S3 Storage Lens metrics can now be automatically exported to S3 Tables, a fully managed feature on AWS with built-in Apache Iceberg support. This integration provides daily automatic delivery of metrics to AWS managed S3 Tables for immediate querying without requiring additional processing infrastructure.

How to get started
I start by following the process outlined in Step 5 on the console, where I choose the export destination. This time, I choose Expanded prefixes metrics report. In addition to General purpose bucket, I choose Table bucket.

The new Storage Lens metrics are exported to new tables in an AWS managed bucket aws-s3.

I select the expanded_prefixes_activity_metrics table to view API usage metrics for expanded prefix reports.

I can preview the table on the Amazon S3 console or use Amazon Athena to query the table.

Good to know
S3 Tables integration with S3 Storage Lens simplifies metric analysis using familiar SQL tools and AWS analytics services such as Amazon Athena, Amazon QuickSight, Amazon EMR, and Amazon Redshift, without requiring a data pipeline. The metrics are automatically organized for optimal querying, with custom retention and encryption options to suit your needs.

This integration enables cross-account and cross-Region analysis, custom dashboard creation, and data correlation with other AWS services. For example, you can combine Storage Lens metrics with S3 Metadata to analyze prefix-level activity patterns and identify objects in prefixes with cold data that are eligible for transition to lower-cost storage tiers.

For your agentic AI workflows, you can use natural language to query S3 Storage Lens metrics in S3 Tables with the S3 Tables MCP Server. Agents can ask questions such as ‘which buckets grew the most last month?’ or ‘show me storage costs by storage class’ and get instant insights from your observability data.

Now available
All three enhancements are available in all AWS Regions where S3 Storage Lens is currently offered (except the China Regions and AWS GovCloud (US)).

These features are included in the Amazon S3 Storage Lens Advanced tier at no additional charge beyond standard advanced tier pricing. For the S3 Tables export, you pay only for S3 Tables storage, maintenance, and queries. There is no additional charge for the export functionality itself.

To learn more about Amazon S3 Storage Lens performance metrics, support for billions of prefixes, and export to S3 Tables, refer to the Amazon S3 user guide. For pricing details, visit the Amazon S3 pricing page.

Veliswa Boya.

Announcing Amazon Quick Suite: your agentic teammate for answering questions and taking action

2025-10-09 Esra Kayabali

Post Syndicated from Esra Kayabali original https://aws.amazon.com/blogs/aws/reimagine-the-way-you-work-with-ai-agents-in-amazon-quick-suite/

Today, we’re announcing Amazon Quick Suite, a new agentic teammate that quickly answers your questions at work and turns those insights into actions for you. Instead of switching between multiple applications to gather data, find important signals and trends, and complete manual tasks, Quick Suite brings AI-powered research, business intelligence, and automation capabilities into a single workspace. You can now analyze data through natural language queries, find critical information across enterprise and external sources in minutes, and automate processes from simple tasks to complex multi-department workflows.

Here’s a look into Quick Suite.

Business users often need to gather data across multiple applications—pulling customer details, checking performance metrics, reviewing internal product information, and performing competitive intelligence. This fragmented process often requires consultation with specialized teams to analyze advanced datasets, and in some cases, must be repeated regularly, reducing efficiency and leading to incomplete insights for decision-making.

Quick Suite helps you overcome these challenges by combining agentic teammates for research, business intelligence, and automation into a unified digital workspace for your day-to-day work.

Integrated capabilities that power productivity
Quick Suite includes the following integrated capabilities:

Research – Quick Research accelerates complex research by combining enterprise knowledge, premium third-party data, and data from the internet for more comprehensive insights.
Business intelligence – Quick Sight provides AI-powered business intelligence capabilities that transform data into actionable insights through natural language queries and interactive visualizations, helping everyone make faster decisions and achieve better business outcomes.
Automation – Quick Flows and Quick Automate help users and technical teams to automate any business process from simple, routine tasks to complex multi-department workflows, enabling faster execution and reducing manual work across the organization.

Let’s dive into some of these key capabilities.

Quick Index: Your unified knowledge foundation
Quick Index creates a secure, searchable repository that consolidates documents, files, and application data to power AI-driven insights and responses across your organization.

As a foundational component of Quick Suite, Quick Index operates in the background to bring together all your data—from databases and data warehouses to documents and email. This creates a single, intelligent knowledge base that makes AI responses more accurate and reduces time spent searching for information.

Quick Index automatically indexes and prepares any uploaded files or unstructured data you add to your Quick Suite, enabling efficient searching, sorting, and data access. For example, when you search for a specific project update, Quick Index instantly returns results from uploaded documents, meeting notes, project files, and reference materials—all from one unified search instead of checking different repositories and file systems.

To learn more, visit the Quick Index overview page.

Quick Research: From complex business challenges to expert-level insights
Quick Research is a powerful agent that conducts comprehensive research across your enterprise data and external sources to deliver contextualized, actionable insights in minutes or hours — work that previously could take longer.

Quick Research systematically breaks down complex questions into organized research plans. Starting with a simple prompt, it automatically creates detailed research frameworks that outline the approach and data sources needed for comprehensive analysis.

After Quick Research creates the plan, you can easily refine it through natural language conversations. When you are happy with the plan, it works in the background to gather information from multiple sources, using advanced reasoning to validate findings and provide thorough analysis with citations.

Quick Research integrates with your enterprise data connected to Quick Suite, the unified knowledge foundation that connects to your dashboards, documents, databases, and external sources, including Amazon S3, Snowflake, Google Drive, and Microsoft SharePoint. Quick Research grounds key insights to original sources and reveals clear reasoning paths, helping you verify accuracy, understand the logic behind recommendations, and present findings with confidence. You can trace findings back to their original sources and validate conclusions through source citations. This makes it ideal for complex topics requiring in-depth analysis.

To learn more, visit the Quick Research overview page.

Quick Sight: AI-powered business intelligence
Quick Sight provides AI-powered business intelligence capabilities that transform data into actionable insights through natural language queries and interactive visualizations.

You can create dashboards and executive summaries using conversational prompts, reducing dashboard development time while making advanced analytics accessible without specialized skills.

Quick Sight helps you ask questions about your data in natural language and receive instant visualizations, executive summaries, and insights. This generative AI integration provides you with answers from your dashboards and datasets without requiring technical expertise.

Using the scenarios capability, you can perform what-if analysis in natural language with step-by-step guidance, exploring complex business scenarios and finding answers faster than before.

Additionally, you can respond to insights with one-click actions by creating tickets, sending alerts, updating records, or triggering automated workflows directly from your dashboards without switching applications.

To learn more, visit Quick Sight overview page.

Quick Flows: Automation for everyone
With Quick Flows, any user can automate repetitive tasks by describing their workflow using natural language without requiring any technical knowledge. Quick Flows fetches information from internal and external sources, takes action in business applications, generates content, and handles process-specific requirements.

Starting with straightforward business requirements, it creates a multi-step flow including input steps for gathering information, reasoning groups for AI-powered processing, and output steps for generating and presenting results.

After the flow is configured, you can share it with a single click to your coworkers and other teams. To execute the flow, users can open it from the library or invoke it from chat, provide the necessary inputs, and then chat with the agent to refine the outputs and further customize the results.

To learn more, visit the Quick Flows overview page.

Quick Automate: Enterprise-scale process automation
Quick Automate helps technical teams build and deploy sophisticated automation for complex, multistep processes that span departments, systems, and third-party integrations. Using AI-powered natural language processing, Quick Automate transforms complex business processes into multi-agent workflows that can be created merely by describing what you want to automate or uploading process documentation.

While Quick Flows handles straightforward workflows, Quick Automate is designed for comprehensive and complex business processes like customer onboarding, procurement automations, or compliance procedures that involve multiple approval steps, system integrations, and cross-departmental coordination. Quick Automate offers advanced orchestration capabilities with extensive monitoring, debugging, versioning, and deployment features.

Quick Automate then generates a comprehensive automation plan with detailed steps and actions. You will find a UI agent that understands natural language instructions to autonomously navigate websites, complete form inputs, extract data, and produces structured outputs for downstream automation steps.

Additionally, you can define a custom agent, complete with instructions, knowledge, and tools, to complete process-specific tasks using the visual building experience – no code required.

Quick Automate includes enterprise-grade features such as user role management and human-in-the-loop capabilities that route specific tasks to users or groups for review and approval before continuing workflows. The service provides comprehensive observability with real-time monitoring, success rate tracking, and audit trails for compliance and governance.

To learn more, visit the Quick Automate overview page.

Additional foundational capabilities
Quick Suite includes other foundational capabilities that deliver seamless data organization and contextual AI interactions across your enterprise.

Spaces – Spaces provide a straightforward way for every business user to add their own context by uploading files or connecting to specific datasets and repositories specific to their work or to a particular function. For example, you might create a space for quarterly planning that includes budget spreadsheets, market research reports, and strategic planning documents. Or you could set up a product launch space that connects to your project management system and customer feedback databases. Spaces can scale from personal use to enterprise-wide deployment while maintaining access permissions and seamless integration with Quick Suite capabilities.

Chat agents – Quick Suite includes insights agents that you can use to interact with your data and workflows through natural language. Quick Suite includes a built-in agent to answer questions across all of your data and custom chat agents that you can configure with specific expertise and business context. Custom chat agents can be tailored for particular departments or use cases—such as a sales agent connected to your product catalog data and pricing information stored in a space or a compliance agent configured with your regulatory requirements and actions to request approvals.

Additional things to know
If you’re an existing Amazon QuickSight customer – Amazon QuickSight customers will be upgraded to Quick Suite, a unified digital workspace that includes all your existing QuickSight business intelligence capabilities (now called “Quick Sight”) plus new agentic AI capabilities. This is an interface and capability change—your data connectivity, user access, content, security controls, user permissions, and privacy settings remain exactly the same. No data is moved, migrated, or changed.

Quick Suite offers per-user subscription-based pricing with consumption-based charges for the Quick Index and other optional features. You can find more detail on the Quick Suite pricing page.

Now available
Amazon Quick Suite gives you a set of agentic teammates that helps you get the answers you need using all your data and move instantly from answers to action so you can focus on high value activities that drive better business and customer outcomes.

Visit the getting started page to start using Amazon Quick Suite today.

Happy building
— Esra and Donnie

Unifying data insights with Amazon QuickSight and Amazon SageMaker

2025-07-18 Ramon Lopez

Post Syndicated from Ramon Lopez original https://aws.amazon.com/blogs/big-data/unifying-data-insights-with-amazon-quicksight-and-amazon-sagemaker/

Amazon SageMaker has announced an integration with Amazon QuickSight, bringing together data in SageMaker seamlessly with QuickSight capabilities like interactive dashboards, pixel perfect reports and generative business intelligence (BI)—all in a governed and automated manner. With this integration users can go from exploring data in SageMaker to visualizing it in QuickSight with a single click.

“The integration between Amazon SageMaker and Amazon QuickSight will help us streamline how our teams move from data exploration to insights. Our analysts can go from data discovery to building and sharing dashboards through a unified, governed experience. Dashboards are no longer siloed, one-off reports. They’re cataloged, discoverable assets that others can find and access. This has made insight delivery faster, more consistent, and far easier to scale across the business.”

– Lingam Chockalingam, Chief Data Architect, Maryland Department of Human Services – MD THINK

About QuickSight

QuickSight is a cloud-powered BI service that revolutionizes data analysis and visualization. It seamlessly integrates data from various sources, including AWS services, third-party applications, and software as a service (SaaS) platforms into a single, intuitive dashboard. As a fully managed service, QuickSight offers enterprise-grade security, global accessibility, and scalability without the hassle of infrastructure management. Amazon Q in QuickSight transforms access to data insights for the entire organization using generative AI. Using Amazon Q, business analysts can generate dashboards and reports using natural language prompts. With Amazon Q, business users can ask and answer questions of data using data Q&A, get natural language executive summaries of data to see trends and insights, and use the powerful new agentic data analysis experience of scenarios to discover patterns and outliers in data and perform what-if analysis.

About SageMaker

Amazon SageMaker Unified Studio provides a unified, end-to-end experience consisting of data, analytics, and AI capabilities. You can use familiar AWS services for model development, generative AI, data processing, and analytics—all within a single, governed environment. Users can now build, deploy, and execute end-to-end workflows from a single interface. SageMaker is built on the foundations of Amazon DataZone, where it uses domains to categorize and structure the data assets, while offering project-based collaboration features that teams can use to securely share artifacts and work together across various compute services. This experience allows multiple personas to seamlessly collaborate, while operating under appropriate access controls and governance policies.

Dashboard and insight workflows simplified

Today administrators can configure SageMaker projects with QuickSight to streamline the flow of building insights from your data lake. After being set up, the integration automatically creates a restricted folders that provides a governed context to share assets and data sources, pre-configured with secure connections to data lake tables. This serves as the foundation for any project member securely building and sharing insights. When exploring data in your project the integration allows for one-click access to building a dashboard from any table. Behind the scenes, SageMaker creates a QuickSight dataset in the project’s restricted folder that’s accessible only to members within the project. Not only do dashboards you build in QuickSight stay within this folder, they’re also automatically added as assets to your SageMaker project. There, you can add custom metadata, publish to the SageMaker Catalog and share with users or groups in your corporate directory for broader access—all within SageMaker Unified Studio. This keeps your dashboards organized, discoverable, shareable, and governed, making cross-team collaboration and asset reuse straightforward.

Configure SageMaker and QuickSight

To get started with SageMaker and QuickSight integration, you enable the QuickSight blueprint and create project profiles in the AWS Management Console.

Note that both your SageMaker Uniﬁed Studio domain and QuickSight account must be integrated with AWS IAM Identity Center using the same Identity Center instance. Additionally, your QuickSight account must exist in the same AWS account.

Go to the SageMaker console and choose Domain in the navigation pane.
Select the Blueprints tab.
To enable the QuickSight Blueprint, select it from the list, then choose Enable.
On the Enable QuickSight page:
1. 1. 1. For Provisioning role, select your provisioning role.
    2. For QuickSight VPC manager role, select the AmazonSageMakerQuickSightVPC role.
Choose Enable blueprint.
A confirmation message will appear after the blueprint is successfully enabled.
Go back to the Domains page and select the Project profiles tab and then select the SQL analytics project profile.
Choose Add blueprint deployment settings.
Configure the blueprint deployment settings as follows:
- Blueprint deployment settings name: Enter a name for your settings. For this post, we used QuickSight-BDS.
- Blueprint: Select the QuickSight blueprint from the list.
- Other parameters: Adjust these based on your use case. For this post, we kept the default values.
Scroll down and choose Add blueprint deployment settings to save your configuration.
You’ll receive a confirmation message, and you’ll see that the QuickSight Blueprint deployment setting (QuickSight-BDS) has been added to the list.

Create a SageMaker project with QuickSight enabled:

After the QuickSight integration has been set up by the administrator, data consumers such as analysts and data scientists can begin using it in the SageMaker portal by creating a new project.

Go to the SageMaker portal.
Choose Select a project, then, choose Create project.
On the Create project page:
1. Project name: Enter the name of your project. For this post, we’re using KPI-Analysis.
2. Project profile: Select the SQL Analytics project profile.
3. Choose Continue.
Leave the remaining parameters set to their default values and choose Continue.
Review the information displayed, then choose Create project.
You’ll be redirected to the Creating new project page. Wait for the process to complete.
After the project creation process is complete, you’ll be taken to the Project overview page.

Create a data asset to build the analysis

For this post, you’ll use the transactions.csv file, which contains financial transaction data from various departments.
Choose Build in the top-right menu.
Then select Query Editor from the dropdown.
Choose the plus (+) icon
Select Create table, then choose Next.
On the Set table properties page:
1. Upload file: Upload the transactions.csv file.
2. Table type: Select S3/external table.
3. Leave the remaining parameters at the default values.
4. Choose Next.
On the Preview schema page, verify that the schema matches the expected structure, then choose Create table.
The Transactions table has now been successfully created.

Create a dashboard using QuickSight

Choose the KPI-Analysis project, then choose Data.
On the Data page: Select the Transactions table, choose Actions, then select Open in QuickSight.
This step redirects you to the QuickSight UI, specifically to the transactions dataset page.
Choose USE IN ANALYSIS to begin exploring the data.
Choose a folder to save your new analysis—for this post, we selected the Assets folder.
Choose Add to save the analysis.
On the New sheet page, leave all parameters at the default values, then choose CREATE.
You’ll now be taken to the Analysis page. In this example, you analyze credit card spending at gas stations, focusing on identifying the most popular fuel type among your cardholders. The goal is to use this insight to design targeted promotions.
Under Visuals, select Pie chart.
Under GROUP/COLOR, select fuel_type.
Under Value, select amount[Sum].
You will see that credit card holders of AWSome-Bank prefer the Premium fuel type.
Publish this new dashboard to the enterprise data catalog. To do that, choose PUBLISH located in the top right corner.
On the Publish Dashboard page:
1. Enter a name for the dashboard. For this post, we’re using gas_consumption_analysis.
2. Leave the remaining parameters set to their default values.
3. Choose PUBLISH DASHBOARD.

Documenting and publishing a QuickSight asset

After the dashboard is created, it’s automatically added to the SageMaker project. From there, analysts or BI engineers can enrich it with business metadata, make it discoverable across the organization, and share it with other users or groups in their corporate directory.

Go back to the Amazon SageMaker portal
Select the Assets tab.
On the Inventory tab, select the gas_consumption_analysis asset.
This will take you to the main asset page, where you can add business metadata, view the lineage diagram, and review the asset history.
For this post, you will only add a README section.
Choose CREATE README to get started.
Add a description for the asset. For this POST, we used the following:

Overview
This Amazon QuickSight dashboard provides insights into the fuel type preferences of a bank’s credit card holders. It helps business stakeholders and analysts understand customer behavior at fuel stations, supporting data-driven marketing strategies and product personalization.
Purpose
The goal of this dashboard is to:
Analyze which fuel types (for example, Regular, Premium, Diesel, Electric) are most frequently purchased using the bank’s credit cards.
Identify customer segments (for example, age groups, locations, income brackets) that prefer specific fuel types.
Understand transaction patterns such as frequency, average spend per fuel type, and purchase timeframes.

Choose SAVE README to save the description.
On this page, you can also add glossary terms and metadata forms to provide additional business context to the asset. For this post, leave these fields empty.
Now you’re ready to publish the QuickSight asset to the enterprise data catalog. To do this, choose PUBLISH ASSET.
A confirmation prompt will appear. Choose PUBLISH ASSET again to complete the publishing process.

Search for a QuickSight asset

For this post, we created a second project called Marketing, but you can use any other project within your domain or even reuse the one created in the earlier steps.
Navigate to the SageMaker home page.
In the catalog search field, enter gas to find the published asset.
Select the relevant result for the published asset from the search results.
This will take you to the asset’s main page, where you can view the metadata added by the producer.

Sharing a QuickSight asset

You can share the QuickSight dashboard with users and groups in your organization directly from within SageMaker.

Go back to the KPI-Analysis project.
Choose the Data tab.
Then, select Assets from the Project catalog.
Go to the PUBLISHED tab, then select the gas_consumption_analysis asset.
Choose Actions, then select Share.
You can share the asset with individual SSO users or with groups. For this post, we selected an SSO group named quicksight-users, but you can choose any user or group you have previously created.
Choose Share.
A confirmation message will appear after the asset has been successfully shared.

Clean up

When you’re done with these exercises, complete the following steps to delete your resources to avoid incurring costs:

Delete the QuickSight assets that you created.
1. If QuickSight is enabled solely for testing, make sure to cancel the QuickSight account.
Delete the project created in SageMaker.
1. If SageMaker is enabled solely for testing, make sure to cancel the SageMaker account.

Conclusion

This post walked through the complete process of integrating Amazon QuickSight with Amazon SageMaker Unified Studio, demonstrating how teams can move from raw data to published dashboards in a secure and governed environment. By combining the advanced analytics capabilities of QuickSight with the collaborative project-based structure of SageMaker, organizations can accelerate insight delivery while maintaining clear control over data access and governance.

The integration simplifies creating datasets directly from Amazon Athena or Amazon Redshift tables, enrich them with business metadata, and publish dashboards to the SageMaker Catalog. When published, these dashboards can be shared with users or groups across the organization, making insights both discoverable and actionable.

With the added power of Amazon Q in QuickSight and generative BI, users can ask questions in plain English and receive real-time visualizations and insights. This makes data exploration intuitive and inclusive, empowering more users to make informed decisions. Combined with the unified analytics and AI environment of SageMaker Unified Studio, this solution supports secure, scalable, and collaborative data-driven innovation.

About the authors

Ramon Lopez is a Principal Solutions Architect for Amazon QuickSight. With many years of experience building BI solutions and a background in accounting, he loves working with customers, creating solutions, and making world-class services. When not working, he prefers to be outdoors in the ocean or up on a mountain.

Leonardo Gomez is a Principal Analytics Specialist Solutions Architect at AWS. He has over a decade of experience in data management, helping customers around the globe address their business and technical needs. Connect with him on LinkedIn.

Streamline the path from data to insights with new Amazon SageMaker Catalog capabilities

2025-07-16 Donnie Prakoso

Post Syndicated from Donnie Prakoso original https://aws.amazon.com/blogs/aws/streamline-the-path-from-data-to-insights-with-new-amazon-sagemaker-capabilities/

Modern organizations manage data across multiple disconnected systems—structured databases, unstructured files, and separate visualization tools—creating barriers that slow analytics workflows and limit insight generation. Separate visualization platforms often create barriers that prevent teams from extracting comprehensive business insights.

These disconnected workflows prevent your organizations from maximizing your data investments, creating delays in decision making and missed opportunities for comprehensive analysis that combines multiple data types.

Starting today, you can use three new capabilities in Amazon SageMaker to accelerate your path from raw data to actionable insights:

Amazon QuickSight integration – Launch Amazon QuickSight directly from Amazon SageMaker Unified Studio to build dashboards using your project data, then publish them to the Amazon SageMaker Catalog for broader discovery and sharing across your organization.
Amazon SageMaker adds support for Amazon S3 general purpose buckets and Amazon S3 Access Grants in SageMaker Catalog– Make data stored in Amazon S3 general purpose buckets easier for teams to ﬁnd, access, and collaborate on all types of data including unstructured data, while maintaining ﬁne-grained access control using Amazon S3 Access Grants.
Automatic data onboarding from your lakehouse – Automatic onboarding of existing AWS Glue Data Catalog (GDC) datasets from the lakehouse architecture into SageMaker Catalog, without manual setup.

These new SageMaker capabilities address the complete data lifecycle within a unified and governed experience. You get automatic onboarding of existing structured data from your lakehouse, seamless cataloging of unstructured data content in Amazon S3, and streamlined visualization through QuickSight—all with consistent governance and access controls.

Let’s take a closer look at each capability.

Amazon SageMaker and Amazon QuickSight Integration
With this integration, you can build dashboards in Amazon QuickSight using data from your Amazon SageMaker projects. When you launch QuickSight from Amazon SageMaker Unified Studio, Amazon SageMaker automatically creates the QuickSight dataset and organizes it in a secured folder accessible only to project members.

Furthermore, the dashboards you build stay within this folder and automatically appear as assets in your SageMaker project, where you can publish them to the SageMaker Catalog and share them with users or groups in your corporate directory. This keeps your dashboards organized, discoverable, and governed within SageMaker Unified Studio.

To use this integration, both your Amazon SageMaker Unified Studio domain and QuickSight account must be integrated with AWS IAM Identity Center using the same IAM Identity Center instance. Additionally, your QuickSight account must exist in the same AWS account where you want to enable the QuickSight blueprint. You can learn more about the prerequisites on Documentation page.

After these prerequisites are met, you can enable the blueprint for Amazon QuickSight by navigating to the Amazon SageMaker console and choosing the Blueprints tab. Then find Amazon QuickSight and follow the instructions.

You also need to configure your SQL analytics project profile to include Amazon QuickSight in Add blueprint deployment settings.

To learn more on onboarding setup, refer to the Documentation page.

Then, when you create a new project, you need to use the SQL analytics profile.

With your project created, you can start building visualizations with QuickSight. You can navigate to the Data tab, select the table or view to visualize, and choose Open in QuickSight under Actions.

This will redirect you to the Amazon QuickSight transactions dataset page and you can choose USE IN ANALYSIS to begin exploring the data.

When you create a project with the QuickSight blueprint, SageMaker Unified Studio automatically provisions a restricted QuickSight folder per project where SageMaker scopes all new assets—analyses, datasets, and dashboards. The integration maintains real-time folder permission sync, keeping QuickSight folder access permissions aligned with project membership.

Amazon Simple Storage Service (S3) general purpose buckets integration
Starting today, SageMaker adds support for S3 general purpose buckets in SageMaker Catalog to increase discoverability and allows granular permissions through S3 Access Grants, enabling users to govern data, including sharing and managing permissions. Data consumers, such as data scientists, engineers, and business analysts, can now discover and access S3 assets through SageMaker Catalog. This expansion also enables data producers to govern security controls on any S3 data asset through a single interface.

To use this integration, you need appropriate S3 general purpose bucket permissions, and your SageMaker Unified Studio projects must have access to the S3 buckets containing your data. Learn more about prerequisites on Amazon S3 data in Amazon SageMaker Unified Studio Documentation page.

You can add a connection to an existing S3 bucket.

When it’s connected, you can browse accessible folders and create discoverable assets by choosing on the bucket or a folder and selecting Publish to Catalog.

This action creates a SageMaker Catalog asset of type “S3 Object Collection” and opens an asset details page where users can augment business context to improve search and discoverability. Once published, data consumers can discover and subscribe to these cataloged assets. When data consumers subscribe to “S3 Object Collection” assets, SageMaker Catalog automatically grants access using S3 Access Grants upon approval, enabling cross-team collaboration while ensuring only the right users have the right access.

When you have access, now you can process your unstructured data in Amazon SageMaker Jupyter notebook. Following screenshot is an example to process image in medical use case.

If you have structured data, you can query your data using Amazon Athena or process using Spark in notebooks.

With this access granted through S3 Access Grants, you can seamlessly incorporate S3 data into my workflows—analyzing it in notebooks, combining it with structured data in the lakehouse and Amazon Redshift for comprehensive analytics. You can access unstructured data such as documents, images in JupyterLab notebooks to train ML models, or generate queryable insights.

Automatic data onboarding from your lakehouse
This integration automatically onboards all your lakehouse datasets into SageMaker Catalog. The key benefit for you is to bring AWS Glue Data Catalog (GDC) datasets into SageMaker Catalog, eliminating manual setup for cataloging, sharing, and governing them centrally.

This integration requires an existing lakehouse setup with Data Catalog containing your structured datasets.

When you set up a SageMaker domain, SageMaker Catalog automatically ingests metadata from all lakehouse databases and tables. This means you can immediately explore and use these datasets from within SageMaker Unified Studio without any configuration.

The integration helps you to start managing, governing, and consuming these assets from within SageMaker Unified Studio, applying the same governance policies and access controls you can use for other data types while unifying technical and business metadata.

Additional things to know
Here are a couple of things to note:

Availability – These integrations are available in all commercial AWS Regions where Amazon SageMaker is supported.
Pricing – Standard SageMaker Unified Studio, QuickSight, and Amazon S3 pricing applies. No additional charges for the integrations themselves.
Documentation – You can find complete setup guides in the SageMaker Unified Studio Documentation.

Get started with these new integrations through the Amazon SageMaker Unified Studio console.

Happy building!
— Donnie

Perform per-project cost allocation in Amazon SageMaker Unified Studio

2025-07-09 Enrique Salgado Hernández

Post Syndicated from Enrique Salgado Hernández original https://aws.amazon.com/blogs/big-data/perform-per-project-cost-allocation-in-amazon-sagemaker-unified-studio/

Amazon SageMaker Unified Studio is a single data and AI development environment where you can find and access your data and act on it using AWS resources for SQL analytics, data processing, model development, and generative AI application development.

SageMaker Unified Studio is part of the next generation of Amazon SageMaker. SageMaker brings together AWS artificial intelligence and machine learning (AI/ML) and analytics capabilities and delivers an integrated experience for analytics and AI with unified access to data.

With SageMaker Unified Studio, you can create domains and projects, providing a single interface to build, deploy, execute, and monitor end-to-end workflows. This approach helps drive collaboration across teams and facilitates agile development.

SageMaker Unified Studio implements resource tagging when AWS resources are provisioned. You can use these tags to track and allocate costs for the various resources created as part of the domains and projects within SageMaker Unified Studio.

This post demonstrates how to perform cost allocation using these resource tags, so finance analysts and business analysts can implement and follow Financial Operations (FinOps) best practices to control and track cloud infrastructure costs.

Solution overview

The following diagram illustrates how tagging works within SageMaker domains.

High level diagram that illustrates SageMaker Unified Studio entities (domains, projects and environments) are organized and how tags are applied to each of them

Before reviewing the implementation details, let’s explore several key SageMaker concepts: domain, project, project profile, and environment blueprint. For more information, refer to the SageMaker Unified Studio Administrator Guide.

Domain – A domain is an organizing entity created by an administrator. Administrators assign users to domains to enable collaboration using similar tools, assets, and resources. A domain can represent a business organization or a business unit containing people who collaborate and share resources. After creating a domain, administrators share the URL with users to access the portal.
Projects – Projects exist within each domain. A project provides a boundary where users can collaborate on a business use case. Users can create and share data, computing, and other resources within projects.
Project profile – When you create a project, you must select a project profile. A project profile is a template that governs infrastructure for the project, simplifying project creation with preconfigured settings and resources ready for use.
Environment blueprints – Environment blueprints are reusable templates for creating environments. They define settings for resource deployment and provide information for provisioning. Each blueprint uses an AWS CloudFormation template to create resources in a repeatable and scalable manner.

For effective cost tracking and allocation, make sure your SageMaker resources have proper tags. You can configure these as cost allocation tags to group and filter across AWS Billing and Cost Management tools (such as AWS Cost Explorer and AWS Data Exports).

As of this writing, SageMaker domains support tagging at the blueprint, domain, project, and environment level. When you create projects or add resources within an existing project, the following tags are automatically added to resources through CloudFormation resource tags, configured for each blueprint stack:

AmazonDataZoneBlueprint – Type of blueprint corresponding to this blueprint’s CloudFormation template (for example, Tooling)
AmazonDataZoneDomain – Amazon DataZone domain associated with this CloudFormation template
AmazonDataZoneEnvironment – Amazon DataZone environment ID associated with this CloudFormation template
AmazonDataZoneProject – Amazon DataZone project associated with this CloudFormation template

To track costs in SageMaker Unified Studio, you will perform the following steps:

Create a SageMaker domain and project.
Configure cost and billing settings by enabling cost allocation tags.
(Optional) Generate costs for your project.
Track costs using Cost Explorer and Data Exports.

Prerequisites

This post requires the following configurations in your AWS account:

AWS IAM Identity Center enabled in your organization management account (preferred) or in the member account where you will use SageMaker Unified Studio. For instructions on enabling IAM Identity Center, refer to Enable IAM Identity Center.
Cost Explorer enabled in your organization management account (preferred) or in the member account where you will use SageMaker Unified Studio. For configuration steps, refer to Enabling Cost Explorer.

Either legacy AWS Cost and Usage Reports (AWS CUR) with Amazon Athena integration or Data Exports configured and integrated with Athena for queries. For setup instructions, refer to creating Data Exports.

Create a SageMaker Unified Studio domain and project

Complete the following steps to set up your domain and project:

Create a SageMaker Unified Studio domain using the Quick setup option (recommended for new users) or manual setup.

After domain creation, you will be redirected to the domain overview page.

Choose Open Unified Studio.
On the SageMaker Unified Studio console, choose Create project.
For Project profile, choose SQL analytics, then choose Continue.

SageMaker Unified Studio create project wokflow (configuration page)

Choose Continue to keep the default blueprint parameters.
Review the configuration summary, then choose Create project.

SageMaker Unified Studio create project wokflow (confirmation page)

After the project is created, you will be redirected to the project overview page. Record the project ID and domain ID.

Project details page showing various details such as project id, project name and project IAM role ARN

Cost and billing configuration

As mentioned earlier, to track costs in SageMaker Unified Studio, you must configure cost allocation tags. Refer to Organizing and tracking costs using AWS cost allocation tags for more information about this feature.

Complete the following steps:

On the AWS Billing and Cost Management console, under Cost organization in the navigation pane, choose Cost allocation tags.
Select the following tags and choose Activate:
1. AmazonDataZoneDomain
2. AmazonDataZoneProject
3. AmazonDataZoneEnvironment
4. AmazonDataZoneBlueprint

The AmazonDataZoneProject and AmazonDataZoneDomain tags correspond to the project and domain ID values you recorded earlier.

AWS cost allocation tags interface showing the AWS tags that are currently configured as cost allocation tags

Cost allocation tags configuration doesn’t apply retroactively. If you want to monitor costs associated with these tags in the AWS Billing and Cost Management tools before the activation date, you must request a cost allocation tag backfill. The backfill operation can take several hours to complete.

Generate costs for the project

This section explains how to generate costs associated with the underlying data backend (Amazon Redshift in this case) to examine them using AWS billing tools. You can skip this section if you’re tracking costs on an active project.

To generate costs, we use the table structure used in the Redshift Immersion Labs. Refer to Create Tables for more details.

To run queries in SageMaker Unified Studio, follow these steps:

In your project, choose New and then Query.

Image that shows the query button within the SageMaker Unified Studio project overview page allowing users to open the query editor tool

Use the Amazon Redshift Serverless compute configured for the project to generate the costs:
1. Choose the Redshift (Lakehouse) connection.
2. Choose the dev database.
3. Choose the project schema.
4. Choose Choose.

Image that shows the conection selector available in SageMaker Unified Studio. In this case Redshift LakeHouse connection is selected with dev database and project schema selected underneath

Copy and execute the SQL statements provided in the following GitHub repo into the SageMaker Unified Studio query editor to create, load, and validate data on the tables.

View of the Query editor within the SageMaker Unified Studio portal. Image contains two SQL queries (create tables and COPY data operation)

After running these steps, you will have generated some Amazon Redshift costs that will be present for further analysis in AWS Billing and Cost Management tools. However, these tools (Cost Explorer and Data Exports) are refreshed least one time every 24 hours, so you might need to wait up to 24 hours before proceeding to the next section.

Tracking costs in AWS Billing and Cost Management tools

With the cost allocation tags enabled, you can use AWS Billing and Cost Management tools to analyze and track costs, including Cost Explorer and Data Exports. For more information about using these tools, refer to the AWS Billing and Cost Management User Guide.

Check costs in Cost Explorer

You can check your SageMaker Unified Studio costs using Cost Explorer. With this tool, you can view and analyze your costs and usage through an interface with pre-built filters and aggregation capabilities for various metrics. For more information, refer to the Analyzing your costs and usage with AWS Cost Explorer.

To access Cost Explorer, complete the following steps:

On the AWS Management Console, choose your account name in the top right corner and choose Billing Dashboard, or search for “Cost Explorer” in the console search bar.
On the Billing Dashboard, choose Cost Explorer in the navigation pane.
For first-time users, choose Launch Cost Explorer to enable the service.

AWS can take up to 24 hours to prepare your cost data.

To view overall costs per project, configure the following report parameters:
1. For Date Range, enter your range.
2. For Granularity, choose Monthly.
3. For Dimension, choose Tag.
4. For Tag, enter your tag (AmazonDataZoneProject).

Image that shows how to group by a particular dimension (tag) in cost explorer

The following screenshot shows a sample report.

AWS cost explorer report showing costs by SageMaker Unified Studio project

To view different service costs for a specific project, update the following parameters:
1. For Dimension, choose Service.
2. For Tag¸ choose AmazonDataZoneProject and choose the value of the project you want to inspect (in this case, 4z9d694nbsnyqx).

Image that illustrates how to filter by a specific dimension (tag) and value in cost explorer

The results should look similar to the following screenshot.

AWS cost explorer report showing service costs for a particular SageMaker Unified Studio project

Check costs using Data Exports

With Data Exports, you can query your cost and usage in AWS with the maximum flexibility degree compared to other tools such as Cost Explorer. It provides a comprehensive set of measures and dimensions that you can include in the export to create a personalized report. This report is then delivered to Amazon Simple Storage Service (Amazon S3) so you can configure it with Athena, so it can be queried using SQL or business intelligence (BI) tools such as Amazon QuickSight.

This post assumes you have already configured a data export and you have it integrated with Athena (refer to Processing data exports for more information). For instructions on setting up CUR and Athena integration, refer to Creating reports.

Check costs by project

Use the following query to check costs by project:

SELECT product_servicecode,
    product_product_family,
    resource_tags[ 'user_amazon_data_zone_project' ] as user_amazon_data_zone_project,
    round(sum(line_item_unblended_cost), 2) costs,
    line_item_line_item_description 
FROM "data_exports"."data_exportdata"
where resource_tags [ 'user_amazon_data_zone_project' ] != ''
group by product_product_family,
    product_servicecode,
    resource_tags[ 'user_amazon_data_zone_project' ],
    line_item_line_item_description
order by round(sum(line_item_unblended_cost), 2) DESC;

Results will look similar to the following screenshot on the Athena console.

Athena SQL query results when querying cost and usage data from data exports

The preceding query shows your costs grouped by:

Project (using tags)
Service
Product family, which corresponds to the subtype for a given product usage charge (for example, ML Instance for SageMaker, or Managed Storage for Amazon Redshift)

Check costs for individual projects

To check costs for a specific SageMaker Unified Studio project (for example, the sample project 4z9d694nbsnyqx created during this walkthrough), you can use the following query:

SELECT product_servicecode,
    product_product_family,
    resource_tags[ 'user_amazon_data_zone_project' ] as user_amazon_data_zone_project,
    round(sum(line_item_unblended_cost), 2) costs,
    line_item_line_item_description 
FROM "data_exports"."data_exportdata"
where resource_tags [ 'user_amazon_data_zone_project' ] != ''
and resource_tags [ 'user_amazon_data_zone_project' ] = <provide the project id here>
group by product_product_family,
    product_servicecode,
    resource_tags[ 'user_amazon_data_zone_project' ],
    line_item_line_item_description
order by round(sum(line_item_unblended_cost), 2) DESC;

Monitor costs with Data Exports and QuickSight

If you enabled Athena to work with Data Exports, you can also configure QuickSight to query this data source. With QuickSight, you can create interactive dashboards to track SageMaker costs in SageMaker Unified Studio at scale.

Configure access and permissions

To create CUR dashboards in QuickSight, first complete the following steps:

Subscribe to QuickSight and have an author user account. For instructions on subscribing to QuickSight, refer to Signing up for an Amazon QuickSight subscription.
Enable access to Athena and your CUR S3 bucket in the Security & permissions section of the QuickSight administration console. You need QuickSight administrator permissions to access this console.

Image shows QuickSight administration console where administrators can edit the AWS services (Athena in this case) that QuickSight is allowed to access

If you’re using AWS Lake Formation, make sure your QuickSight user is authorized to query the CUR database and table. For more information about granting access in Lake Formation, refer to Granting permissions on Data Catalog resources.

Create a QuickSight dataset

The next step is to create a dataset in QuickSight using a SQL query. For instructions on creating a dataset with SQL, refer to Using SQL to customize data. Use the following SQL expression:

SELECT product_servicecode,
    product_product_family,
    resource_tags[ 'user_amazon_data_zone_environment' ] as user_amazon_data_zone_environment,
    resource_tags[ 'user_amazon_data_zone_project' ] as user_amazon_data_zone_project,
    resource_tags[ 'user_amazon_data_zone_domain' ] as user_amazon_data_zone_domain,
    line_item_unblended_cost,
    line_item_usage_start_date,
    line_item_line_item_description
FROM "data_exports"."data_exportdata"
where resource_tags [ 'user_amazon_data_zone_environment' ] != '' or resource_tags [ 'user_amazon_data_zone_project' ] != ''

Image of QuickSight dataset preparation page. Shows a SQL query that is used to extract data from the data exports previously configured.

The preceding query includes only cost and usage data that’s tagged with either user_amazon_data_zone_environment or user_amazon_data_zone_project to focus on SageMaker associated costs. To include other AWS costs, you must modify these filters.

Create QuickSight dashboards

Using the authoring capabilities of QuickSight, you can create interactive dashboards where business stakeholders can explore and track costs associated with SageMaker Unified Studio projects. You can use these dashboards to review relevant cost metrics at a glance that are derived from the Data Exports dimensions and metrics included in your dataset, as shown in the following screenshot. For more information about adding visuals to analyses, refer to Adding visuals to Amazon QuickSight analyses.

Example of a QuickSight dashboard consuming data exports cost and usage data. Dashboard contains multiple visuals that illustrate SageMaker Unified Studio costs by project and service

The preceding example shows a dashboard built using QuickSight connected to a Data Exports dataset. The dashboard contains the following visuals:

KPI visual showing the current monthly costs for SageMaker Unified Studio along with the month over month (MoM) variation and history
Autonarrative visual analyzing SageMaker Unified Studio costs (highest) by month
Vertical stacked bar chart showing SageMaker Unified Studio costs by month (grouped by project)
Donut chart showing SageMaker Unified Studio cost by service
Heat map visual correlating costs by project ID and service

Using this approach (QuickSight and Data Exports), you can create highly customizable dashboards to explore and monitor your SageMaker Unified Studio costs. Furthermore, you can create automated reports using the QuickSight reporting feature to send these by email to the relevant stakeholders.

Clean up

Delete the resources you created as part of this post when you’re done with them to avoid monthly charges. This includes SageMaker resources, created Data Export reports and the QuickSight subscription (in case it was created to visualize costs).

Delete SageMaker resources
1. Log in to the SageMaker domain using an admin role.
2. Delete the project you created.
3. Delete the SageMaker domain.
Delete Data Exports reports
1. On the AWS Billing console, in the navigation pane, choose Cost & Usage Reports.
2. Select the report you want to delete.
3. Choose Delete.
4. Confirm the deletion by choosing Delete report.

For more information about managing Data Exports, refer to Deleting exports.

Unsubscribe from QuickSight
1. On the QuickSight console, choose your profile name in the top right corner.
2. Choose Manage QuickSight.
3. Choose Account settings.
4. At the bottom of the page, choose Delete your QuickSight account.
5. Review the information about data deletion.
6. Enter delete to confirm.
7. Choose Delete.

IMPORTANT NOTE: Before unsubscribing, make sure you backed up any dashboards or analyses you want to keep. After deletion, you can’t recover your QuickSight assets. For more information about managing your QuickSight subscription, refer to Deleting your Amazon QuickSight subscription and closing the account.

Conclusion

Managing costs on a unified platform like SageMaker can seem challenging because it aggregates many tools and services with different cost models. In this post, we showed how to use AWS Billing and Cost Management tools to aggregate and categorize costs across the various services used within SageMaker. With this approach, you can monitor and track respective service costs, either in aggregate or focusing on a particular project.

Start taking control of your analytics and ML costs today. With AWS Billing and Cost Management tools with SageMaker, you can:

Track and monitor your service costs
Break down expenses by project or service
Implement efficient back charging mechanisms to the different business units or organizations using SageMaker within your organization

For further reading, refer to Analyzing your costs and usage with AWS Cost Explorer and Processing Data Exports (using Athena).

About the authors

Enrique Salgado Hernández is a Senior Specialist Solutions Architect at AWS with more than 10 years of experience working in the cloud. He specializes in designing and implementing large-scale analytics architectures across various industry sectors. He is passionate about working with customers to solve their problems by supporting them during their cloud journey.

Angel Conde Manjon is a Senior EMEA Data & AI PSA, based in Madrid. He previously worked on research related to data analytics and AI in diverse European research projects. In his current role, Angel helps partners develop businesses centered on data and AI.

Build a multi-Region analytics solution with Amazon Redshift, Amazon S3, and Amazon QuickSight

2025-06-19 Donatas Kuchalskis

Post Syndicated from Donatas Kuchalskis original https://aws.amazon.com/blogs/big-data/build-a-multi-region-analytics-solution-with-amazon-redshift-amazon-s3-and-amazon-quicksight/

Organizations increasingly face complex requirements balancing regional data sovereignty with global analytics needs. Regulatory frameworks like GDPR, HIPAA, and local data protection laws often mandate storing data in specific geographic regions, and business operations require global teams to access and analyze this data efficiently.

This post explores how to effectively architect a solution that addresses this specific challenge: enabling comprehensive analytics capabilities for global teams while making sure that your data remains in the AWS Regions required by your compliance framework. We use a variety of AWS services, including Amazon Redshift, Amazon Simple Storage Service (Amazon S3), and Amazon QuickSight.

It’s important to note that this solution focuses primarily on data residency (where data is stored) and not on preventing data from being in transit between Regions. Organizations with strict data transit restrictions might need additional controls beyond what’s covered here. We show how you can configure AWS across Regions to help meet business needs and regulatory requirements simultaneously.

Cross-Region architecture requirements

Before implementing a cross-Region solution, it’s important to understand when this approach is actually necessary. Although single-Region deployments offer simplicity and cost advantages, several specific business and regulatory scenarios warrant a cross-Region approach:

Data sovereignty and residency requirements – When regulations like GDPR, HIPAA, or local data sovereignty laws require data to remain in specific geographic boundaries while still enabling global analytics capabilities
Global operations with local compliance – When your organization operates globally, but needs to adhere to regional compliance frameworks while maintaining unified analytics
Performance optimization for global users – When your organization needs to optimize analytics performance for users in different geographic areas while centralizing data governance
Enhanced business continuity – When your analytics capabilities need higher availability and Regional redundancy to support mission-critical business processes

Use case: Financial services analytics with Regional data residency

Consider a financial services company with the following business and regulatory requirements:

Data residency requirement – All customer financial data must remain in the Bahrain Region (me-south-1) to comply with local financial regulations.
Global analytics capability – The organization’s data science team operates from European offices and needs to access and analyze the financial data without moving it out of its mandated storage Region.
Advanced analytics requirements – Business leaders need interactive data exploration and natural language query capabilities to derive insights from financial data.
Performance requirement – Specific dashboard queries require subsecond response times for both local executives and the global management team.

This specific combination of requirements can’t be met with a single-Region deployment. Let’s explore how to architect a solution.

Solution overview

The following architecture is designed to address the specific challenge of using QuickSight in one Region while maintaining data in another Region.

As shown in the architecture diagram, data engineers based in Bahrain (me-south-1) work with local data, whereas data engineers in Stockholm (eu-north-1) and analysts in Ireland (eu-west-1) can securely access the same data through Redshift datashares and virtual private cloud (VPC) peering connections. This approach maintains data residency in me-south-1 while enabling global access.

The solution consists of the following key components:

Primary data Region (me-south-1):
- Redshift cluster (primary data repository)
- S3 buckets for data lake storage
- Private and public subnets with appropriate security controls
- Data must remain in this Region for compliance reasons
Analytics services Region (eu-west-1):
- QuickSight deployment
- Cross-Region VPC peering connection to the primary Region
- Data access using Redshift datashares (no data replication)
Data engineering Region (eu-north-1):
- Redshift consumer cluster for data engineering workloads
- Data access using Redshift datashares from me-south-1
- Makes it possible for data engineering teams in eu-north-1 to access and work with data while maintaining compliance

Before implementing this architecture, evaluate whether:

Your requirements actually necessitate a cross-Region approach
The performance impact is acceptable for your use case
The additional cost is justified by your business requirements

For most analytics workloads, a single-Region architecture remains the recommended approach for simplicity, performance, and cost-effectiveness. Consider cross-Region architectures only when specific business and compliance requirements make them necessary.

Establish cross-Region network connectivity: Amazon Redshift to QuickSight

The foundation of a cross-Region solution is secure, reliable network connectivity. VPC peering provides a straightforward approach for connecting VPCs across Regions. To implement VPC peering in Amazon Virtual Private Cloud (Amazon VPC), complete the following steps:

Create a new VPC in the secondary Region (eu-west-1):
1. Open the Amazon VPC console in the eu-west-1 Region.
2. Choose Create VPC.
3. Set IPv4 CIDR block to 172.32.0.0/16 (verify there is no overlap with the primary Region VPC).
4. Select Auto-generate to create subnets automatically within this new VPC.
5. Leave other settings as default and choose Create VPC.

Set up VPC peering:
1. On the Amazon VPC console, choose Peering connections in the navigation pane and choose Create peering connection.
2. Select the new eu-west-1 VPC as the requester.
3. For Select another VPC to peer with, select My account and Another Region.
4. Choose the primary Region (me-south-1) and enter the VPC ID.
5. Choose Create peering connection.

Accept the VPC peering connection:
1. Switch to the primary Region on the Amazon VPC console.
2. Choose Peering connections in the navigation pane and select the pending connection.
3. On the Actions dropdown menu, choose Accept request.

Update the route tables:
1. On the secondary Region Amazon VPC console, choose Route tables in the navigation pane.
2. Choose the route table for the new VPC.
3. Choose Edit routes and add a new route:
  - Destination: Primary Region VPC CIDR (e.g., 172.31.0.0/16).
  - Target: Choose the peering connection.
4. On the primary Region Amazon VPC console, repeat the process, adding a route to the secondary Region VPC CIDR (172.32.0.0/16) using the peering connection.

Configure security groups:
1. On the secondary Region Amazon VPC console, choose Security groups in the navigation pane and create a new security group.
2. Add an outbound rule:
  - Type: Custom TCP
  - Port range: 5439
  - Destination: Primary Region VPC CIDR
3. On the primary Region Amazon VPC console, locate the Redshift cluster’s security group.
4. Add an inbound rule:
  - Type: Custom TCP
  - Port range: 5439
  - Source: Secondary Region VPC CIDR

Configure DNS settings:
1. On the Amazon VPC console for both Regions, choose Your VPCs in the navigation pane.
2. Select each VPC, and on the Actions dropdown menu, choose Edit DNS hostnames.
3. Select Enable DNS resolution and Enable DNS hostnames.

Implement cross-Region data sharing

Rather than replicating data, which could create compliance issues, you can use Redshift datashares to provide secure, read-only access to data across Regions. Complete the following steps to set up your datashares:

Create producer datashares in the primary Region:

On the Amazon Redshift console, choose Query editor v2 in the navigation pane to connect to your primary Region Redshift cluster (me-south-1).

Run the following commands:

-- In Primary Region Redshift

CREATE DATASHARE datashare_1;
ALTER DATASHARE datashare_1 ADD SCHEMA analytics;
ALTER DATASHARE datashare_1 ADD TABLE analytics.customers;
ALTER DATASHARE datashare_1 ADD TABLE analytics.transactions;

-- Grant usage permissions
	
GRANT USAGE ON DATASHARE datashare_1 TO ACCOUNT '123456789012';

Create a consumer database in the secondary Region:

Connect to your secondary Region Redshift cluster (eu-west-1) using the query editor and run the following commands:

-- In Secondary Region Redshift

CREATE DATABASE consumer_db FROM DATASHARE datashare_1 OF ACCOUNT '123456789012'REGION 'me-south-1';

Verify the datashare configuration with the following code:

-- In Secondary Region Redshift

SELECT * FROM SVV_DATASHARE_CONSUMERS;
SELECT * FROM SVV_DATASHARE_OBJECTS;

This approach maintains data residency in the primary Region while enabling analytics access from another Region, addressing the core challenge of Regional service limitations. For our financial services company example, this makes sure that customer financial data remains in Bahrain (me-south-1) while making it securely accessible to the data science team in Europe (eu-west-1).

Configure QuickSight in the analytics Region

With network connectivity and data sharing established, complete the following steps to configure QuickSight to securely access the Redshift data:

Set up a QuickSight VPC connection:
1. Open the QuickSight console in the secondary Region.
2. Choose Manage QuickSight, VPC connections, and Add VPC connection.
3. Configure the connection:
  - Name: Enter a name (for example, Cross-Region-Connection).
  - VPC: Choose the secondary Region VPC.
  - Subnet: Choose the automatically created subnets.
  - Security group: Choose the security group created for cross-Region access.

Add a QuickSight IP range to the data source security group:
1. Open the Amazon Elastic Compute Cloud (Amazon EC2) console in the primary Region.
2. Choose Security groups in the navigation pane and find the security group for your data source.
3. Edit the inbound rules.
4. Add a new rule:
  - Type: HTTPS (443)
  - Protocol: TCP
  - Port range: 443
  - Source: QuickSight IP range for the secondary Region (for example, 52.210.255.224/27 for eu-west-1).

QuickSight IP ranges can change over time. Refer to AWS Regions, websites, IP address ranges, and endpoints for current IP ranges.

Create a QuickSight data source:
1. On the QuickSight console, choose Datasets in the navigation pane.
2. Choose New dataset, then choose Redshift.
3. Configure the connection:
  - Data source name: Enter a descriptive name.
  - Connection type: Choose the VPC connection.
  - Database server: Enter the Redshift cluster endpoint from the primary Region.
  - Port: 5439
  - Database name: Enter the consumer database name.
  - Username and Password: Enter credentials (consider using AWS Secrets Manager).
4. Choose Validate connection to test.
5. Choose Create data source.

Verify the connection and create datasets:
1. Choose the schema and tables from the consumer database.
2. Configure appropriate refresh schedules.
3. Create calculations and visualizations as needed.

Performance considerations for cross-Region analytics

When implementing a cross-Region analytics architecture, be aware of the following performance implications:

Query performance impact – Cross-Region queries can experience higher latency than single-Region queries. To mitigate this, consider the following:
- Use SPICE for QuickSight – Import frequently-used datasets into SPICE (Super-fast, Parallel, In-memory Calculation Engine) to help avoid repeated cross-Region queries. SPICE is the QuickSight in-memory engine that enables fast, interactive visualizations by precomputing and storing datasets locally in the QuickSight Region.
- Implement efficient query patterns – Minimize the amount of data transferred between Regions.
- Use appropriate caching – Enable result caching where possible.
- Monitoring cross-Region performance – Implement monitoring to identify and address performance issues:
  - Set up Amazon CloudWatch metrics to track cross-Region query performance
  - Create dashboards to visualize latency trends
  - Establish performance baselines and alerts for degradation

Security considerations

Maintaining security in a cross-Region architecture requires additional attention:

Network security:
- Limit VPC peering connections to only necessary VPCs
- Implement restrictive security groups that allow only required traffic
- Consider using VPC endpoints for service access when possible
Data access controls:
- Use AWS Identity and Access Management (IAM) policies consistently across Regions
- Implement fine-grained access controls in Redshift datashares
- Enable audit logging in relevant Regions
Compliance monitoring:
- Implement AWS CloudTrail in all Regions
- Create centralized logging for cross-Region activities
- Regularly review cross-Region access patterns

Cost implications

Before implementing a cross-Region architecture, consider these cost factors:

Data transfer costs – Data transfer between Regions incurs charges
Additional infrastructure – You might need Redshift clusters in multiple Regions
VPC peering costs – Data transfer costs are associated with VPC peering
Operational overhead – Managing multi-Region deployments requires additional resources
Workload-based sizing – You should size each Regional Redshift cluster according to the specific workloads it will handle

Conclusion

The cross-Region architecture described in this post addresses specific challenges related to Regional compliance requirements and global analytics needs, particularly in the following scenarios:

Your data must remain in a specific Region for compliance reasons
You have teams in different Regions who need to access and analyze this data
Different user groups have distinct workload requirements

The datasharing capabilities of Amazon Redshift and Regional storage options in Amazon S3 are key enablers of this solution, allowing data to remain in the required Region while still being accessible for analytics across Regions. However, it’s worth emphasizing that this architecture supports data storage in specific Regions but doesn’t prevent data from traveling between Regions during processing. Organizations concerned about data transit restrictions should evaluate additional controls to address those specific requirements. Combined with secure VPC peering connections and QuickSight visualizations, this architecture creates a complete solution that satisfies both compliance requirements and business needs.

For our financial services example, this architecture successfully enables the company to keep its customer financial data in Bahrain while providing seamless analytics capabilities to the European data science team and delivering interactive dashboards to global business leaders.

For more information, refer to Building a Cloud Security Posture Dashboard with Amazon QuickSight. For hands-on experience, explore the Amazon QuickSight Workshops. Visit the Amazon Redshift console or Amazon QuickSight console to start building your first dashboard, and explore our AWS Big Data Blog for more customer success stories and implementation patterns

Try out this solution for your own use case, and share your thoughts in the comments.

About the Authors

Donatas Kuchalskis is a Cloud Operations Architect at AWS, based in London, focusing on Financial Services customers in the UK. He helps customers optimize their AWS environments for cost, security, and resiliency while providing strategic cloud guidance. Prior to this role, he served as a Prototyping Architect specializing in Big Data and as a Specialist Solutions Architect for Retail. Before joining AWS, Donatas spent 6 years as a technical consultant in the retail sector.

Jumana Nagaria is a Prototyping Architect at AWS. She builds innovative prototypes with customers to solve their business challenges. She is passionate about cloud computing and data analytics. Outside of work, Jumana enjoys travelling, reading, painting, and spending quality time with friends and family.

Analyze media content using AWS AI services

2025-06-02 Jack Bradham

Post Syndicated from Jack Bradham original https://aws.amazon.com/blogs/architecture/analyze-media-content-using-aws-ai-services/

Organizations managing large audio and video archives face significant challenges in extracting value from their media content. Consider a radio network with thousands of broadcast hours across multiple stations and the challenges they face to efficiently verify ad placements, identify interview segments, and analyze programming patterns.

In this post, we demonstrate how you can automatically transform unstructured media files into searchable, analyzable content. By combining Amazon Transcribe, Amazon Bedrock, Amazon QuickSight, and Amazon Q, organizations can achieve the following:

Process and transcribe media files upon upload
Identify commercials, interviews, and program segments
Extract insights using foundation models (FMs)
Create a searchable knowledge base
Generate rich visualizations for decision-making
Enable natural language queries across their media archive
Visualize complex information with intuitive graphics

In the following sections, we explore how these AWS services work together to help organizations unlock the full potential of their media content, whether for advertising compliance, content analysis, or discovering specific segments within thousands of hours of recordings.

Solution overview

This solution provides an event-driven media analysis pipeline that transforms how you manage and extract value from your content:

Streamline content management – Automatically process media files the moment they’re uploaded, saving time and reducing manual work
Unlock deeper insights – Generate accurate transcriptions that capture not just words, but the full context of your content—including speakers, timing, and key moments
Harness AI – Automatically extract meaningful insights and uncover hidden patterns in your media without extensive manual review
Build a searchable knowledge base – Turn scattered media files into a discoverable catalog that your entire team can use
Build a customizable interface – Create a customizable UI to search the catalog
Create powerful visualizations – Bring your insights to life with intuitive visualizations that make complex information immediately understandable

The following diagram illustrates our architecture.

Media Analysis Architecture

This event-driven architecture automatically processes and analyzes multimedia content using AWS services. The workflow consists of the following steps:

A user uploads media files to an Amazon Simple Storage Service (Amazon S3) bucket. A “New Media” event triggers the first AWS Step Functions workflow. This workflow handles the initial cataloging based on values in the file name and launches the transcription process.
Amazon Transcribe converts the audio into accurate, readable text. The transcribed content is securely saved to an S3 bucket for further analysis. A “Transcription Complete” event triggers the next step.
A second Step Functions workflow processes the transcription. Using predefined prompts, Amazon Bedrock analyzes the transcripts to extract meaningful information. Key insights extracted from the transcript are stored in an S3 data lake.
The processed results are organized systematically, structured by date (year/month/day) and tagged with relevant attributes. This organized data enables natural language queries through Amazon Q when used as a knowledge base, interactive visualizations using QuickSight, and straightforward content discovery and analysis.
Amazon Athena serves as the data exploration tool to query the data lake. Athena is used as the data source in QuickSight, which turns complex data into clear, compelling visuals.

This architecture automatically transforms raw media content into searchable, analyzable data while maintaining an organized hierarchy for efficient access and analysis. The event-driven design provides automatic processing of new content as it arrives, and the combination of AWS AI services enables deep content understanding and insight extraction. Each AWS service plays a crucial role in transforming your media content:

Amazon Bedrock – Reviews content after transcription for insights and entity extraction:
- Uses advanced FMs to analyze transcripts
- Identifies commercials, interviews, and program segments
- Extracts meaningful insights from content
Amazon EventBridge – Triggers actions in the cataloging workflow:
- Monitors for new media files and completed transcriptions
- Automatically triggers Step Functions workflows
AWS Lambda – Handles custom code actions needed in the workflow:
- Facilitates interaction with Amazon Bedrock
- Executes custom prompts on transcripts
- Enables flexible, scalable processing
Amazon Q – Serves as the frontend and Retrieval Augmented Generation (RAG) engine:
- Addresses enterprise generative AI needs by providing a turnkey solution with built-in security features like single sign-on (SSO) integration and responsible AI governance policies
- Allows businesses to quickly deploy AI assistance while maintaining compliance, data privacy, and security standards
- Enables natural language queries across the media archive
- Links results to the source media files
- Provides conversational access to content
Amazon QuickSight – Turns insights in beautiful visualization for better consumption:
- Creates interactive dashboards and visualizations
- Displays comprehensive media analytics
- Helps track advertising, programming, and content patterns
Amazon S3 – Stores assets and the catalog:
- Securely stores raw media files, transcripts, and processed data
- Automatically triggers processing when new content is uploaded
AWS Step Functions – Orchestrates the entire content processing workflow:
- Manages transcription and AI analysis steps
- Provides robust error handling and automatic retries
Amazon Transcribe – Converts speech to accurate, readable text:
- Identifies speakers and timestamps
- Provides accurate transcriptions of audio content

Security considerations

Although this post focuses on the technical implementation of media content analysis, it’s important to acknowledge that production deployments should include comprehensive security measures:

Data storage security (Amazon S3):
- Enable server-side encryption using AWS Key Management Service (AWS KMS) keys
- Apply bucket policies restricting access to authorized principals only
- Enable Amazon S3 Block Public Access at account and bucket levels
- Enable versioning for data recovery
- Implement lifecycle policies for data retention
- Enable S3 access logging
- Use presigned URLs for temporary access
Identity and Access Management (IAM):
- Create dedicated service roles with minimum required permissions for:
  - Step Functions execution
  - Amazon Transcribe jobs
  - Amazon Bedrock API calls
  - Athena queries
- Implement role-based access control
- Regularly rotate credentials
- Enable multi-factor authentication (MFA) for all users
- Use AWS Organizations for multi-account management
Network security:
- Deploy virtual private cloud (VPC) endpoints for:
  - Amazon S3
  - Athena
  - QuickSight
- Implement network access control lists (ACLs) and security groups
- Enable VPC Flow Logs
- Use AWS PrivateLink where applicable
- Configure route tables to control traffic flow
Data encryption:
- Implement AWS KMS encryption for S3 objects
- Use TLS 1.2+ for all API communications
- Enable automatic key rotation in AWS KMS
- Implement envelope encryption for sensitive data
Monitoring and detection:
- Enable AWS CloudTrail for API activity logging
- Configure Amazon GuardDuty for threat detection
- Set up Amazon CloudWatch:
  - Metrics for service health
  - Alarms for security events
  - Log groups for application logs
- Enable S3 server access logging
- Configure VPC Flow Logs
Access controls:
- Implement fine-grained access controls for:
  - Amazon Bedrock model access
  - Athena query permissions
  - QuickSight dashboard sharing
- Conduct regular access reviews

Additionally, compliance requirements and data governance policies might impact how you implement this solution in your environment.

These security considerations are crucial but beyond the scope of this post. We recommend consulting AWS security best practices and working with your security team to implement appropriate measures for your specific use case. For more information on AWS security best practices, refer to Best Practices for Security, Identity, & Compliance.

The following sections walk you through setting up each component of the architecture to help you transform raw media into actionable insights.

Prerequisites

The following are the prerequisites to follow along this post:

An AWS account with an IAM user who has permissions to Lambda, Amazon Bedrock, Amazon S3, Amazon Transcribe, Step Functions, and IAM.
Access to the FMs that you are planning to use in Amazon Bedrock. For instructions, see Access Amazon Bedrock foundation models.
A QuickSight enterprise account. For instructions, see Setting up for Amazon QuickSight.

Create S3 buckets

For this solution, we create three distinct buckets to support the media analytics workflow:

Raw media bucket for incoming files
Transcription outputs bucket
Processed insights bucket

For instructions on creating buckets, refer to Creating a general purpose bucket.

Configure EventBridge

You can enable event notifications on the raw media bucket to trigger your automated workflow through EventBridge. Establish your automation backbone by monitoring S3 bucket activities. When new media arrives or transcription completes, EventBridge will trigger the appropriate workflow, providing continuous processing. For further instructions, refer to Creating rules that react to events in Amazon EventBridge.

The following are two example triggers that can be used to filter events and trigger Step Functions workflows. The following is an example filter for new media files:

{
  "source": ["aws.s3"],
  "detail-type": ["Object Created"],
  "detail": {
    "bucket": {
      "name": ["rawinputbucket"]
    }
  }
}

The following is an example filter for new transcripts added to the data lake:

{
  "source": ["aws.s3"],
  "detail-type": ["Object Created"],
  "detail": {
    "bucket": {
      "name": ["business-data-lake"]
    },
    "object": {
      "key": [{
        "suffix": ".transcription"
      }]
    }
  }
}

Create Step Functions workflows

We design the orchestration layer with two key workflows. The first handles media intake and transcription, and the second manages AI analysis. Each workflow includes safeguards for potential failures and retry mechanisms. For further instructions, refer to Learn how to get started with Step Functions.

The following diagram shows an example of processing new media uploads for indexing and transcription.

Media Analysis - Step Function Example

The following diagram shows an example of the Step Functions workflow that analyzes the transcription.

Set up Amazon Transcribe

To create an Amazon Transcribe job, you need permissions to do so. You can implement a speech-to-text conversion with powerful features like language detection, speaker identification, and custom vocabulary support to provide accurate transcription of your media content. For further instructions, refer to How Amazon Transcribe works.

Configure Amazon Bedrock

You can power your AI analysis engine by setting up precise prompts that extract meaningful insights. Amazon Bedrock processes transcripts to identify key segments, speakers, and topics, transforming raw text into structured data. For instructions, refer to Design a prompt.

The following is a sample prompt:

You will be reviewing a radio transcription to identify advertisements and extract relevant details. Your task is to analyze the provided transcript and output the results in a specific JSON format based on a given schema.
Please follow these steps to complete the task:
1. Carefully read through the entire transcript.
2. Identify all advertisements within the transcript. Look for clear indicators such as product mentions, promotional language, or transitions from regular content to commercial content.
3. For each advertisement you identify, determine the following information:
    - Company: The name of the company being advertised
    - Start time: The timestamp in the transcript where the ad begins
    - End time: The timestamp in the transcript where the ad ends
    - Product: The specific product or service being advertised
4. Format your findings into a JSON object that follows the provided schema. Each advertisement should be a separate object within an array.
5. Ensure these fields in your response are provided for each advertisement.. All are required fields: company, starttime, endtime, product. 
6. Use precise timestamps for start and end times. If exact times are not available, make a best estimate based on the transcript's context.
7. If a particular field is unclear or not explicitly mentioned in the transcript, you may use "Unknown" as the value.
8. Only respond with json and nothing else. Do not provide comments or explain your answer. 
9. Surround the JSON response with standard ```json markers
Here's an example of how your output should be formatted:
{
"advertisements": [
        {
            "company": "TechGadgets Inc.",
            "starttime": "00:05:30",
            "endtime": "00:06:15",
            "product": "SmartHome Hub"
        },
        {
            "company": "FreshFoods Market",
            "starttime": "00:15:45",
            "endtime": "00:16:30",
            "product": "Organic Produce Delivery Service"
        }
    ]
}
Do not add any fields that are not specified in the schema, and ensure all required fields are present for each advertisement.

Create a structured data lake

We create a hierarchical data organization strategy that enables efficient access and analysis. You can use AWS Glue crawlers to automatically discover and catalog your media metadata. For instructions, refer to Using crawlers to populate the Data Catalog. Configure Athena tables to enable SQL-based querying of your media insights:

CREATE OR REPLACE VIEW "commercials_view" AS 
SELECT
  metadata.market market
, metadata.station_call station_call
, metadata.format_type format_type
, CAST(metadata.timestamp AS timestamp) timestamp
, ads.company adCompany
, ads.product adProduct
, ads.starttime
, ads.endtime
FROM
  (commercials
CROSS JOIN UNNEST(advertisements) t (ads))

Set Up Amazon Q

You can enable natural language interaction with your media archive using Amazon Q Business. Configure the knowledge base and metadata to make your content searchable and accessible through conversational queries. Use the processed insights S3 buckets to configure the knowledge base. For instructions, refer to Getting started with Amazon Q Business.

The following screenshot shows example conversations with an AI assistant.

Build QuickSight dashboards

With QuickSight, you can create visual analytics that bring your data to life. Connect to Athena views to display advertising patterns, content analysis, and performance metrics in interactive dashboards. For more information, refer to Tutorial: Create an Amazon QuickSight dashboard.

The following screenshots are a few examples of dashboards created for a fictitious radio station as part of our use case.

Validate and optimize your media analytics solution

After you implement your media analytics architecture, follow these critical steps to achieve robust performance and alignment with your organization’s needs. First, configure a comprehensive testing approach. Imagine you’re preparing to launch your media analysis solution. Your testing journey begins with accuracy validation:

Compare transcription outputs against original media
Verify AI-generated insights for precision
Use representative sample sets from your content library

You start by taking a recently processed radio show and comparing its transcription against the original broadcast. Your team meticulously reviews the AI-generated insights, checking if key moments like ad transitions or interview segments are correctly identified. To make sure your system works across all content types, you select diverse samples from your library—perhaps a morning talk show, an evening news segment, and a weekend sports broadcast. Next, you delve into performance benchmarking:

Measure processing time for different media types
Evaluate resource utilization across AWS services
Identify potential bottlenecks in the workflow

Time how long it takes to process different types of media files, from short commercial segments to lengthy program recordings. As you watch how your AWS services respond under various loads, you can monitor resource consumption patterns. This helps you identify processing bottlenecks—for instance, you might discover that certain file types take longer to transcribe or that concurrent processing needs optimization. Finally, you put yourself in your users’ shoes for a thorough user experience assessment:

Test natural language queries with Amazon Q
Validate search result relevance
Gather feedback from potential end-users

Team members can interact with Amazon Q, asking questions they would naturally pose when searching for specific content. For example, you can test whether searching for “interviews about climate change last week” returns relevant results. Gathering feedback from potential users—perhaps a content manager with different needs than a compliance officer—provides invaluable insights. Their real-world experiences guide your refinements and make sure the system serves its intended purpose. This comprehensive testing approach, combining structured evaluation with real-world scenarios, sets the stage for a robust and user-friendly media analysis solution. As your media analysis solution moves from initial deployment to production, optimizing its performance becomes crucial for both cost-efficiency and user satisfaction. A radio network processing thousands of hours of content weekly might find that even small improvements in transcription accuracy or processing speed can lead to significant cost savings and better content discoverability. Similarly, a marketing team analyzing ad placements across multiple stations needs precise insights to make data-driven decisions about advertising effectiveness. With these business imperatives in mind, consider the following configuration optimization strategies:

Transcription refinement:
- Adjust language models for domain-specific terminology
- Fine-tune speaker identification settings
- Implement custom vocabularies for improved accuracy
AI insight generation:
- Refine prompts for more targeted analysis
- Experiment with different AI models
- Align extraction parameters with business objectives
Scalability considerations:
- Test workflow performance with increasing media volumes
- Implement appropriate auto scaling configurations
- Monitor cost-effectiveness of your architecture
Continuous improvement:
- Establish regular review cycles
- Track key performance metrics
- Iterate on your solution based on real-world usage

We recommend starting with a pilot implementation and gradually expanding your media analytics capabilities.

Clean up

To avoid incurring ongoing charges, clean up the resources you created as part of this solution:

Delete QuickSight resources:
1. Delete dashboards created for media analytics.
2. Delete the datasets connected to Athena.
3. If no longer needed, delete the QuickSight Enterprise subscription.
Delete S3 buckets:
1. Empty and delete the raw media bucket, transcription outputs bucket, and processed insights bucket.
Remove EventBridge rules:
1. Delete the rules created for monitoring S3 bucket activities.
2. Remove targets associated with these rules.
Delete Step Functions workflows:
1. Delete the media intake and transcription workflow.
2. Delete the AI analysis workflow.
Remove Lambda functions:
1. Delete Lambda functions created for interaction with Amazon Bedrock.
2. Remove associated IAM roles and policies.
Clean up data lake components:
1. Delete Athena views and tables.
2. Remove AWS Glue crawlers and databases.
3. Delete stored query results.
Remove Amazon Q configurations:
1. Delete knowledge bases created.
2. Remove custom configurations.
Remove Amazon Bedrock settings:
1. Remove custom prompts.
2. Disable access to FMs if no longer needed.
Delete Amazon Transcribe settings:
1. Remove custom vocabularies.
2. Delete stored transcription jobs.
Remove IAM resources:
1. Delete custom IAM roles created for this solution.
2. Remove associated IAM policies.
Complete additional cleanup:
1. Delete CloudWatch Logs groups associated with Lambda functions.
2. Remove CloudWatch alarms or metrics created for monitoring.
3. Delete saved queries in Athena.

Common use cases

Organizations in different sectors can use this architecture to unlock value from their audio and video content. You can adapt this solution to meet your specific needs, such as managing broadcast media, corporate communications, educational materials, and more. Let’s explore how different industries might apply this technology:

Media and broadcasting:
- Track advertising compliance
- Verify media placement accuracy
- Analyze broadcast content at scale
Corporate and enterprise:
- Convert meeting recordings into searchable knowledge bases
- Identify key decisions and action items
- Enhance organizational knowledge management
Education and training:
- Create comprehensive, topic-based course catalogs
- Index training materials for quick retrieval
- Support continuous learning initiatives
Legal services:
- Generate precise, timestamped transcripts
- Develop searchable legal proceeding archives
- Improve document review efficiency
Healthcare:
- Extract critical medical insights from consultations
- Categorize patient interaction data
- Support clinical documentation processes
Government and public sector:
- Build comprehensive public meeting archives
- Implement automated topic categorization
- Enhance transparency and accessibility
Customer service:
- Analyze call recordings for quality improvement
- Identify service trends and customer pain points
- Drive continuous customer experience enhancement

This media analytics architecture demonstrates notable versatility. By using AI, organizations can transform raw audio and video content into structured, meaningful insights that drive decision-making across industries.

Conclusion

In this post, we demonstrated how to use AWS services to convert unstructured media content into actionable intelligence. By combining Amazon Transcribe, Amazon Bedrock, QuickSight, and Amazon Q, you can create a scalable, automated solution for media analysis that adapts to your organizational needs.

This solution offers the following key architectural advantages:

Automated media file processing at scale
AI-powered insight generation
Natural language search capabilities
Interactive decision-making visualizations
Flexible, maintainable infrastructure

Organizations can now convert content into searchable knowledge, extract insights automatically, develop data-driven content strategies, and enhance operational efficiency through automation.

As audio and video content generation continues to accelerate, the ability to efficiently process and extract value becomes increasingly critical. This architecture provides a robust foundation for current needs while remaining adaptable to future technological innovations.

We invite you to explore how this media analytics solution can address your organization’s unique challenges. Consider your specific use cases and unlock the insights waiting to be discovered in your media archives.

About the authors

Automate replication of row-level security from AWS Lake Formation to Amazon QuickSight

2025-05-07 Vetri Natarajan

Post Syndicated from Vetri Natarajan original https://aws.amazon.com/blogs/big-data/automate-replication-of-row-level-security-from-aws-lake-formation-to-amazon-quicksight/

Amazon QuickSight is cloud-powered, serverless, and embeddable business intelligence (BI) service that makes it straightforward to deliver insights to your organization. As a fully managed service, Amazon QuickSight lets you create and publish interactive dashboards that can then be accessed from different devices and embedded into your applications, portals, and websites.

When authors create datasets, build dashboards, and share with end-users, the users will see the same data as the author, unless row-level security (RLS) is enabled in the Amazon QuickSight dataset. Amazon QuickSight also provides options to pass a reader’s identity to a data source using trusted identity propagation and apply RLS at the source. To learn more, see Centrally manage permissions for tables and views accessed from Amazon QuickSight with trusted identity propagation and Simplify access management with Amazon Redshift and AWS Lake Formation for users in an External Identity Provider.

However, there are a few requirements when using trusted identity propagation with Amazon QuickSight:

The authentication method for Amazon QuickSight must be using AWS IAM Identity Center.
The dataset created using trusted identity propagation will be a direct query dataset in Amazon QuickSight. QuickSight SPICE can’t be used with trusted identity propagation. This is because when using SPICE, data is imported (replicated) and therefore the entitlements at the source can’t be used when readers access the dashboard.

This post outlines a solution to automatically replicate the entitlements for readers from the source (AWS Lake Formation) to Amazon QuickSight. This solution can be used even when the authentication method in Amazon QuickSight is not using IAM Identity Center and can work with both direct query and SPICE datasets in Amazon QuickSight. This lets you take advantage of auto scaling that comes with SPICE. Although we focus on using a Lake Formation table that exists in the same account, you can extend the solution for cross-account tables as well. When extracting data filter rules for the table in another account, the execution role must have necessary access to the tables in the other account.

Use case overview

For this post, let’s consider a large financial institution that has implemented Lake Formation as its central data lake and entitlement management system. The institution aims to streamline access control and maintain a single source of truth for data permissions across its entire data ecosystem. By using Lake Formation for entitlement management, the financial institution can maintain a robust, scalable, and compliant data access control system that serves as the foundation for its data-driven operations and analytics initiatives. This approach is particularly crucial for maintaining compliance with financial regulations and maintaining data security. The analytics team wants to build an Amazon QuickSight dashboard for data and business teams.

Solution overview

This solution uses APIs of AWS Lake Formation and Amazon QuickSight to extract, transform, and store AWS Lake Formation data filters in a format that can be used in QuickSight.

The solution has four key steps:

Extract and transform the row-level security (data filters) and permissions to data filters for tables of interest from AWS Lake Formation.
Create a rules dataset in Amazon QuickSight.

We use the following key services:

AWS Lambda to extract and transform the data
Amazon Simple Storage Service (Amazon S3) to persist the transformed rules and permissions
AWS Lake Formation, Amazon Athena, and Amazon QuickSight to bring data in and create the rules dataset

The following diagram illustrates the solution architecture.

Prerequisites

To implement this solution, you should have following services enabled in the same account

AWS Lake Formation and
Amazon QuickSight
AWS Identity and Access Management (IAM) permissions: Make sure you have necessary IAM permissions to perform operation across all the services mentioned in the solution overview above
AWS Lake Formation table with data filters with right permissions
Amazon QuickSight principals (Users or Groups)

The below section shows how you can create Amazon QuickSight groups and AWS Lake formation tables and data filters

Create groups in QuickSight

Create two groups in Amazon QuickSight: QuickSight_Readers and QuickSight_Authors. For instructions, see Create a group with the QuickSight console.

You can then form the Amazon Resource Names (ARNs) of the groups as follows. These will be used when granting permission in AWS Lake Formation for data filters.

arn:aws:quicksight:<<identity-region>>:<<AWSAcocuntId>>:group/<<namespace>>/QuickSight_Readers
arn:aws:quicksight:<<identity-region>>:<<AWSAcocuntId>>:group/<<namespace>>/QuickSight_Authors

You can also get the ARN of the groups by executing the Amazon QuickSight CLI command list-groups. The following screenshot shows the output.

Create a table in AWS Lake Formation

The following section is for example purposes and not necessary for production use of this solution. Complete the following steps to create a table in AWS Lake Formation using sample data. In this post, the table is called saas_sales.

Download the file Saas Sales.csv.
Upload the file to an Amazon S3 location.
Create a table in AWS Lake Formation.

Create row-level security (data filter) in AWS Lake Formation

In AWS Lake Formation, data filters are used to filter the data in a table for an individual or group. Complete the following steps to create a data filter:

Create a data filter called QuickSightReaderFilter in the table saas_sales. For Row-level access, enter the expression segment = 'Enterprise'.
Grant the Amazon QuickSight group access to this data filter. Use the reader group ARN from the first step for SAML Users and groups.
Grant the QuickSight_Authors group full access to the table. Use the reader group ARN from the first step for SAML Users and groups.
(Optional) You can create another table called second_table and create another data filter called SecondFilter and grant permission to the QuickSight_Readers group.

Now that you have set up the table, permissions, and data filters, you can extract the row-level access details for the QuickSight_Readers and QuickSight_Authors groups and the saas_sales table in AWS Lake Formation, and create the rules dataset in Amazon QuickSight for the saas_sales table.

Extract and transform data filters and permissions from AWS Lake Formation using a Lambda function

In AWS Lake Formation, data filters are created for each table. There can be many tables in AWS Lake Formation. However, for a team or a project, there are only a specific set of tables that the BI developer is interested in. Therefore, choose a list of tables to track and update the data filters for. In a batch process, for each table in AWS Lake Formation, extract the data filter definitions and write them into Amazon S3 using AWS Lake Formation and Amazon S3 APIs.

We use the following AWS Lake Formation APIs to extract the data filter details and permissions:

ListDataCellFilters – This API is used to list all the data filters in each table that is required for the project
ListPermissions – This API is used to retrieve the permissions for each of the data filters extracted using the ListDataCellFilters API

The Lambda function covers three parts of the solution:

Extract the data filters and permissions to data filters for tables of interest from AWS Lake Formation
Transform the data filters and permission into a format usable in Amazon QuickSight
Persist the transformed data

Complete the following steps to create an AWS Lambda function:

On the Lambda console, create a function called Lake_Formation_QuickSight_RLS. Use Python 3.12 as the runtime and create a new role for execution.
Configure Lambda function timeout to 2 minutes. This can vary depending on the number of tables to be parsed and the number of data filters to be transformed.

Attach the following permissions to the Lambda execution role:

{
"Version": "2012-10-17",
"Statement": [
{
"Sid": "VisualEditor0",
"Effect": "Allow",
"Action": [
"lakeformation:ListDataCellsFilter",
"lakeformation:ListPermissions"
],
"Resource": "*"
},
{
"Sid": "VisualEditor1",
"Effect": "Allow",
"Action": "s3:PutObject",
"Resource": "arn:aws:s3:::<bucket_used_for_storage>/*"
}
]
}

Set the following environment variables for the Lambda function:

Name Value

S3Bucket Value of the S3 bucket where the output files will be stored

tablesToTrack List of tables to track as JSON converted to string

Tmp /tmp

The Lambda function gets the list of tables and S3 bucket details from the environment variables. The list of tables is given as a JSON array converted to string. The JSON format is shown in the following code. The values for catalogId, DatabaseName, and Name can be fetched from the AWS Lake Formation console.

[
{
"CatalogId": "String",
"DatabaseName": "String",
"Name": "String"
}
]

Add a folder named tmp.
Download the zip file Lake_Formation_QuickSight_RLS.zip.
Note: This is sample code for non-production usage. You should work with your security and legal teams to meet your organizational security, regulatory, and compliance requirements before deployment.
For the Lambda function code, upload the downloaded .zip file to the Lambda function, on the Code tab.
Provide necessary access to the execution role in AWS Lake Formation. Although the AWS Identity and Access Management (IAM) permissions are given to the Lambda execution role, explicit permission has to be given to the role in AWS Lake Formation for the Lambda function to get the details about the data filters. Therefore, you have to explicitly grant access to the execution role to limit the Lambda role to read-only admin. For more details, see Viewing data filters.

In the following sections, we explain what the Lambda function code does in more detail.

Extract data filters and permissions for data filters and tables in AWS Lake Formation

The main flow of the code takes the list of tables as input and extracts table and data filter permissions and data filter rules. The approach here is to get the permissions for the entire table and also for the data filters applied to the table. This way, both full access (table level) and partial access (data filter) can be extracted.

...
....
tablesToTrack= json.loads(os.environ["tablesToTrack"])
lf_client = boto3.client('lakeformation')
# For each table in the list get the data filter rules attached to the table.
for table in tablesToTrack:
df_response= lf_client.list_data_cells_filter(
Table= table
)
d_filters += df_response["DataCellsFilters"]

# Also, for each table in the list get the list of permissions at table level.
# This determines who has access to all rows in the table.
tresponse=lf_client.list_permissions(
Resource= {
"Table": table
}
)

d_permissions += tresponse["PrincipalResourcePermissions"]
transformDataFilterRules(d_filters)
# For each data filters fetched above, get the permissions.
# This determines the row level security for the tables.
for filter in d_filters:
p_response=lf_client.list_permissions(
Resource= {

"DataCellsFilter": {
"DatabaseName": filter ["DatabaseName"],
"Name": filter["Name"],
"TableCatalogId": filter["TableCatalogId"],
"TableName": filter["TableName"]
}

}
)
d_permissions += p_response["PrincipalResourcePermissions"]

transformFilterandTablePermissions(d_permissions)

Transform data filter definitions in to a format usable in Amazon QuickSight

The extracted permissions and filters are transformed to create a rules dataset in Amazon QuickSight. There are different ways to define data filters. The following figure illustrates some of the example transformations.

The function transformDataFilterRules in the following code can transform some of the OR and AND conditions into Amazon QuickSight acceptable format. The following are the details available in the transformed format:

Lake Formation catalog ID
Lake Formation database name
Lake Formation table name
Lake Formation data filter name
List of columns from all the tables provided in the input for which the data filter rules are defined

See the following code:

def transformDataFilterRules(rules):
global complete_transformed_filter_rules
transformed_filter_rules = []
filter_to_extract=[]
complete_transformed_filter_rules = []
col_headers=[]
col_headers.append("catalog")
col_headers.append("database")
col_headers.append("table")
col_headers.append("filter")

for rule in rules:
print(rule)
catalog=rule["TableCatalogId"]
database = rule["DatabaseName"]
table = rule["TableName"]
filter = rule["Name"]
row=[]
row.append(catalog)
row.append(database)
row.append(table)
row.append(filter)
logger.info(f"row==={row}")

f_conditions = re.split(' OR | or | and | AND ' , rule["RowFilter"]["FilterExpression"])

for f_condition in f_conditions:
logger.info(f"f_condition={f_condition}")
f_condition = f_condition.replace("(","")
f_condition = f_condition.replace(")","")
filter_rule_column= f_condition.split("=")
if len(filter_rule_column)>1:
filter_rule_column[0] = filter_rule_column[0].strip()
if not filter_rule_column[0].strip() in col_headers:
col_headers.append(filter_rule_column[0].strip())
i= col_headers.index(filter_rule_column[0].strip())
j= i- (len(row)-1)
if j>0:
for x in range(1, j):
row.append("")
logger.info(f"i={i} j={j} {filter_rule_column[1]}")
row.insert(i, filter_rule_column[1].replace("'",""))
print(row)
transformed_filter_rules.append(','.join(row))

row=[]
row.append(catalog)
row.append(database)
row.append(table)
row.append(filter)
max_columns = len(col_headers)
complete_transformed_filter_rules=[]
for rule in transformed_filter_rules:
r = rule.split(",")
to_fill = max_columns - len(r)
if to_fill>0:
for x in range(1, to_fill+1):
r.append("")
complete_transformed_filter_rules.append(','.join(r))

complete_transformed_filter_rules.insert(0,','.join(col_headers))

The following figure is an example of the transformed file. The file contains the columns for both tables. When creating a rules dataset for a specific table, the records are filtered for that table pulled into Amazon QuickSight.

The function transformFilterandTablePermissions in the following code snippet combines and transforms the table and data filter permissions into a flat structure that contains the following columns:

Amazon QuickSight group ARN
Lake Formation catalog ID
Lake Formation database name
Lake Formation table name
Lake Formation data filter name

See the following code:

def transformFilterandTablePermissions(permissions):
    global transformed_table_permissions,transformed_filter_permissions
    # Read and set table level access
    transformed_table_permissions = []
    transformed_filter_permissions = []
    transformed_filter_permissions.insert(0,"group,catalog,database,table,filter")
    transformed_table_permissions.insert(0,"group,catalog,database,table")
    
    for permission in permissions:
    group=""
    database=""
    table =""
    catalog=""
    
    p= permission["Permissions"]
    
    if "DESCRIBE" in p or "SELECT" in p:
    
    group = permission["Principal"]["DataLakePrincipalIdentifier"]
    if "Database" in permission["Resource"]:
    catalog=permission["Resource"]["Database"]["CatalogId"]
    database=permission["Resource"]["Database"]["Name"]
    table = "*"
    transformed_table_permissions.append(group + "," + catalog+ "," + database + "," + table)
    transformed_filter_permissions.append(group+"," +catalog + ","+ database + ","+ table)
    elif "TableWithColumns" in  permission["Resource"]  or "Table" in permission["Resource"]:
    if "TableWithColumns" in  permission["Resource"]:
    catalog=permission["Resource"]["TableWithColumns"]["CatalogId"]
    database = permission["Resource"]["TableWithColumns"]["DatabaseName"]
    table = permission["Resource"]["TableWithColumns"]["Name"]
    elif "Table" in  permission["Resource"]:
    catalog=permission["Resource"]["Table"]["CatalogId"]
    database = permission["Resource"]["Table"]["DatabaseName"]
    table = permission["Resource"]["Table"]["Name"]
    transformed_table_permissions.append( group + "," + catalog + "," + database + "," + table)
    transformed_filter_permissions.append(group+"," +catalog + ","+ database + ","+ table)
    elif "DataCellsFilter" in permission["Resource"]:
    catalog=permission["Resource"]["DataCellsFilter"]["TableCatalogId"]
    database = permission["Resource"]["DataCellsFilter"]["DatabaseName"]
    table = permission["Resource"]["DataCellsFilter"]["TableName"]
    filter = permission["Resource"]["DataCellsFilter"]["Name"]
    transformed_filter_permissions.append(group+"," +catalog + ","+ database + ","+ table+ ","+ filter)

The following figure is an example of the extracted data filter and table permissions. AWS Lake Formation can have data filters applied to any principal. However, we focus on the Amazon QuickSight principals:

The QuickSight_Authors ARN has full access to two tables. This is determined by transforming the table-level permissions in addition to the data filter permissions.
The QuickSight_Readers ARN has limited access based on filter conditions.

Store the transformed rules and permissions in two separate files in Amazon S3

The transformed rules and permissions are then persisted in a data store. In this solution, the transformed rules are written to an Amazon S3 location in CSV format. The name of the files created by the Lambda function are:

transformed_filter_permissions.csv
transformed_filter_rules.csv

See the following code:

with open("/tmp/transformed_table_permissions.csv", "w") as txt_file:
for line in transformed_table_permissions:
txt_file.write(line + "\n") # works with any number of elements in a line
txt_file.close()
s3 = boto3.resource('s3')
s3.meta.client.upload_file(Filename = "/tmp/transformed_table_permissions.csv", Bucket= os.environ['S3Bucket'], Key = "table-permissions/transformed_table_permissions.csv")

with open("/tmp/transformed_filter_permissions.csv", "w") as txt_file:
for line in transformed_filter_permissions:
txt_file.write(line + "\n") # works with any number of elements in a line
txt_file.close()

s3.meta.client.upload_file(Filename = "/tmp/transformed_filter_permissions.csv", Bucket= os.environ['S3Bucket'], Key = "filter-permissions/transformed_filter_permissions.csv")

with open("/tmp/transformed_filter_rules.csv", "w") as txt_file:
for line in complete_transformed_filter_rules:
txt_file.write(line + "\n") # works with any number of elements in a line
txt_file.close()

s3.meta.client.upload_file(Filename = "/tmp/transformed_filter_rules.csv", Bucket= os.environ['S3Bucket'], Key = "filter-rules/transformed_filter_rules.csv")

Create a rules dataset in Amazon QuickSight

In this section, we walk through the steps to create a rules dataset in Amazon QuickSight.

Create a table in Lake formation for the files

The first step is to create a table in AWS Lake Formation for the two files, transformed_filter_permissions.csv and transformed_filter_rules.csv.

Although you can directly use an Amazon S3 connector in Amazon QuickSight, creating a table and making the rules dataset using an Athena connector gives flexibility in writing custom SQL and using direct query. For the steps to bring an Amazon S3 location into AWS Lake Formation, see Creating tables.

For this post, the tables for the files are created in a separate database called quicksight_lf_transformation.

Grant permission for the tables to the QuickSight_Authors group

Grant permission in AWS Lake Formation for the two tables to the QuickSight_Authors group. This is essential for Amazon QuickSight authors to create a rules dataset in Amazon QuickSight. The following screenshot shows the permission details.

Create a rules dataset in Amazon QuickSight

Amazon QuickSight supports both user-level and group-level RLS. In this post, we use groups to enable RLS. To create the rules dataset, you first join the filter permissions table with the filter rules table on the columns catalog, database, table, and filter. Then you can filter the permissions to include the Amazon QuickSight principals, and include only the columns required for the dataset. The objective in this solution is to build a rules dataset for the saas_sales table.

Complete the following steps:

On the Amazon QuickSight console, create a new Athena dataset.
Specify the following:
1. For Catalog, choose AWSDataCatalog.
2. For Database, choose quicksight_lf_transformation.
3. For Table, choose filter_permissions.
Choose Edit/Preview data.
Choose Add data.
Choose Add source.
Select Athena.
Specify the following:
1. For Catalog, choose AWSDataCatalog.
2. For Database, choose quicksight_lf_transformation.
3. For Table, choose filter_rules.
Join the permissions table with the data filter rules table on the catalog, database, table and filter columns.
Rename the column group as GroupArn. This needs to be done before filter is applied.
Filter the data where column table equals saas_sales.
Filter the data where column group is also filtered for values starting with arn:aws:quicksight (Amazon QuickSight principals).
Exclude fields that are not part of the saas_sales table.
Change Query mode to SPICE.
Publish the dataset.

If your organization has a mapping of other principals to a Amazon QuickSight group or user, you can apply that mapping before joining the tables.

You can also write the following custom SQL to achieve the same result:

SELECT a."group" as GroupArn, segment FROM "QuickSight_lf_transformation"."filter_permissions" as a
left join
"QuickSight_lf_transformation"."filter_rules" as b
on
a.catalog = b.catalog and
a.database = b.database and
a."table" = b."table" and
a.filter = b.filter
where a."table" = 'saas_sales'
and a."group" like 'arn:aws:quicksight%'

Name the dataset LakeFormationRLSDataSet and publish the dataset.

Test the row-level security

Now you’re ready to test the row-level security by publishing a dashboard as a user in the QuickSight_Authors group and then viewing the dashboard as a user in the QuickSight_Readers group.

Publish a dashboard as a QuickSight_Authors group user

As an author who belongs to the QuickSight_Authors group, the user will be able to see the saas_sales table in the Athena connector and all the data in the table. As shown in this section, all three segments are visible for the author when creating an analysis and viewing the published dashboard.

Create a dataset by pulling data from the saas_sales table using the Athena connector.
Attach LakeFormationRLSDataSet as the RLS dataset for the saas_sales dataset. For instructions, see Using row-level security with user-based rules to restrict access to a dataset.
Create an analysis using the saas_sales dataset as an author who belongs to the QuickSight_Authors group.
Publish the dashboard.
Share the dashboard with the group QuickSight_Readers.

View the dashboard as a QuickSight_Readers group user

Complete the following steps to view the dashboard as a QuickSight_Readers group user:

Log into Amazon QuickSight as a reader who belongs to the QuickSight_Readers group.

The user will be able to see only the segment Enterprise.

Now, change the RLS in AWS Lake Formation, and set the segment to be SMB for the QuickSightReaderFilter.
Run the Lambda function to export and transform the new data filter rules.
Refresh the SPICE dataset LakeFormationRLSDataSet in Amazon QuickSight.
When the refresh is complete, refresh the dashboard in the reader login.

Now the reader user will see SMB data.

Cleanup

Amazon QuickSight resources

Delete the Amazon QuickSight dashboard and analysis created
Delete the datasets saas_sales and LakeFormationRulesDataSet
Delete the Athena data source
Delete the QuickSight groups using the DeleteGroup API

AWS Lake Formation resources

Delete the database quicksight_lf transformation created in AWS Lake Formation
Revoke permission given to the Lambda execution role
Delete the saas_sales table and data filters created
If you have used Glue crawler to create the tables in AWS Lake Formation, remove the Glue crawler as well

Compute resources

Delete the AWS Lambda function created
Delete the AWS Lambda execution role associated with the lambda

Storage resources

Empty the content of the Amazon S3 bucket created for this solution
Delete the Amazon S3 bucket

Conclusion

This post explained how to replicate row-level security in AWS Lake Formation automatically in Amazon QuickSight. This makes sure that the SPICE dataset in QuickSight can use row-level access defined in Lake Formation.

This solution can also be extended for other data sources. The logic to programmatically extract the entitlements from the source and transform them into Amazon QuickSight format will vary by source. After the extract and transform are in place, it can scale to multiple teams in the organization. Although this post laid out a basic approach, the automation has to be either scheduled to run periodically or triggered based on events like data filters change or grant or revoke of AWS Lake Formation permissions to make sure that the entitlements remain in sync between AWS Lake Formation and Amazon QuickSight.

Try out this solution for your own use case, and share your feedback in the comments.

About the Authors

Vetri Natarajan is a Specialist Solutions Architect for Amazon QuickSight. Vetri has 15 years of experience implementing enterprise business intelligence (BI) solutions and greenfield data products. Vetri specializes in integration of BI solutions with business applications and enable data-driven decisions.

Ismael Murillo is a Solutions Architect for Amazon QuickSight. Before joining AWS, Ismael worked in Amazon Logistics (AMZL) with delivery station management, delivery service providers, and our customer actively in the field. Ismael focused on last mile delivery and delivery success. He designed and implemented many innovative solutions to help reduce cost, influence delivery success. He is also a United States Army Veteran, where he served for eleven years.

How BMW Group built a serverless terabyte-scale data transformation architecture with dbt and Amazon Athena

2025-04-29 Philipp Karg

Post Syndicated from Philipp Karg original https://aws.amazon.com/blogs/big-data/how-bmw-group-built-a-serverless-terabyte-scale-data-transformation-architecture-with-dbt-and-amazon-athena/

Businesses increasingly require scalable, cost-efficient architectures to process and transform massive datasets. At the BMW Group, our Cloud Efficiency Analytics (CLEA) team has developed a FinOps solution to optimize costs across over 10,000 cloud accounts. While enabling organization-wide efficiency, the team also applied these principles to the data architecture, making sure that CLEA itself operates frugally. After evaluating various tools, we built a serverless data transformation pipeline using Amazon Athena and dbt.

This post explores our journey, from the initial challenges to our current architecture, and details the steps we took to achieve a highly efficient, serverless data transformation setup.

Challenges: Starting from a rigid and costly setup

In our early stages, we encountered several inefficiencies that made scaling difficult. We were managing complex schemas with wide tables that required significant effort in maintainability. Initially, we used Terraform to create tables and views in Athena, allowing us to manage our data infrastructure as code (IaC) and automate deployments through continuous integration and delivery (CI/CD) pipelines. However, this method slowed us down when changing data models or dealing with schema changes, therefore requiring high development efforts.

As our solution grew, we faced challenges with query performance and costs. Each query scanned large amounts of raw data, resulting in increased processing time and higher Athena costs. We used views to provide a clean abstraction layer, but this masked underlying complexity because seemingly simple queries against these views scanned large volumes of raw data, and our partitioning strategy wasn’t optimized for these access patterns. As our datasets grew, the lack of modularity in our data design increased complexity, making scalability and maintenance increasingly difficult. We needed a solution for pre-aggregating, computing, and storing query results of computationally intensive transformations. The absence of robust testing and lineage solutions made it challenging to identify the root causes of data inconsistencies when they occurred.

As part of our business intelligence (BI) solution, we used Amazon QuickSight to build our dashboards, providing visual insights into our cloud cost data. However, our initial data architecture led to challenges. We were building dashboards on top of large, wide datasets, with some hitting the QuickSight per-dataset SPICE limit of 1 TB. Additionally, during SPICE ingest, our largest datasets required 4–5 hours of processing time due to performing full scans each time, often scanning over a terabyte of data. This architecture wasn’t helping us be more agile and quick while scaling up. The long processing times and storage limitations hindered our ability to provide timely insights and expand our analytics capabilities.

To address these issues, we enhanced the data architecture with AWS Lambda, AWS Step Functions, AWS Glue, and dbt. This tool stack significantly enhanced our development agility, empowering us to quickly modify and introduce new data models. At the same time, we improved our overall data processing efficiency with incremental loads and better schema management.

Solution overview

Our current architecture consists of a serverless and modular pipeline coordinated by GitHub Actions workflows. We chose Athena as our primary query engine for several strategic reasons: it aligns perfectly with our team’s SQL expertise, excels at querying Parquet data directly in our data lake, and alleviates the need for dedicated compute resources. This makes Athena an ideal fit for CLEA’s architecture, where we process around 300 GB daily from a data lake of 15 TB, with our largest dataset containing 50 billion rows across up to 400 columns. The capability of Athena to efficiently query large-scale Parquet data, combined with its serverless nature, enables us to focus on writing efficient transformations rather than managing infrastructure.

The following diagram illustrates the solution architecture.

Using this architecture, we’ve streamlined our data transformation process using dbt. In dbt, a data model represents a single SQL transformation that creates either a table or a view—essentially a building block of our data transformation pipeline. Our implementation includes around 400 such models, 50 data sources, and around 100 data tests. This setup enables seamless updates—whether creating new models, updating schemas, or modifying views—triggered simply by creating a pull request in our source code repository, with the rest handled automatically.

Our workflow automation includes the following features:

Pull request – When we create a pull request, it’s deployed to our testing environment first. After passing validation and being approved or merged, it’s deployed to production using GitHub workflows. This setup enables seamless model creation, schema updates, or view changes—triggered just by creating a pull request, with the rest handled automatically.
Cron scheduler – For nightly runs or multiple daily runs to reduce data latency, we use scheduled GitHub workflows. This setup allows us to configure specific models with different update strategies based on data needs. We can set models to update incrementally (processing only new or changed data), as views (querying without materializing data), or as full loads (completely refreshing the data). This flexibility optimizes processing time and resource usage. We can target only specific folders—like source, prepared, or semantic layers—and run the dbt test afterward to validate model quality.
On demand – When adding new columns or changing business logic, we need to update historical data to maintain consistency. For this, we use a backfill process, which is a custom GitHub workflow created by our team. The workflow allows us to select specific models, include their upstream dependencies, and set parameters like start and end dates. This makes sure that changes are applied accurately across the entire historical dataset, maintaining data consistency and integrity.

Our pipeline is organized into three primary stages—Source, Prepared, and Semantic—each serving a specific purpose in our data transformation journey. The Source stage maintains raw data in its original form. The Prepared stage cleanses and standardizes this data, handling tasks like deduplication and data type conversions. The Semantic stage transforms this prepared data into business-ready models aligned with our analytical needs. An additional QuickSight step handles visualization requirements. To achieve low cost and high performance, we use dbt models and SQL code to manage all transformations and schema changes. By implementing incremental processing strategies, our models process only new or changed data rather than reprocessing the entire dataset with each run.

The Semantic stage (not to be confused with dbt’s semantic layer feature) introduces business logic, transforming data into aggregated datasets that are directly consumable by BMW’s Cloud Data Hub, internal CLEA dashboards, data APIs, or In-Console Cloud Assistant (ICCA) chatbot. The QuickSight step further optimizes data by selecting only necessary columns by using a column-level lineage solution and setting a dynamic date filter with a sliding window to ingest only relevant hot data into SPICE, avoiding unused data in dashboards or reports.

This approach aligns with BMW Group’s broader data strategy, which includes streamlining data access using AWS Lake Formation for fine-grained access control.

Overall, as a high-level structure, we’ve fully automated schema changes, data updates, and testing through GitHub pull requests and dbt commands. This approach enables controlled deployment with robust version control and change management. Continuous testing and monitoring workflows uphold data accuracy, reliability, and quality across transformations, supporting efficient, collaborative model iteration.

Key benefits of the dbt-Athena architecture

To design and manage dbt models effectively, we use a multi-layered approach combined with cost and performance optimizations. In this section, we discuss how our approach has yielded significant benefits in five key areas.

SQL-based, developer-friendly environment

Our team already had strong SQL skills, so dbt’s SQL-centric approach was a natural fit. Instead of learning a new language or framework, developers could immediately start writing transformations using familiar SQL syntax with dbt. This familiarity aligns well with the SQL interface of Athena and, combined with dbt’s added functionality, has increased our team’s productivity.

Behind the scenes, dbt automatically handles synchronization between Amazon Simple Storage Service (Amazon S3), the AWS Glue Data Catalog, and our models. When we need to change a model’s materialization type—for example, from a view to a table—it’s as simple as updating a configuration parameter rather than rewriting code. This flexibility has reduced our development time dramatically, allowed us to focus on building better data models rather than managing infrastructure.

Agility in modeling and deployment

Documentation is crucial for any data platform’s success. We use dbt’s built-in documentation capabilities by publishing them to GitHub Pages, which creates an accessible, searchable repository of our data models. This documentation includes table schemas, relationships between models, and usage examples, enabling team members to understand how models interconnect and how to use them effectively.

We use dbt’s built-in testing capabilities to implement comprehensive data quality checks. These include schema tests that verify column uniqueness, referential integrity, and null constraints, as well as custom SQL tests that validate business logic and data consistency. The testing framework runs automatically on every pull request, validating data transformations at each step of our pipeline. Additionally, dbt’s dependency graph provides a visual representation of how our models interconnect, helping us understand the upstream and downstream impacts of any changes before we implement them. When stakeholders need to modify models, they can submit changes through pull requests, which, after they’re approved and merged, automatically trigger the necessary data transformations through our CI/CD pipeline. This streamlined process enabled us to create new data products within days compared to weeks and reduced ongoing maintenance work by catching issues early in the development cycle.

Athena workgroup separation

We use Athena workgroups to isolate different query patterns based on their execution triggers and purposes. Each workgroup has its own configuration and metric reporting, allowing us to monitor and optimize separately. The dbt workgroup handles our scheduled nightly transformations and on-demand updates triggered by pull requests through our Source, Prepared, and Semantic stages. The dbt-test workgroup executes automated data quality checks during pull request validation and nightly builds. The QuickSight workgroup manages SPICE data ingestion queries, and the Ad-hoc workgroup supports interactive data exploration by our team.

Each workgroup can be configured with specific data usage quotas, enabling teams to implement granular governance policies. This separation provides several benefits: it enables clear cost allocation, provides isolated monitoring of query patterns across different use cases, and helps enforce data governance through custom workgroup settings. Amazon CloudWatch monitoring per workgroup helps us track usage patterns, identify query performance issues, and adjust configurations based on actual needs.

Using QuickSight SPICE

QuickSight SPICE (Super-fast, Parallel, In-memory Calculation Engine) provides powerful in-memory processing capabilities that we’ve optimized for our specific use cases. Rather than loading entire tables into SPICE, we create specialized views on top of our materialized semantic models. These views are carefully crafted to include only the necessary columns, relevant metadata joins, and appropriate time filtering to have only recent data available in dashboards.

We’ve implemented a hybrid refresh strategy for these SPICE datasets: daily incremental updates keep the data fresh, and weekly full refreshes maintain data consistency. This approach strikes a balance between data freshness and processing efficiency. The result is responsive dashboards that maintain high performance while keeping processing costs under control.

Scalability and cost-efficiency

The serverless architecture of Athena eliminates manual infrastructure management, automatically scaling based on query demand. Because costs are based solely on the amount of data scanned by queries, optimizing queries to scan as little data as possible directly reduces our costs. We use the distributed query execution capabilities of Athena through our dbt model structure, enabling parallel processing across data partitions. By implementing effective partitioning strategies and using Parquet file format, we minimize the amount of data scanned while maximizing query performance.

Our architecture offers flexibility in how we materialize data through views, full tables, and incremental tables. With dbt’s incremental models and partitioning strategy, we process only new or modified data instead of entire datasets. This approach has proven highly effective—we’ve observed significant reductions in data processing volume as well as data scanning, particularly in our QuickSight workgroup.

The effectiveness of these optimizations implemented at the end of 2023 is visible in the following diagram, showing costs by Athena workgroups.

The workgroups are illustrated as follows:

Green (QuickSight): Shows reduced data scanning post-optimization.
Light blue (Ad-hoc): Varies based on analysis needs.
Dark blue (dbt): Maintains consistent processing patterns
Orange (dbt-test): Shows regular, efficient test execution.

The increased dbt workload costs directly correlate with decreased QuickSight costs, reflecting our architectural shift from using complex views in QuickSight workgroups (which previously masked query complexity but led to repeated computations) to using dbt for materializing these transformations. Although this increased the dbt workload, the overall cost-efficiency improved significantly because materialized tables reduced redundant computations in QuickSight. This demonstrates how our optimization strategies successfully manage growing data volumes while achieving net cost reduction through efficient data materialization patterns.

Conclusion

Our data architecture uses dbt and Athena to provide a scalable, cost-efficient, and flexible framework for building and managing data transformation pipelines. Athena’s ability to query data directly in Amazon S3 alleviates the need to move or copy data into a separate data warehouse, and its serverless model and dbt’s incremental processing minimize both operational overhead and processing costs. Given our team’s strong SQL expertise, expressing these transformations in SQL through dbt and Athena was a natural choice, enabling rapid model development and deployment. With dbt’s automatic documentation and lineage, troubleshooting and identifying data issues is simplified, and the system’s modularity allows for quick adjustments to meet evolving business needs.

Starting with this architecture is quick and straightforward: all that is needed is the dbt-core and dbt-athena libraries, and Athena itself requires no setup, because it’s a fully serverless service with seamless integration with Amazon S3. This architecture is ideal for teams looking to rapidly prototype, test, and deploy data models, optimizing resource usage, accelerating deployment, and providing high-quality, accurate data processing.

For those interested in a managed solution from dbt, see From data lakes to insights: dbt adapter for Amazon Athena now supported in dbt Cloud.

About the Authors

Philipp Karg is a Lead FinOps Engineer at BMW Group and has a strong background in data engineering, AI, and FinOps. He focuses on driving cloud efficiency initiatives and fostering a cost-aware culture within the company to leverage the cloud sustainably.

Selman Ay is a Data Architect specializing in end-to-end data solutions, architecture, and AI on AWS. Outside of work, he enjoys playing tennis and engaging outdoor activities.

Cizer Pereira is a Senior DevOps Architect at AWS Professional Services. He works closely with AWS customers to accelerate their journey to the cloud. He has a deep passion for cloud-based and DevOps solutions, and in his free time, he also enjoys contributing to open source projects.

How ANZ Institutional Division built a federated data platform to enable their domain teams to build data products to support business outcomes

2024-12-04 Leo Ramsamy

Post Syndicated from Leo Ramsamy original https://aws.amazon.com/blogs/big-data/how-anz-institutional-division-built-a-federated-data-platform-to-enable-their-domain-teams-to-build-data-products-to-support-business-outcomes/

In today’s rapidly evolving financial landscape, data is the bedrock of innovation, enhancing customer and employee experiences and securing a competitive edge. Recognizing this paradigm shift, ANZ Institutional Division has embarked on a transformative journey to redefine its approach to data management, utilization, and extracting significant business value from data insights.

Like many large financial institutions, ANZ Institutional Division operated with siloed data practices and centralized data management teams. As time went on, the limitations of this approach became apparent due to rising data complexity, larger volumes, and the growing demand for swift, business-driven insights. Consequently, the bank encountered several challenges and needed to take the following actions:

Create business insights from untapped data potential, estimated to be approximately $150 million in the Institutional Division alone
Improve operational efficiency by removing manual data handling, the use of spreadsheets, and duplicate data entries
Increase agility by making data expertise more readily available, thereby improving time to market and overall customer experience
Address data quality
Standardize tooling and remove the Shadow IT culture, driving scalability, reducing risk, and minimizing overall operational inefficiencies

These challenges are not unique to ANZ Institutional Division. Globally, financial institutions have been experiencing similar issues, prompting a widespread reassessment of traditional data management approaches.

One major trend, embraced by many financial institutions, has been the adoption of the data mesh architecture and the shift towards treating data as a product. This paradigm, pioneered by thought leaders like Zhamak Dehghani, introduces a decentralized approach to data management that aligns closely with modern organizational structures and agile methodologies.

Some notable global examples of leading companies embracing and implementing this trend are JPMorgan Chase, Capital One, and Saxo Bank.

Inspired by these global trends and driven by its own unique challenges, ANZ’s Institutional Division decided to pivot from viewing data as a byproduct of projects to treating it as a valuable product in its own right.

This shift promises several business benefits:

Empowered domain expertise – By decentralizing data ownership to domain-based teams, ANZ can use the deep business knowledge within each unit to create more relevant and valuable data products
Increased agility – Domain teams can now respond more quickly to business needs, creating and iterating on data products without relying on a centralized bottleneck
Improved data quality – With domain experts overseeing their own data, there’s a greater likelihood of catching and correcting quality issues at the source
Scalability – The federated approach allows for greater scalability, enabling ANZ to handle increasing data volumes and complexity more effectively
Innovation catalyst – By democratizing data access and empowering teams to create data products, ANZ is fostering a culture of innovation and data-driven decision-making across the organization

This transition is not just about technology; it represents a fundamental shift in how ANZ views and values its data assets. By treating data as a product, the bank is positioned to not only overcome current challenges, but to unlock new opportunities for growth, customer service, and competitive advantage.

This post explores how the shift to a data product mindset is being implemented, the challenges faced, and the early wins that are shaping the future of data management in the Institutional Division.

ANZ’s federated data strategy

In response to the challenges, ANZ Group formulated a data strategy that focuses on empowering employees to securely use data to improve the sustainability and financial well-being of their customers. At its core are the following pillars:

Introducing new ways of working that focus on generating customer value first
New technology platforms and tooling that allow the bank to collect, share, archive, and dispose data in a secure and controlled way
Achieving consistency in how data is produced and consumed across the entire bank through data products and better-connected systems
Supporting the bank’s risk and regulatory obligations by providing a secure and resilient data platform that provides fine-grained, controlled access to quality data products

ANZ has made the strategic decision to adopt an architectural and operational model aligned with the data mesh paradigm, which revolves around four key principles: domain ownership, data as a product, a self-serve data platform, and federated computational governance.

Domain ownership recognizes that the teams generating the data have the deepest understanding of it and are therefore best suited to manage, govern, and share it effectively. This principle makes sure data accountability remains close to the source, fostering higher data quality and relevance.

Treating data as a product instils a product-centric mindset, emphasizing that data must be secure, discoverable, understandable, interoperable, reusable, and managed throughout its lifecycle. This principle makes sure data consumers, both internal and external, derive consistent value from well-designed data products.

A self-serve data platform empowers domains to create, discover, and consume data products independently. It abstracts technical complexities and provides user-friendly tools, enabling a scalable, repeatable, and automated approach to producing high-quality data products.

Under the federated mesh architecture, each divisional mesh functions as a node within the broader enterprise data mesh, maintaining a degree of autonomy in managing its data products. To effectively coordinate these autonomous nodes and facilitate seamless integration, enterprise-wide standards, such as those related to data governance, interoperability, and security, are essential to maintain alignment and consistency across all nodes and domains and teams within.

With this approach, each node in ANZ maintains its divisional alignment and adherence to data risk and governance standards and policies to manage local data products and data assets. This enables global discoverability and collaboration without centralizing ownership or operations.

As a result, governance resides with the data products themselves, making sure standards and policies, such as access control, data quality, and compliance, are enforced where the data lives. In this regard, the enterprise data product catalog acts as a federated portal, facilitating cross-domain access and interoperability while maintaining alignment with governance principles. This model balances node or domain-level autonomy with enterprise-level oversight, creating a scalable and consistent framework across ANZ.

Within the ANZ enterprise data mesh strategy, aligning data mesh nodes with the ANZ Group’s divisional structure provides optimal alignment between data mesh principles and organizational structure, as shown in the following diagram.

Central to the success of this strategy is its support for each division’s autonomy and freedom to choose their own domain structure, which is closely aligned to their business needs. Divisions decide how many domains to have within their node; some may have one, others many. These nodes can implement analytical platforms like data lake houses, data warehouses, or data marts, all united by producing data products. Nodes and domains serve business needs and are not technology mandated.

Under the federated computational governance model, the ANZ Group strategy defines guardrails that treat a node as a logical data container suitable for the following:

Ingestion and metadata management
Creating source-aligned data products complying with ANZ’s Data Product Specification (DPS)
Integrating source-aligned data products from other nodes
Producing consumer-aligned data products for specific business purposes
Publishing conforming data products to ANZ’s Data Product Catalog (DPC)

Following on from this strategy is organizing its domain structure to provide autonomy to various functional teams while preserving the core values of data mesh. The following diagram depicts an example of the possible structure.

For instance, Domain A will have the flexibility to create data products that can be published to the divisional catalog, while also maintaining the autonomy to develop data products that are exclusively accessible to teams within the domain. These products will not be available to others until they are deemed ready for broader enterprise use.

This strategy supports each division’s autonomy to implement their own data catalogs and decide which data products to publish to the group-level catalog. This flexibility extends to divisional domains, which can choose which data products to publish to the divisional catalog or keep visible only to domain consumers.

Institutional Data & AI Platform architecture

The Institutional Division has implemented a self-service data platform to enable the domain teams to build and manage data products autonomously. The Institutional Data & AI platform adopts a federated approach to data while centralizing the metadata to facilitate simpler discovery and sharing of data products. The following diagram illustrates the building blocks of the Institutional Data & AI Platform.

The building blocks are as follows:

Foundational Data & AI Platform capabilities – A dedicated data platform team provides domain-agnostic tools, systems, and capabilities to enable autonomous data product development across domains. This self-serve infrastructure allows domain teams to manage the full data lifecycle without relying on a centralized data team. Key capabilities include data storage, data onboarding and transformation, and data utilities that facilitate data sharing with interoperability between domains. These capabilities abstract the technical complexities associated with data management infrastructure, allowing domain experts to focus on creating valuable data products rather than infrastructure management.
Domain-owned data assets – The domain-oriented data ownership approach distributes responsibility for data across the business units within the Institutional Division. Domain teams are responsible for developing, deploying, and managing their own analytical data products alongside operational data services. Data contracts authored by data product owners automate data product creation and provide a standard to access data products. By treating the data as a product, the outcome is a reusable asset that outlives a project and meets the needs of the enterprise consumer. Consumer feedback and demand drives creation and maintenance of the data product.
Division-level metadata management and data governance – A centrally hosted service provides domain teams with the capability to publish their data products along with relevant metadata, like business definitions and lineage. Some of the key features implemented are:
1. Metadata management that centralizes metadata and presents it within the context of data products, such as data quality scores and data product lineage.
2. A data portal for consumers to discover data products and access associated metadata.
3. Subscription workflows that simplify access management to the data products.
4. Computational governance that enforces divisional and enterprise data policies and standards, such as data classification and business data models for aligning terminology.

The following diagram is a high-level example of the technical architecture approach towards the Institutional Data & AI Platform. The solution uses a building block approach, on a cloud-centered platform comprised of AWS services, with partner solutions and open standards like OpenLineage and Apache Iceberg.

Let’s look at the key services that enable the federated platform to operate at scale:

Data storage and processing:
- Apache Iceberg on Amazon Simple Storage Service (Amazon S3) offers an optimized way to store data assets and products and promotes interoperability across other services
- Amazon Redshift allows domain teams to create and manage fit-for-purpose data marts
- AWS Lambda and AWS Glue are used for data onboarding and processing, and data utilities created in Python and PySpark promote reusability and quality across the data processing pipelines
- dbt simplifies data transformation rules and allows sub-domain data analysts to build modeling logic as SQL statements
- Amazon Managed Workflows for Apache Airflow (Amazon MWAA) enables efficient management of workflows and data pipeline orchestration using out-of-the-box integrations with AWS services
Metadata management and data governance:
- To maintain data reliability and accuracy, a robust data quality framework using Soda core is used that automates data quality using checks defined in a data contract
- Amazon DataZone enables data product cataloging, discovery, metadata management, and implementing computational governance
- OpenLineage simplifies harvesting and collection of data and process-level lineage, which are then published to Amazon DataZone
- AWS Lake Formation, combined with AWS Glue Data Catalog, provides data governance and access management to data products that reside within sub-domains
Analytics:
- Tableau offers capabilities for sub-domains with data visualization and business intelligence capabilities
Observability and security:
- Observability needs of the platform are built into all the processes using monitoring, with logging functionality provided by Amazon CloudWatch and AWS CloudTrail
- AWS Secrets Manager makes sure secrets are stored and made available for data pipelines to access services in a secure manner

The technical implementation actualizes the data product strategy at ANZ Institutional Division. Amazon DataZone plays an essential role in facilitating data product management for the domain teams. The service addresses several critical aspects of the Institutional Division’s data product strategy, including:

Data cataloging and metadata management – Amazon DataZone provides comprehensive data cataloging and metadata management capabilities
Data governance and compliance – Effective data governance is essential for scaling data products
Self-service capabilities – Amazon DataZone empowers domain teams with self-service capabilities, enabling them to create, manage, and deploy data products independently
Integration and interoperability – One of the challenges in scaling data products is providing seamless integration across various data sources and systems
Collaboration and sharing – Amazon DataZone provides a platform for sharing data and metadata across teams and domains

Institutional Division’s delivery model to achieve scale

The Institutional Division has successfully used the federated architecture, and key to this delivery model is the implementation of Foundational Data & AI Platform capabilities that serve all domains within the division. This model promotes self-service and accelerates the delivery of subsequent initiatives by using the capabilities built for previous use cases.

To evaluate the success of the delivery model, ANZ has implemented key metrics, such as cost transparency and domain adoption, to guide the data mesh governance team in refining the delivery approach. For instance, one enhancement involves integrating cross-functional squads to support data literacy.

The key to scaling the Institutional Division operating model are the following considerations:

Data as a product approach – Use techniques like event storming and domain-driven design to capture business events and their meanings.
Education and enablement – Conduct learning interventions to upskill teams on understanding and using the data as a product approach.
Iterative data platform delivery – Work backward from business initiative to iteratively deliver self-service data platform infrastructure capabilities.
Managing demand efficiently – Implement a feedback mechanism to manage demand on data products. Track and manage data debt using standard data contract specifications. Most importantly, adopt governance and standards to make sure data products are built and maintained with a long-term perspective, minimizing technical debt.

“The Institutional Data & Analytics Platform (IDAP) has allowed the Institutional team to establish a base foundation to allow various teams to aggregate and consume the wealth of data across the division. This self-service platform enables business leaders to both create and consume reusable data products, unlocking value across this division. It’s also an excellent proof point for our broader data mesh architecture, allowing us to connect this divisional data to broader enterprise data stores—further positioning us to put the customer at the center of everything we do.”

– Tim Hogarth, CTO ANZ

“AWS believes that democratizing data, while not compromising on security and fine-grained access, is a key component of any future-proof, scalable data platform, so we are pleased to be enabling ANZ bank’s IDAP metadata management and data governance capabilities through Amazon DataZone. This allows the diverse business functions at ANZ the autonomy to self-serve on their data needs with built-in governance.”

– Shikha Verma, Head of Product, Amazon DataZone

Conclusion

ANZ’s journey to move towards a data product approach has improved the organization’s approach to manage data and reduce data silos, and has positioned it to become a data-driven, customer-centric organization. By combining federated platform practices and adopting AWS services and open standards, ANZ Institutional Division is achieving its objectives in decentralization with a scalable data platform that enables its domain teams to make informed decisions, drive innovation, and maintain a competitive edge.

Special thanks: This implementation success is a result of close collaboration between ANZ Institutional Division, AWS ProServe, and the AWS account team. We want to thank ANZ Institutional Executives and the Leadership Team for the strong sponsorship and direction.

About the Authors

Leo Ramsamy is a Platform Architect specializing in data and analytics for ANZ’s Institutional division. He focuses on modern data practices, including Data Mesh architecture, data governance, quality management, and observability. His work aligns data strategies with business goals, improving accessibility and enabling better decision-making across ANZ.

Srinivasan Kuppusamy is a Senior Cloud Architect – Data at AWS ProServe, where he helps customers solve their business problems using the power of AWS Cloud technology. His areas of interests are data and analytics, data governance, and AI/ML.

Rada Stanic is a Chief Technologist at Amazon Web Services, where she helps ANZ customers across different segments solve their business problems using AWS Cloud technologies. Her special areas of interest are data analytics, machine learning/AI, and application modernization.

Solve complex problems with new scenario analysis capability in Amazon Q in QuickSight

2024-12-04 Veliswa Boya

Post Syndicated from Veliswa Boya original https://aws.amazon.com/blogs/aws/solve-complex-problems-with-new-scenario-analysis-capability-in-amazon-q-in-quicksight/

Today, we announced a new capability of Amazon Q in QuickSight that helps users perform scenario analyses to find answers to complex problems quickly. This AI-assisted data analysis experience helps business users find answers to complex problems by guiding them step-by-step through in-depth data analysis—suggesting analytical approaches, automatically analyzing data, and summarizing findings with suggested actions—using natural language prompts. This new capability eliminates hours of tedious and error-prone manual work traditionally required to perform analyses using spreadsheets or other alternatives. In fact, Amazon Q in QuickSight enables business users to perform complex scenario analysis up to 10x faster than spreadsheets. This capability expands upon existing data Q&A capabilities of Amazon QuickSight so business professionals can start their analysis by simply asking a question.

How it works
Business users are often faced with complex questions that have traditionally required specialized training and days or weeks of time analyzing data in spreadsheets or other tools to address. For example, let’s say you’re a franchisee with multiple locations to manage. You might use this new capability in Amazon Q in QuickSight to ask, “How can I help our new Chicago store perform as well as the ﬂagship store in New York?” Using an agentic approach, Amazon Q would then suggest analytical approaches needed to address the underlying business goal, automatically analyze data, and present results complete with visualizations and suggested actions. You can conduct this multistep analysis in an expansive analysis canvas, giving you the ﬂexibility to make changes, explore multiple analysis paths simultaneously, and adapt to situations over time.

This new analysis experience is part of Amazon QuickSight meaning it can read from QuickSight dashboards which connect to sources such as Amazon Athena, Amazon Aurora, Amazon Redshift, Amazon Simple Storage Service (Amazon S3), and Amazon OpenSearch Service. Specifically, this new experience is part of Amazon Q in QuickSight, which allows it to seamlessly integrate with other generative business intelligence (BI) capabilities such as data Q&A. You can also upload either a .csv or a single-table, single-sheet .xlsx file to incorporate into your analysis.

Here’s a visual walkthrough of this new analysis experience in Amazon Q in QuickSight.

I’m planning a customer event, and I’ve received an Excel spreadsheet of all who’ve registered to attend the event. I want to learn more about the attendees, so I analyze the spreadsheet and ask a few questions. I start by describing what I want to explore.

I upload the spreadsheet to start my analysis. Firstly, I want to understand how many people have registered for the event.

To design an agenda that’s suitable for the audience, I want to understand the various roles that will be attending. I select on the + icon to add a new block for asking a question following along the thread from the previous block.

I can continue to ask more questions. However, there are suggested questions for analyzing my data even further, and I now select one of these suggested questions. I want to increase marketing efforts at companies that don’t currently have a lot of attendees in this case, companies with fewer than two attendees.

Amazon Q executes the required analysis and keeps me updated of the progress. Step 1 of the process identifies companies that have fewer than two attendees and lists them.

Step 2 gives an estimate of how many more attendees I might get from each company if marketing efforts are increased.

In Step 3 I can see the potential increase in total attendees (including the percentage increase) in line with the increase in marketing efforts.

Lastly, Step 4 goes even further to highlight companies I should prioritize for these increased marketing efforts.

To increase the potential number of attendees even more, I wanted to change the analysis to identify companies with fewer than three attendees instead of two attendees. I choose the AI sparkle icon in the upper right to launch a modal that I then use to provide more context and make specific changes to the previous result.

This change resulted in new projections, and I can choose to consider them for my marketing efforts or keep to the previous projections.

Now available
Amazon Q in QuickSight Pro users can use this new capability in preview in the following AWS Regions at launch: US East (N. Virginia) and US West (Oregon). Get started with a free 30-day trial of QuickSight today. To learn more, visit the Amazon QuickSight User Guide. You can submit your questions to AWS re:Post for Amazon QuickSight, or through your usual AWS Support contacts.

– Veliswa.

Unlock the potential of your supply chain data and gain actionable insights with AWS Supply Chain Analytics

2024-10-31 Donnie Prakoso

Post Syndicated from Donnie Prakoso original https://aws.amazon.com/blogs/aws/unlock-the-potential-of-your-supply-chain-data-and-gain-actionable-insights-with-aws-supply-chain-analytics/

Today, we’re announcing the general availability of AWS Supply Chain Analytics powered by Amazon QuickSight. This new feature helps you to build custom report dashboards using your data in AWS Supply Chain. With this feature, your business analysts or supply chain managers can perform custom analyses, visualize data, and gain actionable insights for your supply chain management operations.

Here’s how it looks:

AWS Supply Chain Analytics leverages the AWS Supply Chain data lake and provides Amazon QuickSight embedded authoring tools directly into the AWS Supply Chain user interface. This integration provides you with a unified and configurable experience for creating custom insights, metrics, and key performance indicators (KPIs) for your operational analytics.

In addition, AWS Supply Chain Analytics provides prebuilt dashboards that you can use as-is or modify based on your needs. At launch, you will have the following prebuilt dashboards:

Plan-Over-Plan Variance: Presents a comparison between two demand plans, showcasing variances in both units and values across key dimensions such as product, site, and time periods.
Seasonality Analytics: Presents a year-over-year view of demand, illustrating trends in average demand quantities and highlighting seasonality patterns through heatmaps at both monthly and weekly levels.

Let’s get started
Let me walk you through the features of AWS Supply Chain Analytics.

The first step is to enable AWS Supply Chain Analytics. To do this, navigate to Settings, then select Organizations and choose Analytics. Here, I can Enable data access for Analytics.

Now I can edit existing roles or create a new role with analytics access. To learn more, visit User permission roles.

Once this feature is enabled, when I log in to AWS Supply Chain I can access the AWS Supply Chain Analytics feature by selecting either the Connecting to Analytics card or Analytics on the left navigation menu.

Here, I have an embedded Amazon QuickSight interface ready for me to use. To get started, I navigate to Prebuilt Dashboards.

Then, I can select the prebuilt dashboards I need in the Supply Chain Function dropdown list:

What I like the most about this prebuilt dashboards is I can easily get started. AWS Supply Chain Analytics will prepare all the datasets, analysis, and even a dashboard for me. I select Add to begin.

Then, I navigate to the dashboard page, and I can see the results. I can also share this dashboard with my team, which improves the collaboration aspect.

If I need to include other datasets for me to build a custom dashboard, I can navigate to Datasets and select New dataset.

Here, I have AWS Supply Chain data lake as an existing dataset for me to use.

Next, I need to select Create dataset.

Then, I can select a table that I need to include into my analysis. On the Data section, I can see all available fields. All data sets that start with asc_ are generated by AWS Supply Chain, such as data from Demand Planning, Insights, Supply Planning, and others.

I can also find all the datasets I have ingested into AWS Supply Chain. To learn more on data entities, visit the AWS Supply Chain documentation page. One thing to note here is if I have not ingested data into AWS Supply Chain Data Lake, I need to ingest data before using AWS Supply Chain Analytics. To learn how to ingest data into the data lake, visit the data lake page.

At this stage, I can start my analysis.

Now available
AWS Supply Chain Analytics is now generally available in all regions where AWS Supply Chain is offered. Give it a try to experience and transform your operations with the AWS Supply Chain Analytics.

Happy building,
— Donnie

Analyze Amazon EMR on Amazon EC2 cluster usage with Amazon Athena and Amazon QuickSight

2024-10-25 Boon Lee Eu

Post Syndicated from Boon Lee Eu original https://aws.amazon.com/blogs/big-data/analyze-amazon-emr-on-amazon-ec2-cluster-usage-with-amazon-athena-and-amazon-quicksight/

Gaining granular visibility into application-level costs on Amazon EMR on Amazon Elastic Compute Cloud (Amazon EC2) clusters presents an opportunity for customers looking for ways to further optimize resource utilization and implement fair cost allocation and chargeback models. By breaking down the usage of individual applications running in your EMR cluster, you can unlock several benefits:

Informed workload management – Application-level cost insights empower organizations to prioritize and schedule workloads effectively. Resource allocation decisions can be made with a better understanding of cost implications, potentially improving overall cluster performance and cost-efficiency.
Cost optimization – With granular cost attribution, organizations can identify cost-saving opportunities for individual applications. They can right-size underutilized resources or prioritize optimization efforts for applications that are driving high usage and costs.
Transparent billing – In multi-tenant environments, organizations can implement fair and transparent cost allocation models based on individual application resource consumption and associated costs. This fosters accountability and enables accurate chargebacks to tenants.

In this post, we guide you through deploying a comprehensive solution in your Amazon Web Services (AWS) environment to analyze Amazon EMR on EC2 cluster usage. By using this solution, you will gain a deep understanding of resource consumption and associated costs of individual applications running on your EMR cluster. This will help you optimize costs, implement fair billing practices, and make informed decisions about workload management, ultimately enhancing the overall efficiency and cost-effectiveness of your Amazon EMR environment. This solution has been only tested on Spark workloads running on EMR on EC2 that uses YARN as its resource manager. It hasn’t been tested on workloads from other frameworks that run on YARN, such as HIVE or TEZ.

Solution overview

The solution works by running a Python script on the EMR cluster’s primary node to collect metrics from the YARN resource manager and correlate them with cost usage details from the AWS Cost and Usage Reports (AWS CUR). The script activated by a cronjob makes HTTP requests to the YARN resource manager to collect two types of metrics from paths /ws/v1/cluster/metrics for cluster metrics and /ws/v1/cluster/apps for application metrics. The cluster metrics contain utilization information of cluster resources, and the application metrics contain utilization information of an application or job. These metrics are stored in an Amazon Simple Storage Service (Amazon S3) bucket.

There are two YARN metrics that capture the resource utilization information of an application or job.

memorySeconds – This is the memory (in MB) allocated to an application times the number of seconds the application ran
vcoreSeconds – This is the number of YARN vcores allocated to an application times the number of seconds application ran

The solution uses memorySeconds to derive the cost of running the application or job. It can be modified to use vcoreSeconds instead if necessary.

The metadata of the YARN metrics collected in Amazon S3 is created, stored, and represented as database and tables in AWS Glue Data Catalog, which is in turn available to Amazon Athena for further processing. You can now write SQL queries in Athena to correlate the YARN metrics with the cost usage information from AWS CUR to derive the detailed cost breakdown of your EMR cluster by infrastructure and application. This solution creates two corresponding Athena views of the respective cost breakdown that will become the data source to Amazon QuickSight for visualization.

The following diagram shows the solution architecture.

EMR Cluster Usage Utility Solution Architecture

Prerequisites

To perform the solution, you need the following prerequisites:

Confirm that a CUR is created in your AWS account. It needs an S3 bucket to store the report files. Follow the steps described in Creating Cost and Usage Reports to create the CUR on the AWS Management Console. When creating the report, make sure the following settings are enabled:

- Include resource IDs
- Time granularity is set to hourly
- Report data integration to Athena

It can take up to 24 hours for AWS to start delivering reports to your S3 bucket. Thereafter, your CUR gets updated at least one time a day.

The solution needs Athena to run queries against the data from the CUR using standard SQL. To automate and streamline the integration of Athena with CUR, AWS provides an AWS CloudFormation template, crawler-cfn.yml, which is automatically generated in the same S3 bucket during CUR creation. Follow the instructions in Setting up Athena using AWS CloudFormation templates to integrate Athena with the CUR. This template will create an AWS Glue database that references to the CUR, an AWS Lambda event and an AWS Glue crawler that gets invoked by S3 event notification to update the AWS Glue database whenever the CUR gets updated.
Make sure to activate the AWS generated cost allocation tag, aws:elasticmapreduce:job-flow-id. This enables the field, resource_tags_aws_elasticmapreduce_job_flow_id, in the CUR to be populated with the EMR cluster ID and is used by the SQL queries in the solution. To activate the cost allocation tag from the management console, follow these steps:
- Sign in to the payer account’s AWS Management Console and open the AWS Billing and Cost Management console
- In the navigation pane, choose Cost Allocation Tags
- Under AWS generated cost allocation tags, choose the aws:elasticmapreduce:job-flow-id tag
- Choose Activate. It can take up to 24 hours for tags to activate.

The following screenshot shows an example of the aws:elasticmapreduce:job-flow-id tag being activated.

CostAllocationTag

You can now test out this solution on an EMR cluster in a lab environment. If you’re not already familiar with EMR, follow the detailed instructions provided in Tutorial: Getting started with Amazon EMR to launch a new EMR cluster and run a sample Spark job.

Deploying the solution

To deploy the solution, follow the steps in the next sections.

Installing scripts to the EMR cluster

Download two scripts from the GitHub repository and save them into an S3 bucket:

emr_usage_report.py – Python script that makes the HTTP requests to YARN Resource Manager
emr_install_report.sh – Bash script that creates a cronjob to run the python script every minute

To install the scripts, add a step to the EMR cluster through the console or AWS Command Line Interface (AWS CLI) using aws emr add-step command.

Replace:

REGION with the AWS Regions where the cluster is running (for example, Europe (Ireland) eu-west-1)
MY-BUCKET with the name of the bucket where the script is stored (for example, my.artifact.bucket)
MY_REPORT_BUCKET with the bucket name where you want to collect YARN metrics (for example, my.report.bucket)

aws emr add-steps \
--cluster-id j-XXXXXXXXXXXXX \
--steps Type=CUSTOM_JAR,Name="Install YARN reporter",Jar=s3://REGION.elasticmapreduce/libs/script-runner/script-runner.jar,Args=[s3://<MY-BUCKET>/emr-install_reporter.sh,s3://<MY-BUCKET>/emr_usage_reporter.py,MY_REPORT_BUCKET]

You can now run some Spark jobs on your EMR cluster to start generating application usage metrics.

Launching the CloudFormation stack

When the prerequisites are met and you have the scripts deployed so that your EMR clusters are sending YARN metrics to an S3 bucket, the rest of the solution can be deployed using CloudFormation.

Before launching the stack, upload a copy of this QuickSight definition file into an S3 bucket required by the CloudFormation template to build the initial analysis in QuickSight. When ready, proceed to launch your stack to provision the remaining resources of the solution.

Choose

This automatically launches AWS CloudFormation in your AWS account with a template. It prompts you to sign in as needed and make sure you create the stack in your intended Region.

The CloudFormation stack requires a few parameters, as shown in the following screenshot.

CloudFormationStack

The following table describes the parameters.

Parameter	Description
Stack name	A meaningful name for the stack; for example, `EMRUsageReport`
S3 configuration
`YARNS3BucketName`	Name of S3 bucket where YARN metrics are stored
Cost Usage Report configuration
`CURDatabaseName`	Name of Cost Usage Report database in AWS Glue
`CURTableName`	Name of Cost Usage Report table in AWS Glue
AWS Glue Database configuration
`EMRUsageDBName`	Name of AWS Glue database to be created for the EMR Cost Usage Report
`EMRInfraTableName`	Name of AWS Glue table to be created for infrastructure usage metrics
`EMRAppTableName`	Name of AWS Glue table to be created for application usage metrics
QuickSight configuration
`QSUserName`	Name of QuickSight user in default namespace to manage the EMR Usage Report resources in QuickSight.
`QSDefinitionsFile`	S3 URI of the definition JSON file for the EMR Usage Report.

Enter the parameter values from the preceding table.
Choose Next.
On the next screen, enter any necessary tags, an AWS Identity and Access Management (IAM) role, stack failure, or advanced options if necessary. Otherwise, you can leave them as default.
Choose Next.
Review the details on the final screen and select the check boxes confirming AWS CloudFormation might create IAM resources with custom names or require CAPABILITY_AUTO_EXPAND.
Choose Create.

The stack will take a couple of minutes to create the remaining resources for the solution. After the CloudFormation stack is created, on the Outputs tab, you can find the details of the resources created.

Reviewing the correlation results

The CloudFormation template creates two Athena views containing the correlated cost breakdown details of the YARN cluster and application metrics with the CUR. The CUR aggregates cost hourly and therefore correlation to derive the cost of running an application is prorated based on the hourly running cost of the EMR cluster.

The following screenshot shows the Athena view for the correlated cost breakdown details of YARN cluster metrics.

CorrelationResults

The following table describes the fields in the Athena view for YARN cluster metrics.

Field	Type	Description
`cluster_id`	string	ID of the cluster.
`family`	string	Resource type of the cluster. Possible values are compute instance, elastic map reduce instance, storage and data transfer.
`billing_start`	timestamp	Start billing hour of the resource.
`usage_type`	string	A specific type or unit of the resource such as BoxUsage:m5.xlarge of compute instance.
`cost`	string	Cost associated with the resource.

The following screenshot shows the Athena view for the correlated cost breakdown details of YARN application metrics.

CostBreakdownYARNAppMetrics

The following table describes the fields in the Athena view for YARN application metrics.

Field	Type	Description
`cluster_id`	string	ID of the cluster
`id`	string	Unique identifier of the application run
`user`	string	User name
`name`	string	Name of the application
`queue`	string	Queue name from YARN resource manager
`finalstatus`	string	Final status of application
`applicationtype`	string	Type of the application
`startedtime`	timestamp	Start time of the application
`finishedtime`	timestamp	End time of the application
`elapsed_sec`	double	Time taken to run the application
`memoryseconds`	bigint	The memory (in MB) allocated to an application times the number of seconds the application ran
`vcoreseconds`	int	The number of YARN vcores allocated to an application times the number of seconds application ran
`total_memory_mb_avg`	double	Total amount of memory (in MB) available to the cluster in the hour
`memory_sec_cost`	double	Derived unit cost of memoryseconds
`application_cost`	double	Derived cost associated with the application based on memoryseconds
`total_cost`	double	Total cost of resources associated with the cluster for the hour

Building your own visualization

In QuickSight, the CloudFormation template creates two datasets that reference Athena views as data sources and a sample analysis. The sample analysis has two sheets, EMR Infra Spend and EMR App Spend. They have a prepopulated bar chart and pivot tables to demonstrate how you can use the datasets to build your own visualization to present the cost breakdown details of your EMR clusters.

EMR Infra Spend sheet references to the YARN cluster metrics dataset. There is a filter for date range selection and a filter for cluster ID selection. The sample bar chart shows the consolidated cost breakdown of the resources for each cluster during the period. The pivot table breaks them down further to show their daily expenditure.

The following screenshot shows the EMR Infra Spend sheet from sample analysis created by the CloudFormation template.

EMR App Spend sheet references to the YARN application metrics. There is a filter for date range selection and a filter for cluster ID selection. The pivot table in this sheet shows how you can use the fields in the dataset to present the cost breakdown details of the cluster by users to observe the applications that were run, whether they were completed successfully or not, the time and duration of each run, and the derived cost of the run.

The following screenshot shows the EMR App Spend sheet from sample analysis created by the CloudFormation template.

Cleanup

If you no longer need the resources you created during this walkthrough, delete them to prevent incurring additional charges. To clean up your resources, complete the following steps:

On the CloudFormation console, delete the stack that you created using the template
Terminate the EMR cluster
Empty or delete the S3 bucket used for YARN metrics

Conclusion

In this post, we discussed how to implement a comprehensive cluster usage reporting solution that provides granular visibility into the resource consumption and associated costs of individual applications running on your Amazon EMR on EC2 cluster. By using the power of Athena and QuickSight to correlate YARN metrics with cost usage details from your Cost and Usage Report, this solution empowers organizations to make informed decisions. With these insights, you can optimize resource allocation, implement fair and transparent billing models based on actual application usage, and ultimately achieve greater cost-efficiency in your EMR environments. This solution will help you unlock the full potential of your EMR cluster, driving continuous improvement in your data processing and analytics workflows while maximizing return on investment.

About the authors

Boon Lee Eu is a Senior Technical Account Manager at Amazon Web Services (AWS). He works closely and proactively with Enterprise Support customers to provide advocacy and strategic technical guidance to help plan and achieve operational excellence in AWS environment based on best practices. Based in Singapore, Boon Lee has over 20 years of experience in IT & Telecom industries.

Kyara Labrador is a Sr. Analytics Specialist Solutions Architect at Amazon Web Services (AWS) Philippines, specializing in big data and analytics. She helps customers in designing and implementing scalable, secure, and cost-effective data solutions, as well as migrating and modernizing their big data and analytics workloads to AWS. She is passionate about empowering organizations to unlock the full potential of their data.

Vikas Omer is the Head of Data & AI Solution Architecture for ASEAN at Amazon Web Services (AWS). With over 15 years of experience in the data and AI space, he is a seasoned leader who leverages his expertise to drive innovation and expansion in the region. Vikas is passionate about helping customers and partners succeed in their digital transformation journeys, focusing on cloud-based solutions and emerging technologies.

Lorenzo Ripani is a Big Data Solution Architect at AWS. He is passionate about distributed systems, open source technologies and security. He spends most of his time working with customers around the world to design, evaluate and optimize scalable and secure data pipelines with Amazon EMR.

Create security observability using generative AI with Security Lake and Amazon Q in QuickSight

2024-09-16 Priyank Ghedia

Post Syndicated from Priyank Ghedia original https://aws.amazon.com/blogs/security/create-security-observability-using-generative-ai-with-security-lake-and-amazon-q-in-quicksight/

Generative artificial intelligence (AI) is now a household topic and popular across various public applications. Users enter prompts to get answers to questions, write code, create images, improve their writing, and synthesize information. As people become familiar with generative AI, businesses are looking for ways to apply these concepts to their enterprise use cases in a simple, scalable, and cost-effective way. These same needs are shared by a variety of security stakeholders. For example, if security directors want to summarize their security posture in natural language, a security architect will need to triage alerts or findings and investigate AWS CloudTrail logs to identify high priority remediation actions or detect potential threat actors by identifying potentially malicious activity. There are many ways to deploy solutions for these use cases.

In this blog post, we review a fully serverless solution for querying data stored in Amazon Security Lake using natural language (human language) with Amazon Q in QuickSight. This solution has multiple use cases, such as generating visualizations and querying vulnerability information for vulnerability management using tools such as Amazon Inspector that feed into AWS Security Hub. The solution helps reduce the time from detection to investigation by using natural language to query CloudTrail logs and Amazon Virtual Private Cloud (VPC) Flow Logs, resulting in quicker response to threats in your environment.

Amazon Security Lake is a fully managed security data lake service that automatically centralizes security data from AWS environments, software as a service (SaaS) providers, and on-premises and cloud sources into a purpose-built data lake that’s stored in your AWS account. The data lake is backed by Amazon Simple Storage Service (Amazon S3) buckets, and you retain ownership over your data. Security Lake converts ingested data into Apache Parquet format and a standard open source schema called the Open Cybersecurity Schema Framework (OCSF). With OCSF support, Security Lake normalizes and combines security data from AWS and a broad range of enterprise security data sources.

Amazon QuickSight is a cloud-scale business intelligence (BI) service that delivers insights to stakeholders, wherever they are. QuickSight connects to your data in the cloud and combines data from a variety of different sources. With QuickSight, users can meet varying analytic needs from the same source of truth through interactive dashboards, reports, natural language queries, and embedded analytics. With Amazon Q in QuickSight, business analysts and users can use natural language to build, discover, and share meaningful insights.

The recent announcements for Amazon Q in QuickSight, Security Lake, and the OCSF present a unique opportunity to apply generative AI to fully managed hybrid multi-cloud security related logs and findings from over 100 independent software vendors and partners.

Solution overview

The solution uses Security Lake as the data lake which has native ingestion for CloudTrail, VPC Flow Logs, and Security Hub findings as shown in Figure 1. Logs from these sources are sent to S3 buckets in your AWS account and are maintained by Security Lake. We then create Amazon Athena views from tables created by Security Lake for Security Hub findings, CloudTrail logs, and VPC Flow Logs to define the interesting fields from each of the log sources. Each of these views are ingested into a QuickSight dataset. From these datasets, we generate analyses and dashboards. We use Amazon Q topics to label columns in the dataset that are human-readable and create a named entity to present contextual and multi-visual answers in response to questions. After the topics are created, users can perform their analysis using Q topics, QuickSight analyses, or QuickSight dashboards.

Figure 1: Solution architecture

You can use the rollup AWS Region feature in Security Lake to aggregate logs from multiple Regions into a single Region. Specifying a rollup Region can help you adhere to regional compliance requirements. If you use rollup Regions, you must set up the solution described in this post for datasets only in rollup Regions. If you don’t use a rollup Region, you must deploy this solution for each Region you that want to collect data from.

Prerequisites

To implement the solution described in this post, you must meet the following requirements:

Basic understanding of Security Lake, Athena, and QuickSight.
Security Lake is already deployed and accepting CloudTrail management events, VPC Flow Logs, and Security Hub findings as sources. If you haven’t deployed Security Lake yet, we recommend following the best practices established in the security reference architecture.
This solution uses Security Lake data source version 2 to create the dashboards and visualizations. If you aren’t already using data source version 2, you will see a banner in your Security Lake console with instructions to update.
An existing QuickSight deployment that will be used to visualize Security Lake data or an account that is able to sign up for QuickSight to create visualizations.
QuickSight Author Pro and Reader Pro licenses are needed for using Amazon Q features in QuickSight. Non-pro Authors and Readers can still access Q topics if an Author Pro or Admin Pro user shares the topic with them. Non-pro Authors and Readers can also access data stories if a Reader Pro, Author Pro, or Admin Pro shares one with them. Review Generative AI features supported by each QuickSight licensing tiers.
AWS Identity and Access Manager (IAM) permissions for QuickSight, Athena, Lake Formation, Security Lake, and AWS Resource Access Manager.

In the following section, we walk through the steps to ingest Security Lake data into QuickSight using Athena views and then using Amazon Q in QuickSight to create visualizations and query data using natural language.

Provide cross-account query access

In alignment with our security reference architecture, it’s a best practice to isolate the Security Lake account from the accounts that are running the visualization and querying workloads. It’s recommended that QuickSight for security use cases be deployed in the security tooling account. See How to visualize Amazon Security Lake findings with Amazon QuickSight for information on how to set up cross-account query access. Follow the steps in the Configure a Security Lake subscriber section and configure Athena to visualize your data section.

When you get to the create resource link steps, create a resource link for data source version 2 for Security Hub, CloudTrail, and VPC flow log tables for a total of three resource links. The way to identify data source version 2 tables is by their name; it ends in _2_0. For example:

amazon_security_lake_table_us_east_1_sh_findings_2_0
amazon_security_lake_table_us_east_1_cloud_trail_mgmt_2_0
amazon_security_lake_table_us_east_1_vpc_flow_2_0

For the remainder of this post, we will be referencing the database name security_lake_visualization and the resource link names for Security Hub findings, CloudTrail logs, and VPC Flow Logs respectively, as shown in Figure 2:

securitylake_shared_resourcelink_securityhub_2_0_us_east_1
securitylake_shared_resourcelink_cloudtrail_2_0_us_east_1
securitylake_shared_resourcelink_vpcflow_2_0_us_east_1

Figure 2: Lake Formation table snapshot

We will call the QuickSight account the visualization account. If you plan to use same account as the Security Lake delegated administrator and QuickSight, then skip this step and go to the next section where you will create views in Athena.

Create views in Athena

A view in Athena is a logical table that helps simplify your queries by working with only a subset of the relevant data. Follow these steps to create three views in Athena, one each for Security Hub findings, CloudTrail logs, and the VPC Flow Logs in the visualization account.

These queries default to the previous week’s data starting from the previous day, but you can change the time frame by modifying the last line in the query from 8 to the number of days you prefer. Keep in mind that there is a limitation on the size of each SPICE table of 1 TB. If you want to limit the volume of data, you can delete the rows that you find unnecessary. We included the fields customers have identified as relevant to reduce the burden of writing the parsing details yourself.

To create views:

Sign in to the AWS Management Console in the visualization account and navigate to the Athena console.
If a Security Lake rollup Region is used, select the rollup Region.
Choose Launch Query Editor.
If this is the first time you’re using Athena, you will need to choose a bucket to store your query results.
1. Choose Edit Settings.
2. Choose Browse S3.
3. Search for your bucket name.
4. Select the radio button next to the name of your bucket.
5. Select Choose.
For Data Source, select AWSDataCatalog.
Select Database as security_lake_visualization. If you used a different name for the database for cross account query access, then select that database.

Figure 3: Athena database selection
Copy the query for the security_hub_view from the GitHub repo for this post. If you’re using a different name for the database and table resource link than the one specified in this post, edit the FROM statement at the bottom of the query to reflect the correct names.
Paste the query in the query editor and then choose Run. The name of the view is set in the first line of the query which is security_insights_security_hub_vw2.
To confirm this view was created correctly, choose the three dots next to the view that was created and select Preview View.

Figure 4: Previewing the view
Repeat steps 5–9 to create the CloudTrail and VPC Flow Logs views. The queries for each can be found in the GitHub repo.

Figure 5: Athena views

Create QuickSight dataset

Now that you’ve created the views, use Athena as the data source to create a dataset in QuickSight. Repeat these steps for the Security Hub findings, CloudTrail logs, and VPC Flow Logs. Start by creating a dataset for the Security Hub findings.

To configure permissions on tables:

Sign in to the QuickSight console in the visualization account. If a Security Lake rollup Region is used, select the rollup Region.
If this is the first time you’re using QuickSight, you must sign up for a QuickSight subscription.
Although there are multiple ways to sign in to QuickSight, we used IAM based access to build the dashboards. To use QuickSight with Athena and Lake Formation, you first need to authorize connections through Lake Formation.
When using a cross-account configuration with AWS Glue Data Catalog, you need to configure permissions on tables that are shared through Lake Formation. For the use case in this post, use the following steps to grant access on the cross-account tables in the Glue Catalog. You must perform these steps for each of the Security Hub, CloudTrail, and VPC Flow Logs tables that you created in the preceding cross-account query access section. Because granting permissions on a resource link doesn’t grant permissions on the target (linked) database or table, you will grant permission twice, once to the target (linked table) and then to the resource link.
1. In the Lake Formation console, navigate to the Tables section and select the resource link for the Security Hub table. For example:
  securitylake_shared_resourcelink_securityhub_2_0_us_east_1
2. Select Actions. Under Permissions, select Grant on target.
3. For the next step, you need the Amazon Resource Name (ARN) of the QuickSight users or groups that need access to the table. To obtain the ARN through the AWS Command Line Interface (AWS CLI), run following commands (replacing account ID and Region with that of the visualization account.) You can use AWS CloudShell for this purpose.
  1. For users
    aws quicksight list-users --aws-account-id 111122223333 --namespace default --region us-east-1
  2. For groups
    aws quicksight list-groups --aws-account-id 111122223333 --namespace default --region us-east-1
4. After you have the ARN of the user or group, copy it and go back to the LakeFormation console Grant on Target page. For Principals, select SAML users and groups, and then add the QuickSight user’s ARN.
  
  Figure 6: Selecting principals
5. For LF-Tags or catalog resources, keep the default settings.
  
  Figure 7: Table grant on target permissions
6. For Table permissions, select Select for both Table Permissions and Grantable Permissions, and then choose Grant.
  
  Figure 8: Selecting table permissions
7. Navigate back to the Tables section and select the resource link for the Security Hub table. For example:
  securitylake_shared_resourcelink_securityhub_2_0_us_east_1
8. Select Actions. This time under Permissions, and then choose Grant.
9. For Principals, select SAML users and groups, and then add the QuickSight user’s ARN captured earlier.
10. For the LF-Tags or catalog resources section, use the default settings.
11. For Resource link permissions choose Describe for both Table Permissions and Grantable Permissions.
12. Repeat steps a–k for the CloudTrail and VPC Flow Logs resource links.

To create datasets from views:

After permissions are in place, you create three datasets from the views created earlier. Because both Quicksight and Lake Formation are Regional services, verify that you’re using QuickSight in the same Region where Lake Formation is sharing the data. The simplest way to determine your Region is to check the QuickSight URL in your web browser. The Region will be at the beginning of the URL, such as us-east-1. To change the Region, select the settings icon in the top right of the QuickSight screen and select the correct Region from the list of available Regions in the drop-down menu.
Navigate back to the QuickSight console.
Select Datasets, and then choose New dataset.
Select Athena from the list of available data sources.
Enter a Data source name, for example security_lake_securityhub_dataset and leave the Athena workgroup as [primary]. Choose Create data source.
At the Choose your table prompt, for Catalog, select AwsDataCatalog. For Database, select security_lake_visualization. If you used a different name for the database for cross-account query access, then select that database. For Tables, select the view name security_insights_security_hub_vw2 to build your dashboards for Security Hub findings. Then choose Select.

Figure 9: Choose a table during QuickSight dataset creation
At the Finish dataset creation prompt, select Import to SPICE for quicker analytics. Choose Visualize. This will create a new dataset in QuickSight using the name of the Athena view, which is security_insights_security_hub_vw2. You will be taken to the Analysis page, exit out of it.
Go back to the QuickSight console and repeat steps 3–8 for the CloudTrail and VPC Flow Log datasets.

Create a topic

Now that you have created a dataset, you can create a topic. Q topics are collections of one or more datasets that represent a subject area for your business users to ask questions. Topics allow users to ask questions in natural language and to build visualizations using natural language.

To create a Q topic:

Navigate to the QuickSight console.
Choose Topics in the left navigation pane.

Figure 10: QuickSight navigation pane
Choose New topic. Create one topic each for the Security Hub findings, CloudTrail logs, and VPC Flow Logs

Figure 11: QuickSight topic creation
On the New topic page, do the following:
1. For Topic name, enter a descriptive name for the topic. Name the first one SecurityHubTopic. Your business users will identify the topic by this name and use it to ask questions.
2. For Description, enter a description for the topic. Your users can use this description to get more details about the topic.
3. Choose Continue.
On the Add data to topic page, choose the dataset you created in the Create a QuickSight dataset section. Start with the Security Hub dataset security_insights_security_hub_vw2.
Choose Continue. It will take a few minutes to create the topic.
Now that your topic has been created, navigate to the Data tab of the topic.
Your Data Fields sub-tab should be selected already. If not, choose Data Fields.

Figure 12: Topics data fields
For each of the fields in the list, turn on Include to make sure that all fields are included. For this example, we selected all fields, but you can adjust the included columns as needed for your use case. Note, you might see a banner at the top of the page indicating that the indexing is in progress. Depending on the size of your data, it might take some time for Q to make those fields available for querying. Most of the time, indexing is complete in less than 15 minutes.
Review the Synonyms column. These alternate representations of your column name are automatically generated by Amazon Q. You can add and remove synonyms as needed for your use case.
At this point, you’re ready to ask questions about your data using Amazon Q in QuickSight. Choose Ask a question about SecurityHubTopic at the top of the page.

Figure 13: Ask questions using Q
You can now ask questions about Security Hub findings in the prompt. Enter Show me findings with compliance status failed along with control id.

Figure 14: Q answers
Under the question, you will see how it was interpreted by QuickSight.
Repeat steps 1–13 to create CloudTrail and VPC Flow Log QuickSight topics.

Create named entities for your topics

Now that you’ve created your topics, you will now add named entities. Named entities are optional, but we’re using them in the solution to help make queries more effective. The information contained in named entities, the ordering of fields, and their ranking make it possible to present contextual, multi-visual answers in response to even vague questions.

To create a named entity:

In the QuickSight console, navigate to Topics.
Select the Security Hub topic that you created in the previous section.
Under the Data tab, select the Named Entity subtab, and choose Add Named Entity.

Figure 15: Named entity subtab
Enter Security Findings as the entity name.
Select the following datafields: Status, Metadata Product Name, Finding Info Title, Region, Severity, Cloud Account Uid, Time Dt, Compliance Status, and AccountId. The order of the fields helps Q to prioritize the data, so rearrange your data fields as needed.

Figure 16: Security hub finding names entity creation
Choose Save in the top right corner to save your results.
Repeat steps 1–6 with the CloudTrail dataset using the following datafields: API operation, Time Dt, Region, Status, AccountId, API Response Error, Actor User Credential Uid, Actor User Name, Actor User Type, Api Service Name, Actor Idp Name, Cloud Provider, Session Issuer, and Unmapped.

Figure 17: CloudTrail named entity creation
Repeat steps 1–6 with the VPC Flow Log dataset using the following datafields: Src Endpoint IP, Src Endpoint Port, Dst Endpoint IP, Dst Endpoint Port, Connection Info Direction, Traffic Bytes, Action, Accountid, Time Dt, and Region.

Figure 18: VPC Flow log named entity creation

Create visualizations using natural language

After your topic is done indexing, you can start creating visualizations using natural language. In QuickSight, an analysis is the same thing as a dashboard, but is only accessible by the authors. You can keep it private and make it as robust and detailed as you want. When you decide to publish it, the shared version is called a dashboard.

To create visualizations:

Open the QuickSight console and navigate to the Analysis tab.
In the top right, select New analysis.
Select the dataset you created previously, it will have the same naming convention as the Athena view. For reference, the Athena view query created a Security Hub dataset called security_insights_security_hub_vw2.
Validate the information about the data set you’re going to use in the analysis and choose USE IN ANALYSIS.
On the pop up, select the interactive sheet option and choose Create.
For datasets that have a corresponding Q topic, which you created in a previous step, choose Build visual at the top of the screen.

Figure 19: Build visual using natural language
Enter your prompt and choose BUILD. For example, enter findings with product security hub group by control id include count. Q automatically generates a visualization.

Figure 20: Q response
To add to your dashboard, choose ADD TO ANALYSIS to see your new visualization module in your current analysis.
The supplied questions are targeted towards a Security Hub findings topic, where you can ask questions about your security hub findings data. For example, show all Security Hub findings for critical severity for a specific resource or ARN.
If you use Amazon Inspector for software vulnerability management and you want to monitor top common vulnerabilities and exposures (CVEs) affecting your organization, choose Build visual and enter show all ACTIVE findings with product inspector group by Title add count in the prompt. We used the keyword ACTIVE because ACTIVE is a finding state in Security Hub that indicates the finding is still active as per the finding source and Amazon Inspector has not closed the finding yet. If Amazon Inspector has closed the finding, the finding will have a state of ARCHIVED.

Figure 21: Q Response for an Amazon Inspector findings question
After you add visualization to the analysis, you can customize it further using various QuickSight visualization options.
To add the remaining datasets, which allows you to visualize data from multiple datasets in a single view, select the dropdown in the left navigation under Dataset.
1. Select Add a new dataset.
2. Search the name of the remaining datasets you created previously.
3. Select anywhere on the name of the dataset to make the radial button blue for the single dataset you want to add. Choose Select.
Repeat steps 7–12 in this section to add all the corresponding datasets you created previously.

Note: When you add additional datasets to the same Analysis and use Build visual to generate visualizations using natural language, the corresponding datasets with Q Topics are populated in the drop down under the prompt. Be sure to choose the correct dataset when asking questions.

Figure 22: Choosing a QuickSight dataset

To create dashboards:

After you’ve created the visual and are ready to publish the analysis as a dashboard, select PUBLISH in the top right corner.
1. Enter a name for your dashboard.
2. Choose Publish Dashboard.
After your dashboard is published, your users can ask questions about the data through the dashboard as well. This dashboard can be shared with other users. Users with QuickSight Reader Pro licenses can ask questions using Amazon Q.

To ask questions using the dashboard:

Navigate to the Dashboards section on the left navigation.
Select the dashboard you previously published.
Select Ask a question about [Topic Name] at the top of the screen. A module will open from the side of your screen. Questions can only be addressed to a single topic. To change the topic, select the name of the topic and a drop-down will appear. Select the name of the current topic to see other options and select the topic you want to ask a question about. For this example, select CloudTrailTopic.

Figure 23: Selecting a topic
Enter a question in the prompt. For this example, enter show top API operations in the last 24 hours with accessdenied.

Figure 24: CloudTrail question 1
Enter show all activity by user johndoe in the last 3 days.

Figure 25: CloudTrail question 2
Q will automatically build a small dashboard based on the questions provided.
Now change the topic to VPCFlowTopic as described in step 3.
Enter show me the top 5 dst ip by bytes for outbound traffic with dst port 443.

Figure 26: VPC Flow Log question

You can build executive summaries using QuickSight data stories, which also use generative AI. Data stories use Amazon Q prompts and visuals to produce a draft that incorporates the details that you provide. For example, you can create a data story about how a specific CVE affects your organization by asking Q questions, then add visuals from analyses you already created.

Conclusion

In this blog post, you learned how to use generative AI for your security use cases. We showed you how to use cross-account query access to allow a QuickSight visualization account to subscribe to Security Lake data for Security Hub findings, CloudTrail logs, and VPC Flow Logs. We then provided instructions for creating, Athena views, QuickSight datasets, Q topics, named entities, and for using natural language to build dashboards and query your data. You can customize the Athena views to create, update, or delete columns and column names as needed for your use case. You can also customize the Q topics and named entities to use naming conventions and structure responses based on your organization’s needs.

If you have feedback about this post, submit comments in the Comments section below. If you have questions about this post, contact AWS Support.

AWS Weekly Roundup: AWS Parallel Computing Service, Amazon EC2 status checks, and more (September 2, 2024)

2024-09-02 Esra Kayabali

Post Syndicated from Esra Kayabali original https://aws.amazon.com/blogs/aws/aws-weekly-roundup-aws-parallel-computing-service-amazon-ec2-status-checks-and-more-september-2-2024/

With the arrival of September, AWS re:Invent 2024 is now 3 months away and I am very excited for the new upcoming services and announcements at the conference. I remember attending re:Invent 2019, just before the COVID-19 pandemic. It was the biggest in-person re:Invent with 60,000+ attendees and it was my second one. It was amazing to be in that atmosphere! Registration is now open for AWS re:Invent 2024. Come join us in Las Vegas for five exciting days of keynotes, breakout sessions, chalk talks, interactive learning opportunities, and career-changing connections!

Now let’s look at the last week’s new announcements.

Last week’s launches
Here are the launches that got my attention.

Announcing AWS Parallel Computing Service – AWS Parallel Computing Service (AWS PCS) is a new managed service that lets you run and scale high performance computing (HPC) workloads on AWS. You can build scientific and engineering models and run simulations using a fully managed Slurm scheduler with built-in technical support and a rich set of customization options. Tailor your HPC environment to your specific needs and integrate it with your preferred software stack. Build complete HPC clusters that integrates compute, storage, networking, and visualization resources, and seamlessly scale from zero to thousands of instances. To learn more, visit AWS Parallel Computing Service and read Channy’s blog post.

Amazon EC2 status checks now support reachability health of attached EBS volumes – You can now use Amazon EC2 status checks to directly monitor if the Amazon EBS volumes attached to your instances are reachable and able to complete I/O operations. With this new status check, you can quickly detect attachment issues or volume impairments that may impact the performance of your applications running on Amazon EC2 instances. You can further integrate these status checks within Auto Scaling groups to monitor the health of EC2 instances and replace impacted instances to ensure high availability and reliability of your applications. Attached EBS status checks can be used along with the instance status and system status checks to monitor the health of your instances. To learn more, refer to the Status checks for Amazon EC2 instances documentation.

Amazon QuickSight now supports sharing views of embedded dashboards – You can now share views of embedded dashboards in Amazon QuickSight. This feature allows you to enable more collaborative capabilities in your application with embedded QuickSight dashboards. Additionally, you can enable personalization capabilities such as bookmarks for anonymous users. You can share a unique link that displays only your changes while staying within the application, and use dashboard or console embedding to generate a shareable link to your application page with QuickSight’s reference encapsulated using the QuickSight Embedding SDK. QuickSight Readers can then send this shareable link to their peers. When their peer accesses the shared link, they are taken to the page on the application that contains the embedded QuickSight dashboard. For more information, refer to Embedded view documentation.

Amazon Q Business launches IAM federation for user identity authentication – Amazon Q Business is a fully managed service that deploys a generative AI business expert for your enterprise data. You can use the Amazon Q Business IAM federation feature to connect your applications directly to your identity provider to source user identity and user attributes for these applications. Previously, you had to sync your user identity information from your identity provider into AWS IAM Identity Center, and then connect your Amazon Q Business applications to IAM Identity Center for user authentication. At launch, Amazon Q Business IAM federation will support the OpenID Connect (OIDC) and SAML2.0 protocols for identity provider connectivity. To learn more, visit Amazon Q Business documentation.

Amazon Bedrock now supports cross-Region inference – Amazon Bedrock announces support for cross-Region inference, an optional feature that enables you to seamlessly manage traffic bursts by utilizing compute across different AWS Regions. If you are using on-demand mode, you’ll be able to get higher throughput limits (up to 2x your allocated in-Region quotas) and enhanced resilience during periods of peak demand by using cross-Region inference. By opting in, you no longer have to spend time and effort predicting demand fluctuations. Instead, cross-Region inference dynamically routes traffic across multiple Regions, ensuring optimal availability for each request and smoother performance during high-usage periods. You can control where your inference data flows by selecting from a pre-defined set of Regions, helping you comply with applicable data residency requirements and sovereignty laws. Find the list at Supported Regions and models for cross-Region inference. To get started, refer to the Amazon Bedrock documentation or this Machine Learning blog.

For a full list of AWS announcements, be sure to keep an eye on the What’s New at AWS page.

We launched existing services and instance types in additional Regions:

Amazon EC2 C6gd and R6gd instances are now available in AWS Europe (Spain) Region. C6gd instances are ideal for compute-intensive workloads such as high performance computing (HPC), batch processing, and CPU-based machine learning inference. R6gd instances are built for running memory-intensive workloads such as open-source databases, in-memory caches, and real time big data analytics.
Amazon OpenSearch Serverless now available in the AWS GovCloud (US-West) Region. OpenSearch Serverless is a serverless deployment option for Amazon OpenSearch Service that makes it simple to run search and analytics workloads without the complexities of infrastructure management.
AWS Global Accelerator launches new edge location in Cairo, Egypt. AWS Global Accelerator is a networking service that helps you improve the availability and performance of the applications that you offer to your global users.
Amazon Redshift Serverless is now available in the AWS Asia Pacific (Jakarta) Region. Amazon Redshift Serverless is a serverless option of Amazon Redshift that makes it more efficient to run and scale analytics in seconds without the need to set up and manage data warehouse infrastructure.
Amazon OpenSearch Service now supports Graviton3 (C7g, M7g, R7g, R7gd) instances. Amazon OpenSearch Service now supports AWS Graviton3 instances, which deliver up to 25% better performance over Graviton2-based instances.
AWS Config conformance packs now available in 12 additional AWS Regions. Conformance packs allow you to bundle AWS Config rules and their associated remediation actions into a single package, simplifying deployment at scale. These capabilities have been added to the following Regions: Asia Pacific (Jakarta), Africa (Cape Town), Middle East (UAE), Asia Pacific (Hyderabad), Asia Pacific (Osaka), Europe (Milan), Israel (Tel Aviv), Canada West (Calgary), Europe (Spain), Europe (Zurich), AWS GovCloud (US-East), and AWS GovCloud (US-West).

Other AWS events
AWS GenAI Lofts are collaborative spaces and immersive experiences that showcase AWS’s cloud and AI expertise, while providing startups and developers with hands-on access to AI products and services, exclusive sessions with industry leaders, and valuable networking opportunities with investors and peers. Find a GenAI Loft location near you and don’t forget to register.

credit: Antje Barth

Upcoming AWS events
Check your calendar and sign up for upcoming AWS events:

AWS Summits are free online and in-person events that bring the cloud computing community together to connect, collaborate, and learn about AWS. AWS Summits for this year are coming to an end. There are 3 more left that you can still register: Jakarta (September 5), Toronto (September 11), and Ottawa (October 9).

AWS Community Days feature technical discussions, workshops, and hands-on labs led by expert AWS users and industry leaders from around the world. While AWS Summits 2024 are almost over, AWS Community Days are in full swing. Upcoming AWS Community Days are in Belfast (September 6), SF Bay Area (September 13), where our own Antje Barth is a keynote speaker, Argentina (September 14), and Armenia (September 14).

Browse all upcoming AWS led in-person and virtual events here.

That’s all for this week. Check back next Monday for another Weekly Roundup!

— Esra

This post is part of our Weekly Roundup series. Check back each week for a quick roundup of interesting news and announcements from AWS!

Set up cross-account AWS Glue Data Catalog access using AWS Lake Formation and AWS IAM Identity Center with Amazon Redshift and Amazon QuickSight

2024-08-05 Poulomi Dasgupta

Post Syndicated from Poulomi Dasgupta original https://aws.amazon.com/blogs/big-data/set-up-cross-account-aws-glue-data-catalog-access-using-aws-lake-formation-and-aws-iam-identity-center-with-amazon-redshift-and-amazon-quicksight/

Most organizations manage their workforce identity centrally in external identity providers (IdPs) and are comprised of multiple business units that produce their own datasets and manage the lifecycle spread across multiple AWS accounts. These business units have varying landscapes, where a data lake is managed by Amazon Simple Storage Service (Amazon S3) and analytics workloads are run on Amazon Redshift, a fast, scalable, and fully managed cloud data warehouse that allows you to process and run your complex SQL analytics workloads on structured and semi-structured data.

Business units that create data products like to share them with others, without copying the data, to promote analysis to derive insights. Also, they want tighter control on user access and the ability to audit access to their data products. To address this, enterprises usually catalog the datasets in the AWS Glue Data Catalog for data discovery and use AWS Lake Formation for fine-grained access control to adhere to the compliance and operating security model for their business units. Given the diverse range of services, fine-grained data sharing, and personas involved, these enterprises often want a streamlined experience for enterprise user identities when accessing their data using AWS Analytics services.

AWS IAM Identity Center enables centralized management of workforce user access to AWS accounts and applications using a local identity store or by connecting corporate directories using IdPs. Amazon Redshift and AWS Lake Formation are integrated with the new trusted identity propagation capability in IAM Identity Center, allowing you to use third-party IdPs such as Microsoft Entra ID (Azure AD), Okta, Ping, and OneLogin.

With trusted identity propagation, Lake Formation enables data administrators to directly provide fine-grained access to corporate users and groups, and simplifies the traceability of end-to-end data access across supported AWS services. Because access is managed based on a user’s corporate identity, end-users don’t need to use database local user credentials or assume an AWS Identity and Access Management (IAM) role to access data. Furthermore, this enables effective user permissions based on collective group membership and supports group hierarchy.

In this post, we cover how to enable trusted identity propagation with AWS IAM Identity Center, Amazon Redshift, and AWS Lake Formation residing on separate AWS accounts and set up cross-account sharing of an S3 data lake for enterprise identities using AWS Lake Formation to enable analytics using Amazon Redshift. Then we use Amazon QuickSight to build insights using Redshift tables as our data source.

Solution overview

This post covers a use case where an organization centrally manages corporate users within their IdP and where the users belong to multiple business units. Their goal is to enable centralized user authentication through IAM Identity Center in the management account, while keeping the business unit that analyzes data using a Redshift cluster and the business unit that produces data cataloged using the Data Catalog in separate member accounts. This allows them to maintain a single authentication mechanism through IAM Identity Center within an organization while retaining access control, resource, and cost separation through the use of separate AWS accounts per business units and enabling cross-account data sharing using Lake Formation.

For this solution, AWS Organizations is enabled in the central management account and IAM Identity Center is configured for managing workforce identities. The organization has two member accounts: one account that manages the S3 data lake using the Data Catalog, and another account that runs analytical workloads on Amazon Redshift and QuickSight, with all the services enabled with trusted identity propagation. Amazon Redshift will access cross-account AWS Glue resources using IAM Identity Center users and groups set up in the central management account using QuickSight in member account 1. In member account 2, permissions on the AWS Glue resources are managed using Lake Formation and are shared with member account 1 using Lake Formation data sharing.

The following diagram illustrates the solution architecture.

The solution consists of the following:

In the centralized management account, we create a permission set and create account assignments for Redshift_Member_Account. We integrate users and groups from the IdP with IAM Identity Center.
Member account 1 (Redshift_Member_Account) is where the Redshift cluster and application exist.
Member account 2 (Glue_Member_Account) is where metadata is cataloged in the Data Catalog and Lake Formation is enabled with IAM Identity Center integration.
We assign permissions to two IAM Identity Center groups to access the Data Catalog resources:
- awssso-sales – We apply column-level filtering for this group so that users belonging to this group will be able to select two columns and read all rows.
- awssso-finance – We apply row-level filtering using data filters for this group so that users belonging to this group will be able to select all columns and see rows after row-level filtering is applied.
We apply different permissions for three IAM Identity Center users:
- User Ethan, part of awssso-sales – Ethan will be able to select two columns and read all rows.
- User Frank, part of awssso-finance – Frank will be able to select all columns and see rows after row-level filtering is applied.
- User Brian, part of awssso-sales and awssso-finance – Brian inherits permissions defined for both groups.
We set up QuickSight in the same account where Amazon Redshift exists, enabling authentication using IAM Identity Center.

Prerequisites

You should have the following prerequisites alreday set up:

A centralized management account where IAM Identity Center is enabled with member accounts added. For more information, see Enabling AWS IAM Identity Center.
Optionally, connect IAM Identity Center with your preferred IdP and sync users and groups. For instructions, refer to Getting started tutorials.
Member account 1 (Redshift_Member_Account) where the Redshift cluster and application exist. To set up a Redshift cluster with IAM Identity Center integration enabled, refer to Integrate Identity Provider (IdP) with Amazon Redshift Query Editor V2 using AWS IAM Identity Center for seamless Single Sign-On.
Member account 2 (Glue_Member_Account) where metadata is cataloged in the Data Catalog.

Member account 2 configuration

Sign in to the Lake Formation console as the data lake administrator. To learn more about setting up permissions for a data lake administrator, see Create a data lake administrator.

In this section, we walk through the steps to set up Lake Formation, enable Lake Formation permissions, and grant database and table permissions to IAM Identity Center groups.

Set up Lake Formation

Complete the steps in this section to set up Lake Formation.

Create AWS Glue resources

You can use an existing AWS Glue database that has a few tables. For this post, we use a database called customerdb and a table called reviews whose data is stored in the S3 bucket lf-datalake-<account-id>-<region>.

Register the S3 bucket location

Complete the following steps to register the S3 bucket location:

On the Lake Formation console, in the navigation pane, under Administration, choose Data lake locations.
Choose Register location.
For Amazon S3 location, enter the S3 bucket location that contains table data.
For IAM role, provide a user-defined IAM role. For instructions to create a user-defined IAM role, refer to Requirements for roles used to register locations.
For Permission mode, select Lake Formation.
Choose Register location.

Set cross-account version

Complete the following steps to set your cross-account version:

Sign in to the Lake Formation console as the data lake admin.
In the navigation pane, under Administration, choose Data Catalog settings.
Under Cross-account version settings, keep the latest version (Version 4) as the current cross-account version.
Choose Save.

Add permissions required for cross-account access

If the AWS Glue Data Catalog resource policy is already enabled in the account, then you can either remove the policy or add the following permissions to the policy that are required for cross-account grants. The provided policy enables AWS Resource Access Manager (AWS RAM) to share a resource policy while cross-account grants are made using Lake Formation. For more information, refer to Prerequisites. Please skip to the following step if your policy is blank under Catalog Settings.

Sign in to the AWS Glue console as an IAM admin.
In the navigation pane, under Data Catalog, choose Catalog settings.
Under Permissions, add the following policy, and provide the account ID where your AWS Glue resources exist:

{ "Version": "2012-10-17",
"Statement": [
{
"Effect": "Allow",
"Principal": {
"Service": "ram.amazonaws.com"
},
"Action": "glue:ShareResource",
"Resource": [
"arn:aws:glue:us-east-1:<account-id>:table/*/*",
"arn:aws:glue:us-east-1:<account-id>:database/*",
"arn:aws:glue:us-east-1:<account-id>:catalog"
]
}
]
}

Choose Save.

For more information, see Granting cross-account access.

Enable IAM Identity Center integration for Lake Formation

To integrate IAM Identity Center with your Lake Formation organization instance of IAM Identity Center, refer to Connecting Lake Formation with IAM Identity Center.

To enable cross-account sharing for IAM Identity Center users and groups, add the target recipient accounts to your Lake Formation IAM Identity Center integration under the AWS account and organization IDs.

Sign in to the Lake Formation console as a data lake admin.
In the navigation pane, under Administration, choose IAM Identity Center integration.
Under AWS account and organization IDs, choose Add.
Enter your target accounts.
Choose Add.

Enable Lake Formation permissions for databases

For Data Catalog databases that contain tables that you might share, you can stop new tables from having the default grant of Super to IAMAllowedPrincipals. Complete the following steps:

Sign in to the Lake Formation console as a data lake admin.
In the navigation pane, under Data Catalog, choose Databases.
Select the database customerdb.
Choose Actions, then choose Edit.
Under Default permissions for newly created tables, deselect Use only IAM access control for new tables in this database.
Choose Save.

For Data Catalog databases, remove IAMAllowedPrincipals.

Under Data Catalog in the navigation pane, choose Databases.
Select the database customerdb.
Choose Actions, then choose View.
Select IAMAllowedPrincipals and choose Revoke.

Repeat the same steps for tables under the customerdb database.

Grant database permissions to IAM Identity Center groups

Complete the following steps to grant database permissions to your IAM Identity Center groups:

On the Lake Formation console, under Data Catalog, choose Databases.
Select the database customerdb.
Choose Actions, then choose Grant.
Select IAM Identity Center.
Choose Add and select Get Started.
Search for and select your IAM Identity Center group names and choose Assign.

Select Named Data Catalog resources.
Under Databases, choose customerdb.
Under Database permissions, select Describe for Database permissions.
Choose Grant.

Grant table permissions to IAM Identity Center groups

In the following section, we will grant different permissions to our two IAM Identity Center groups.

Column filter

We first add permissions to the group awssso-sales. This group will have access to the customerdb database and be able to select only two columns and read all rows.

On the Lake Formation console, under Data Catalog in the navigation pane, choose Databases.
Select the database customerdb.
Choose Actions, then choose Grant.
Select IAM Identity Center.
Choose Add and select Get Started.
Search for and select awssso-sales and choose Assign.

Select Named Data Catalog resources.
Under Databases, choose customerdb.
Under Tables, choose reviews.
Under Table permissions, select Select for Table permissions.
Select Column-based access.
Select Include columns and choose product_title and star_rating.
Choose Grant.

Row filter

Next, we grant permissions to awssso-finance. This group will have access to customerdb and be able to select all columns and apply filters on rows.

We need to first create a data filter by performing the following steps:

On the Lake Formation console, choose Data filters under Data Catalog.
Choose Create data filter.
For Data filter name, provide a name.
For Target database, choose customerdb.
For Target table, choose reviews.
For Column-level access, select Access to all columns.
For Row-level access, choose Filter rows and apply your filter. In this example, we are filtering reviews with star_rating as 5.
Choose Create data filter.

Under Data Catalog in the navigation pane, choose Databases.
Select the database customerdb.
Choose Actions, then choose Grant.
Select IAM Identity Center.
Choose Add and select Get Started.
Search for and select awssso-finance and choose Assign.
Select Named Data Catalog resources.
Under Databases, choose customerdb.
Under Tables, choose reviews.
Under Data Filters, choose the High_Rating
Under Data Filter permissions, select Select.
Choose Grant.

Member account 1 configuration

In this section, we walk through the steps to add Amazon Redshift Spectrum table access in member account 1, where the Redshift cluster and application exist.

Accept Invite from RAM

You should have received a Resource Access Manager (RAM) invite from member account 2 when you added member account 1 under IAM Identity Center integration in Lake Formation at the member account 1.

Navigate to Resource Access Manager(RAM) from admin console.
Under Shared with me, click on resource shares.
Select the resource name and click on Accept resource share.

Please make sure that you have followed this entire blog to establish the Redshift Integration with IAM Identity Center before following the next steps.

Set up Redshift Spectrum table access for the IAM Identity Center group

Complete the following steps to set up Redshift Spectrum table access:

Sign in to the Amazon Redshift console using the admin role.
Navigate to Query Editor v2.
Choose the options menu (three dots) next to the cluster and choose Create connection.
Connect as the admin user and run the following commands to make the shared resource link data in the S3 data lake available to the sales group (use the account ID where the Data Catalog exists):

create external schema if not exists <schema_name> from DATA CATALOG database '<glue_catalog_name>' catalog_id '<accountid>';
grant usage on schema <schema_name> to role "<role_name>";

For example:

create external schema if not exists cross_account_glue_schema from DATA CATALOG database 'customerdb' catalog_id '932880906720';
grant usage on schema cross_account_glue_schema to role "awsidc:awssso-sales";
grant usage on schema cross_account_glue_schema to role "awsidc:awssso-finance";

Validate Redshift Spectrum access as an IAM Identity Center user

Complete the following steps to validate access:

On the Amazon Redshift console, navigate to Query Editor v2.
Choose the options menu (three dots) next to the cluster and choose Create connection.
Select IAM Identity Center.
Enter your Okta user name and password in the browser pop-up.

When you’re connected as a federated user, run the following SQL commands to query the cross_account_glue_schema data lake table.

select * from "dev"."cross_account_glue_schema"."reviews";

The following screenshot shows that user Ethan, who is part of the awssso-sales group, has access to two columns and all rows from the Data Catalog.

The following screenshot shows that user Frank, who is part of the awssso-finance group, has access to all columns for records that have star_rating as 5.

The following screenshot shows that user Brian, who is part of awssso-sales and awssso-finance, has access to all columns for records that have star_rating as 5 and access to only two columns (other columns are returned NULL) for records with star_rating other than 5.

Subscribe to QuickSight with IAM Identity Center

In this post, we set up QuickSight in the same account where the Redshift cluster exists. You can use the same or a different member account for QuickSight setup. To subscribe to QuickSight, complete the following steps:

Sign in to your AWS account and open the QuickSight console.
Choose Sign up for QuickSight.

Enter a notification email address for the QuickSight account owner or group. This email address will receive service and usage notifications.
Select the identity option that you want to subscribe with. For this post, we select Use AWS IAM Identity Center.
Enter a QuickSight account name.
Choose Configure.

Next, assign groups in IAM Identity Center to roles in QuickSight (admin, author, and reader.) This step enables your users to access the QuickSight application. In this post, we choose awssso-sales and awssso-finance for Admin group.
Specify an IAM role to control QuickSight access to your AWS resources. In this post, we select Use QuickSight managed role (default).
For this post, we deselect Add Paginated Reports.
Review the choices that you made, then choose Finish.

Enable trusted identity propagation in QuickSight

Trusted identity propagation authenticates the end-user in Amazon Redshift when they access QuickSight assets that use a trusted identity propagation enabled data source. When an author creates a data source with trusted identity propagation, the identity of the data source consumers in QuickSight is propagated and logged in AWS CloudTrail. This allows database administrators to centrally manage data security in Amazon Redshift and automatically apply data security rules to data consumers in QuickSight.

To configure QuickSight to connect to Amazon Redshift data sources with trusted identity propagation, configure Amazon Redshift OAuth scopes to your QuickSight account:

aws quicksight update-identity-propagation-config --aws-account-id "AWSACCOUNTID" --service "REDSHIFT" --authorized-targets "IAM Identity Center managed application ARN"

For example:

aws quicksight update-identity-propagation-config --aws-account-id "1234123123" --service "REDSHIFT" --authorized-targets "arn:aws:sso::XXXXXXXXXXXX:application/ssoins-XXXXXXXXXXXX/apl-XXXXXXXXXXXX"

After you have added the scope, the following command lists all OAuth scopes that are currently on a QuickSight account:

aws quicksight list-identity-propagation-configs --aws-account-id "AWSACCOUNTID"

The following code is the example with output:

aws quicksight list-identity-propagation-configs --aws-account-id "1234123123"
{
"Status": 200,
"Services": [
{
"Service": "REDSHIFT",
"AuthorizedTargets": [
"arn:aws:sso::1004123000:application/ssoins-1234f1234bb1f123/apl-12a1234e2e391234"
]
}
],
"RequestId": "116ec1b0-1533-4ed2-b5a6-d7577e073b35"
}

For more information, refer to Authorizing connections from Amazon QuickSight to Amazon Redshift clusters.

For QuickSight to connect to a Redshift instance, you must add an appropriate IP address range in the Redshift security group for the specific AWS Region. For more information, see AWS Regions, websites, IP address ranges, and endpoints.

Test your IAM Identity Center and Amazon Redshift integration with QuickSight

Now you’re ready to connect to Amazon Redshift using QuickSight.

In the management account, open the IAM Identity Center console and copy the AWS access portal URL from the dashboard.
Sign out from the management account and enter the AWS access portal URL in a new browser window.
In the pop-up window, enter your IdP credentials.

After successful authentication, you’ll be logged in to the AWS Management Console as a federated user.

On the Applications tab, select the QuickSight app.
After you federate to QuickSight, choose Datasets.
Select New Dataset and then choose Redshift (Auto Discovered).
Enter your data source details. Make sure to select Single sign-on for Authentication method.
Choose Create data source.

Congratulations! You’re signed in using IAM Identity Center integration with Amazon Redshift and are ready to explore and analyze your data using QuickSight.

The following screenshot from QuickSight shows that user Ethan, who is part of the awssso-sales group, has access to two columns and all rows from the Data Catalog.

The following screenshot from QuickSight shows that user Frank, who is part of the awssso-finance group, has access to all columns for records that have star_rating as 5.

The following screenshot from QuickSight shows that user Brian, who is part of awssso-sales and awssso-finance, has access to all columns for records that have star_rating as 5 and access to only two columns (other columns are returned NULL) for records with star_rating other than 5.

Clean up

Complete the following steps to clean up your resources:

Delete the data from the S3 bucket.
Delete the Data Catalog objects that you created as part of this post.
Delete the Lake Formation resources and QuickSight account.
If you created new Redshift cluster for testing this solution, delete the cluster.

Conclusion

In this post, we established cross-account access to enable centralized user authentication through IAM Identity Center in the management account, while keeping the Amazon Redshift and AWS Glue resources isolated by business unit in separate member accounts. We used Query Editor V2 for querying the data from Amazon Redshift. Then we showed how to build user-facing dashboards by integrating with QuickSight. Refer to Integrate Tableau and Okta with Amazon Redshift using AWS IAM Identity Center to learn about integrating Tableau and Okta with Amazon Redshift using IAM Identity Center.

Learn more about IAM Identity Center with Amazon Redshift, QuickSight, and Lake Formation. Leave your questions and feedback in the comments section.

About the Authors

Srividya Parthasarathy is a Senior Big Data Architect on the AWS Lake Formation team. She enjoys building data mesh solutions and sharing them with the community.

Maneesh Sharma is a Senior Database Engineer at AWS with more than a decade of experience designing and implementing large-scale data warehouse and analytics solutions. He collaborates with various Amazon Redshift Partners and customers to drive better integration.

Poulomi Dasgupta is a Senior Analytics Solutions Architect with AWS. She is passionate about helping customers build cloud-based analytics solutions to solve their business problems. Outside of work, she likes travelling and spending time with her family.

AWS Weekly Roundup: Global AWS Heroes Summit, AWS Lambda, Amazon Redshift, and more (July 22, 2024)

2024-07-22 Donnie Prakoso

Post Syndicated from Donnie Prakoso original https://aws.amazon.com/blogs/aws/aws-weekly-roundup-global-aws-heroes-summit-aws-lambda-amazon-redshift-and-more-july-22-2024/

Last week, AWS Heroes from around the world gathered to celebrate the 10th anniversary of the AWS Heroes program at Global AWS Heroes Summit. This program recognizes a select group of AWS experts worldwide who go above and beyond in sharing their knowledge and making an impact within developer communities.

Matt Garman, CEO of AWS and a long-time supporter of developer communities, made a special appearance for a Q&A session with the Heroes to listen to their feedback and respond to their questions.

Here’s an epic photo from the AWS Heroes Summit:

As Matt mentioned in his Linkedin post, “The developer community has been core to everything we have done since the beginning of AWS.” Thank you, Heroes, for all you do. Wishing you all a safe flight home.

Last week’s launches
Here are some launches that caught my attention last week:

Announcing the July 2024 updates to Amazon Corretto — The latest updates for the Corretto distribution of OpenJDK is now available. This includes security and critical updates for the Long-Term Supported (LTS) and Feature (FR) versions.

New open-source Advanced MYSQL ODBC Driver now available for Amazon Aurora and RDS — The new AWS ODBC Driver for MYSQL provides faster switchover and failover times, and authentication support for AWS Secrets Manager and AWS Identity and Access Management (IAM), making it a more efficient and secure option for connecting to Amazon RDS and Amazon Aurora MySQL-compatible edition databases.

Productionize Fine-tuned Foundation Models from SageMaker Canvas — Amazon SageMaker Canvas now allows you to deploy fine-tuned Foundation Models (FMs) to SageMaker real-time inference endpoints, making it easier to integrate generative AI capabilities into your applications outside the SageMaker Canvas workspace.

AWS Lambda now supports SnapStart for Java functions that use the ARM64 architecture — Lambda SnapStart for Java functions on ARM64 architecture delivers up to 10x faster function startup performance and up to 34% better price performance compared to x86, enabling the building of highly responsive and scalable Java applications using AWS Lambda.

Amazon QuickSight improves controls performance — Amazon QuickSight has improved the performance of controls, allowing readers to interact with them immediately without having to wait for all relevant controls to reload. This enhancement reduces the loading time experienced by readers.

Amazon OpenSearch Serverless levels up speed and efficiency with smart caching — The new smart caching feature for indexing in Amazon OpenSearch Serverless automatically fetches and manages data, leading to faster data retrieval, efficient storage usage, and cost savings.

Amazon Redshift Serverless with lower base capacity available in the Europe (London) Region — Amazon Redshift Serverless now allows you to start with a lower data warehouse base capacity of 8 Redshift Processing Units (RPUs) in the Europe (London) region, providing more flexibility and cost-effective options for small to large workloads.

AWS Lambda now supports Amazon MQ for ActiveMQ and RabbitMQ in five new regions — AWS Lambda now supports Amazon MQ for ActiveMQ and RabbitMQ in five new regions, enabling you to build serverless applications with Lambda functions that are invoked based on messages posted to Amazon MQ message brokers.

From community.aws
Here’s my top 5 personal favorites posts from community.aws:

Upcoming AWS events
Check your calendars and sign up for upcoming AWS events:

AWS Summits — Join free online and in-person events that bring the cloud computing community together to connect, collaborate, and learn about AWS. To learn more about future AWS Summit events, visit the AWS Summit page. Register in your nearest city: AWS Summit Taipei (July 23–24), AWS Summit Mexico City (Aug. 7), and AWS Summit Sao Paulo (Aug. 15).

AWS Community Days — Join community-led conferences that feature technical discussions, workshops, and hands-on labs led by expert AWS users and industry leaders from around the world. Upcoming AWS Community Days are in Aotearoa (Aug. 15), Nigeria (Aug. 24), New York (Aug. 28), and Belfast (Sept. 6).

You can browse all upcoming in-person and virtual events.

That’s all for this week. Check back next Monday for another Weekly Roundup!

— Donnie

This post is part of our Weekly Roundup series. Check back each week for a quick roundup of interesting news and announcements from AWS!

Simplify and automate bill processing with Amazon Bedrock

2024-07-19 Vijay Shekhar Rao

Post Syndicated from Vijay Shekhar Rao original https://aws.amazon.com/blogs/architecture/simplify-and-automate-bill-processing-with-amazon-bedrock/

This post was co-written with Shyam Narayan, a leader in the Accenture AWS Business Group, and Hui Yee Leong, a DevOps and platform engineer, both based in Australia. Hui and Shyam specialize in designing and implementing complex AWS transformation programs across a wide range of industries.

Enterprises that operate out of multiple locations such as in retail and telecom industries often deal with the complexities of processing several utility bills. These bills need to be verified for discrepancies before making payments. Business processes are often done by teams of people manually processing invoices in various formats.

Additionally, enterprises often need to meet Environmental, Social, and Governance (ESG) regulatory compliances, and utility bills are important elements relating to the reporting of electricity, water, and gas usage, which largely gets untapped as well.

Invoices are generated by utility providers in various formats, like PDF, XLS, and EML, have different layouts, and are often delivered as emails. This makes it difficult to standardize ingestion, process these invoices for anomalies such as seasonal usage patterns, compare contracted vs. billed rates, and finally process payments.

Due to this lack of usage data standardization, ingesting this data into a central ESG data lake becomes challenging.

In this post, we present a solution using Amazon Bedrock to address these challenges. The solution offers the following capabilities:

Provides flexibility to ingest utility bills in various formats and layouts
Standardizes bills into a single format and applies data quality controls
Integrates with existing systems through events
Automates repetitive tasks, which reduces human error and enhances efficiency
Enables predictive analysis, which enables informed decision-making with generative artificial intelligence (AI)
Integrates with existing data lakes, data warehouse, payments systems, and ESG reporting systems

Solution overview

The solution uses Amazon Bedrock to automate invoice processing, tariff extraction, validation, and reporting, as shown in Figure 1.

Figure 1. Diagram showing the Amazon Bedrock solution to simplify and automate billing

The workflow includes the following steps:

Using SFTP connectors with the AWS Transfer Family, invoices and are uploaded to an Amazon Simple Storage Service (Amazon S3) bucket.
Some Utility providers send invoices directly to an email address enabled on Amazon SES, the PDF attachment is extracted and uploaded to a Amazon S3 bucket.
The upload generates an S3 event into an Amazon EventBridge bus and an EventBridge rule invokes AWS Step Functions workflow for invoice extraction and validation.
The Step Functions workflow to validates invoices. It uses Amazon Textract for text extraction (for a tutorial, see Detecting text with an AWS Lambda function) and invokes the Amazon Titan Text V1 Express model to generate embeddings and store them in Amazon Aurora PostgreSQL-Compatible Edition with pgvector It also stores the extracted invoices in the DynamoDB table.
Failed validations are flagged for manual processing by agents through Amazon Simple Notification Service (Amazon SNS).
A Lambda function invoked by Amazon EventBridge scheduled rule fetches tariff data from external SFTP repository and stores in a S3 bucket.
Utility Data Extraction Step Functions is invoked by an S3 event. This process involves extracting data from various providers, which may be in different formats and units, to facilitate seamless integration with the business logic.
The tariff data is then stored in an Amazon DynamoDB table, which is used by the business logic Step Functions workflow.
The main business logic of checking invoices for usage anomalies and check for approved tariff is done in the Business Logic Step function. This Step function makes use of Amazon Bedrock, embeddings, extracted invoices and tariff data to check for anomalies, invoice accuracy and update the reporting database.
Reporting data is stored in an Amazon Aurora database and visualized using Amazon QuickSight for payment validation reports.
Amazon Q in QuickSight is used for enhanced and quick decision-making using generative BI capabilities.

The following screenshots show examples of the Amazon QuickSight visualizations.

Figure 2. QuickSight visualization showing physical location of invoiced locations, monthly combined usage and billed amount.

Figure 3. QuickSight Q animation demonstrating AI-driven answers to the questions on the data beyond what is presented in the dashboards

Benefits from the solution

This solution offers the following benefits:

Contextual understanding – With the Anthropic Claude 3 Sonnet model on Amazon Bedrock, this solution has the capability to understand, analyze, and interpret the context of your data beyond just text recognition.
Flexibility and adaptability – This solution enables flexibility to learn and adapt to new formats because Amazon Bedrock is able to understand the data contained within the invoices and adapt to the various changes of data representation.
Event-driven architecture – This is an event-driven, serverless architecture, which enables modularity and integration with external workflows specific to your organization.
Automated workflow – The solution reduces the need for manual intervention in data quality processes, such as data profiling, cleansing, and validation. This allows for faster processing and reduced human error.
Cost savings – Automation reduces the reliance on teams of people, resulting in cost savings for organizations.
Compliance and risk mitigation – Automated data quality processes help organizations maintain ESG compliance with regulatory requirements and industry standards.
Data governance – Automation facilitates the implementation of data governance policies and procedures. By automating data quality monitoring and reporting, organizations can enforce data governance standards more effectively and adhere to data quality guidelines.

Conclusion

In this post, we saw how automation paves the way for organizations to optimize utility bill processing and get additional ESG insights. We demonstrated how the application and the power of generative AI on Amazon Bedrock can simplify data extraction when the data isn’t presented in a standard format. Finally, we presented a serverless and event-driven solution that scales automatically based on your business needs.

For more in-depth guides, check out our workshops on Amazon QuickSight Q and Amazon Bedrock.

Building a scalable streaming data platform that enables real-time and batch analytics of electric vehicles on AWS

2024-07-17 Ayush Agrawal

Post Syndicated from Ayush Agrawal original https://aws.amazon.com/blogs/big-data/building-a-scalable-streaming-data-platform-that-enables-real-time-and-batch-analytics-of-electric-vehicles-on-aws/

The automobile industry has undergone a remarkable transformation because of the increasing adoption of electric vehicles (EVs). EVs, known for their sustainability and eco-friendliness, are paving the way for a new era in transportation. As environmental concerns and the push for greener technologies have gained momentum, the adoption of EVs has surged, promising to reshape our mobility landscape.

The surge in EVs brings with it a profound need for data acquisition and analysis to optimize their performance, reliability, and efficiency. In the rapidly evolving EV industry, the ability to harness, process, and derive insights from the massive volume of data generated by EVs has become essential for manufacturers, service providers, and researchers alike.

As the EV market is expanding with many new and incumbent players trying to capture the market, the major differentiating factor will be the performance of the vehicles.

Modern EVs are equipped with an array of sensors and systems that continuously monitor various aspects of their operation including parameters such as voltage, temperature, vibration, speed, and so on. From battery management to motor performance, these data-rich machines provide a wealth of information that, when effectively captured and analyzed, can revolutionize vehicle design, enhance safety, and optimize energy consumption. The data can be used to do predictive maintenance, device anomaly detection, real-time customer alerts, remote device management, and monitoring.

However, managing this deluge of data isn’t without its challenges. As the adoption of EVs accelerates, the need for robust data pipelines capable of collecting, storing, and processing data from an exponentially growing number of vehicles becomes more pronounced. Moreover, the granularity of data generated by each vehicle has increased significantly, making it essential to efficiently handle the ever-increasing number of data points. The challenges include not only the technical intricacies of data management but also concerns related to data security, privacy, and compliance with evolving regulations.

In this blog post, we delve into the intricacies of building a reliable data analytics pipeline that can scale to accommodate millions of vehicles, each generating hundreds of metrics every second using Amazon OpenSearch Ingestion. We also provide guidelines and sample configurations to help you implement a solution.

Of the prerequisites that follow, the IOT topic rule and the Amazon Managed Streaming for Apache Kafka (Amazon MSK) cluster can be set up by following How to integrate AWS IoT Core with Amazon MSK. The steps to create an Amazon OpenSearch Service cluster are available in Creating and managing Amazon OpenSearch Service domains.

Prerequisites

Before you begin the implementing the solution, you need the following:

IOT topic rule
Amazon MSK Simple Authentication and Security Layer/Salted Challenge Response Mechanism (SASL/SCRAM) cluster
Amazon OpenSearch Service domain

Solution overview

The following architecture diagram provides a scalable and fully managed modern data streaming platform. The architecture uses Amazon OpenSearch Ingestion to stream data into OpenSearch Service and Amazon Simple Storage Service (Amazon S3) to store the data. The data in OpenSearch powers real-time dashboards. The data can also be used to notify customers of any failures occurring on the vehicle (see Configuring alerts in Amazon OpenSearch Service). The data in Amazon S3 is used for business intelligence and long-term storage.

Architecture diagram

In the following sections, we focus on the following three critical pieces of the architecture in depth:

1. Amazon MSK to OpenSearch ingestion pipeline

2. Amazon OpenSearch Ingestion pipeline to OpenSearch Service

3. Amazon OpenSearch Ingestion to Amazon S3

Solution Walkthrough

Step 1: MSK to Amazon OpenSearch Ingestion pipeline

Because each electric vehicle streams massive volumes of data to Amazon MSK clusters through AWS IoT Core, making sense of this data avalanche is critical. OpenSearch Ingestion provides a fully managed serverless integration to tap into these data streams.

The Amazon MSK source in OpenSearch Ingestion uses Kafka’s Consumer API to read records from one or more MSK topics. The MSK source in OpenSearch Ingestion seamlessly connects to MSK to ingest the streaming data into OpenSearch Ingestion’s processing pipeline.

The following snippet illustrates the pipeline configuration for an OpenSearch Ingestion pipeline used to ingest data from an MSK cluster.

While creating an OpenSearch Ingestion pipeline, add the following snippet in the Pipeline configuration section.

version: "2"
msk-pipeline: 
  source: 
    kafka: 
      acknowledgments: true                  
      topics: 
         - name: "ev-device-topic " 
           group_id: "opensearch-consumer" 
           serde_format: json                 
      aws: 
        # Provide the Role ARN with access to MSK. This role should have a trust relationship with osis-pipelines.amazonaws.com 
        sts_role_arn: "arn:aws:iam:: ::<<account-id>>:role/opensearch-pipeline-Role"
        # Provide the region of the domain. 
        region: "<<region>>" 
        msk: 
          # Provide the MSK ARN.  
          arn: "arn:aws:kafka:<<region>>:<<account-id>>:cluster/<<name>>/<<id>>"

When configuring Amazon MSK and OpenSearch Ingestion, it’s essential to establish an optimal relationship between the number of partitions in your Kafka topics and the number of OpenSearch Compute Units (OCUs) allocated to your ingestion pipelines. This optimal configuration ensures efficient data processing and maximizes throughput. You can read more about it in Configure recommended compute units (OCUs) for the Amazon MSK pipeline.

Step 2: OpenSearch Ingestion pipeline to OpenSearch Service

OpenSearch Ingestion offers a direct method for streaming EV data into OpenSearch. The OpenSearch sink plugin channels data from multiple sources directly into the OpenSearch domain. Instead of manually provisioning the pipeline, you define the capacity for your pipeline using OCUs. Each OCU provides 6 GB of memory and two virtual CPUs. To use OpenSearch Ingestion auto-scaling optimally, it’s essential to configure the maximum number of OCUs for a pipeline based on the number of partitions in the topics being ingested. If a topic has a large number of partitions (for example, more than 96, which is the maximum OCUs per pipeline), it’s recommended to configure the pipeline with a maximum of 1–96 OCUs. This way, the pipeline can automatically scale up or down within this range as needed. However, if a topic has a low number of partitions (for example, fewer than 96), it’s advisable to set the maximum number of OCUs to be equal to the number of partitions. This approach ensures that each partition is processed by a dedicated OCU enabling parallel processing and optimal performance. In scenarios where a pipeline ingests data from multiple topics, the topic with the highest number of partitions should be used as a reference to configure the maximum OCUs. Additionally, if higher throughput is required, you can create another pipeline with a new set of OCUs for the same topic and consumer group, enabling near-linear scalability.

OpenSearch Ingestion provides several pre-defined configuration blueprints that can help you quickly build your ingestion pipeline on AWS

The following snippet illustrates pipeline configuration for an OpenSearch Ingestion pipeline using OpenSearch as a SINK with a dead letter queue (DLQ) to Amazon S3. When a pipeline encounters write errors, it creates DLQ objects in the configured S3 bucket. DLQ objects exist within a JSON file as an array of failed events.

sink: 
      - opensearch: 
          # Provide an AWS OpenSearch Service domain endpoint 
          hosts: [ "https://<<domain-name>>.<<region>>.es.amazonaws.com" ] 
          aws: 
          # Provide a Role ARN with access to the domain. This role should have a trust relationship with osis-pipelines.amazonaws.com 
            sts_role_arn: "arn:aws:iam::<<account-id>>:role/<<role-name>>" 
          # Provide the region of the domain. 
            region: "<<region>>" 
          # Enable the 'serverless' flag if the sink is an Amazon OpenSearch Serverless collection 
          # serverless: true 
          # index name can be auto-generated from topic name 
          index: "index_ev_pipe-%{yyyy.MM.dd}" 
          # Enable 'distribution_version' setting if the AWS OpenSearch Service domain is of version Elasticsearch 6.x 
          #distribution_version: "es6" 
          # Enable the S3 DLQ to capture any failed requests in Ohan S3 bucket 
          dlq: 
            s3: 
            # Provide an S3 bucket 
              bucket: "<<bucket-name>>"
            # Provide a key path prefix for the failed requests
              key_path_prefix: "oss-pipeline-errors/dlq"
            # Provide the region of the bucket.
              region: "<<region>>"
            # Provide a Role ARN with access to the bucket. This role should have a trust relationship with osis-pipelines.amazonaws.com
              sts_role_arn: "arn:aws:iam:: <<account-id>>:role/<<role-name>>"

Step 3: OpenSearch Ingestion to Amazon S3

OpenSearch Ingestion offers a built-in sink for loading streaming data directly into S3. The service can compress, partition, and optimize the data for cost-effective storage and analytics in Amazon S3. Data loaded into S3 can be partitioned for easier query isolation and lifecycle management. Partitions can be based on vehicle ID, date, geographic region, or other dimensions as needed for your queries.

The following snippet illustrates how we’ve partitioned and stored EV data in Amazon S3.

- s3:
            aws:
              # Provide a Role ARN with access to the bucket. This role should have a trust relationship with osis-pipelines.amazonaws.com
                sts_role_arn: "arn:aws:iam::<<account-id>>:role/<<role-name>>"
              # Provide the region of the domain.
                region: "<<region>>"
            # Replace with the bucket to send the logs to
            bucket: "evbucket"
            object_key:
              # Optional path_prefix for your s3 objects
              path_prefix: "index_ev_pipe/year=%{yyyy}/month=%{MM}/day=%{dd}/hour=%{HH}"
            threshold:
              event_collect_timeout: 60s
            codec:
              parquet:
                auto_schema: true

The pipeline can be created following the steps in Creating Amazon OpenSearch Ingestion pipelines.

The following is the complete pipeline configuration, combining the configuration of all three steps. Update the Amazon Resource Names (ARNs), AWS Region, Open Search Service domain endpoint, and S3 names as needed.

The entire OpenSearch Ingestion pipeline configuration can be directly copied into the ‘Pipeline configuration’ field in the AWS Management Console while creating the OpenSearch Ingestion pipeline

version: "2"
msk-pipeline: 
  source: 
    kafka: 
      acknowledgments: true           # Default is false  
      topics: 
         - name: "<<msk-topic-name>>" 
           group_id: "opensearch-consumer" 
           serde_format: json        
      aws: 
        # Provide the Role ARN with access to MSK. This role should have a trust relationship with osis-pipelines.amazonaws.com 
        sts_role_arn: "arn:aws:iam::<<account-id>>:role/<<role-name>>"
        # Provide the region of the domain. 
        region: "<<region>>" 
        msk: 
          # Provide the MSK ARN.  
          arn: "arn:aws:kafka:us-east-1:<<account-id>>:cluster/<<cluster-name>>/<<cluster-id>>" 
  processor:
      - parse_json:
  sink: 
      - opensearch: 
          # Provide an AWS OpenSearch Service domain endpoint 
          hosts: [ "https://<<opensearch-service-domain-endpoint>>.us-east-1.es.amazonaws.com" ] 
          aws: 
          # Provide a Role ARN with access to the domain. This role should have a trust relationship with osis-pipelines.amazonaws.com 
            sts_role_arn: "arn:aws:iam::<<account-id>>:role/<<role-name>>" 
          # Provide the region of the domain. 
            region: "<<region>>" 
          # Enable the 'serverless' flag if the sink is an Amazon OpenSearch Serverless collection 
          # index name can be auto-generated from topic name 
          index: "index_ev_pipe-%{yyyy.MM.dd}" 
          # Enable 'distribution_version' setting if the AWS OpenSearch Service domain is of version Elasticsearch 6.x 
          #distribution_version: "es6" 
          # Enable the S3 DLQ to capture any failed requests in Ohan S3 bucket 
          dlq: 
            s3: 
            # Provide an S3 bucket 
              bucket: "<<bucket-name>>"
            # Provide a key path prefix for the failed requests
              key_path_prefix: "oss-pipeline-errors/dlq"
            # Provide the region of the bucket.
              region: "<<region>>"
            # Provide a Role ARN with access to the bucket. This role should have a trust relationship with osis-pipelines.amazonaws.com
              sts_role_arn: "arn:aws:iam::<<account-id>>:role/<<role-name>>"
      - s3:
            aws:
              # Provide a Role ARN with access to the bucket. This role should have a trust relationship with osis-pipelines.amazonaws.com
                sts_role_arn: "arn:aws:iam::<<account-id>>:role/<<role-name>>"
              # Provide the region of the domain.
                region: "<<region>>"
            # Replace with the bucket to send the logs to
            bucket: "<<bucket-name>>"
            object_key:
              # Optional path_prefix for your s3 objects
              path_prefix: "index_ev_pipe/year=%{yyyy}/month=%{MM}/day=%{dd}/hour=%{HH}"
            threshold:
              event_collect_timeout: 60s
            codec:
              parquet:
                auto_schema: true

Real-time analytics

After the data is available in OpenSearch Service, you can build real-time monitoring and notifications. OpenSearch Service has robust support for multiple notification channels, allowing you to receive alerts through services like Slack, Chime, custom webhooks, Microsoft Teams, email, and Amazon Simple Notification Service (Amazon SNS).

The following screenshot illustrates supported notification channels in OpenSearch Service.

The notification feature in OpenSearch Service allows you to create monitors that will watch for certain conditions or changes in your data and launch alerts, such as monitoring vehicle telemetry data and launching alerts for issues like battery degradation or abnormal energy consumption. For example, you can create a monitor that analyzes battery capacity over time and notifies the on-call team using Slack if capacity drops below expected degradation curves in a significant number of vehicles. This could indicate a potential manufacturing defect requiring investigation.

In addition to notifications, OpenSearch Service makes it easy to build real-time dashboards to visually track metrics across your fleet of vehicles. You can ingest vehicle telemetry data like location, speed, fuel consumption, and so on, and visualize it on maps, charts, and gauges. Dashboards can provide real-time visibility into vehicle health and performance.

The following screenshot illustrates creating a sample dashboard on OpenSearch Service

Opensearch Dashboard

A key benefit of OpenSearch Service is its ability to handle high sustained ingestion and query rates with millisecond latencies. It distributes incoming vehicle data across data nodes in a cluster for parallel processing. This allows OpenSearch to scale out to handle very large fleets while still delivering the real-time performance needed for operational visibility and alerting.

Batch analytics

After the data is available in Amazon S3, you can build a secure data lake to power a variety of analytics use cases deriving powerful insights. As an immutable store, new data is continually stored in S3 while existing data remains unaltered. This serves as a single source of truth for downstream analytics.

For business intelligence and reporting, you can analyze trends, identify insights, and create rich visualizations powered by the data lake. You can use Amazon QuickSight to build and share dashboards without needing to set up servers or infrastructure. Here’s an example of a Quicksight dashboard for IoT device data. For example, you can use a dashboard to gain insights from historical data that can help with better vehicle and battery design.

The Amazon Quicksight public gallery shows examples of dashboards across different domains.

You should consider Amazon OpenSearch dashboards for your operational day-to-day use cases to identify issues and alert in near real time whereas Amazon Quicksight should be used to analyze big data stored in a lake house and generate actionable insights from them.

Clean up

Delete the OpenSearch pipeline and Amazon MSK cluster to stop incurring costs on these services.

Conclusion

In this post, you learned how Amazon MSK, OpenSearch Ingestion, OpenSearch Services, and Amazon S3 can be integrated to ingest, process, store, analyze, and act on endless streams of EV data efficiently.

With OpenSearch Ingestion as the integration layer between streams and storage, the entire pipeline scales up and down automatically based on demand. No more complex cluster management or lost data from bursts in streams.

See Amazon OpenSearch Ingestion to learn more.

About the authors

Ayush Agrawal is a Startups Solutions Architect from Gurugram, India with 11 years of experience in Cloud Computing. With a keen interest in AI, ML, and Cloud Security, Ayush is dedicated to helping startups navigate and solve complex architectural challenges. His passion for technology drives him to constantly explore new tools and innovations. When he’s not architecting solutions, you’ll find Ayush diving into the latest tech trends, always eager to push the boundaries of what’s possible.

Fraser Sequeira is a Solutions Architect with AWS based in Mumbai, India. In his role at AWS, Fraser works closely with startups to design and build cloud-native solutions on AWS, with a focus on analytics and streaming workloads. With over 10 years of experience in cloud computing, Fraser has deep expertise in big data, real-time analytics, and building event-driven architecture on AWS.

Simplify custom contact center insights with Amazon Connect analytics data lake

2024-05-31 Donnie Prakoso

Post Syndicated from Donnie Prakoso original https://aws.amazon.com/blogs/aws/simplify-custom-contact-center-insights-with-amazon-connect-analytics-data-lake/

Analytics are vital to the success of a contact center. Having insights into each touchpoint of the customer experience allows you to accurately measure performance and adapt to shifting business demands. While you can find common metrics in the Amazon Connect console, sometimes you need to have more details and custom requirements for reporting based on the unique needs of your business.

Starting today, the Amazon Connect analytics data lake is generally available. As announced last year as preview, this new capability helps you to eliminate the need to build and maintain complex data pipelines. Amazon Connect data lake is zero-ETL capable, so no extract, transform, or load (ETL) is needed.

Here’s a quick look at the Amazon Connect analytics data lake:

Improving your customer experience with Amazon Connect
Amazon Connect analytics data lake helps you to unify disparate data sources, including customer contact records and agent activity, into a single location. By having your data in a centralized location, you now have access to analyze contact center performance and gain insights while reducing the costs associated with implementing complex data pipelines.

With Amazon Connect analytics data lake, you can access and analyze contact center data, such as contact trace records and Amazon Connect Contact Lens data. This provides you the flexibility to prepare and analyze data with Amazon Athena and use the business intelligence (BI) tools of your choice, such as, Amazon QuickSight and Tableau.

Get started with the Amazon Connect analytics data lake
To get started with the Amazon Connect analytics data lake, you’ll first need to have an Amazon Connect instance setup. You can follow the steps in the Create an Amazon Connect instance page to create a new Amazon Connect instance. Because I’ve already created my Amazon Connect instance, I will go straight to showing you how you can get started with Amazon Connect analytics data lake.

First, I navigate to the Amazon Connect console and select my instance.

Then, on the next page, I can set up my analytics data lake by navigating to Analytics tools and selecting Add data share.

This brings up a pop-up dialog, and I first need to define the target AWS account ID. With this option, I can set up a centralized account to receive all data from Amazon Connect instances running in multiple accounts. Then, under Data types, I can select the types I need to share with the target AWS account. To learn more about the data types that you can share in the Amazon Connect analytics data lake, please visit Associate tables for Analytics data lake.

Once it’s done, I can see the list of all the target AWS account IDs with which I have shared all the data types.

Besides using the AWS Management Console, I can also use the AWS Command Line Interface (AWS CLI) to associate my tables with the analytics data lake. The following is a sample command:

$> aws connect batch-associate-analytics-data-set --cli-input-json file:///input_batch_association.json

Where input_batch_association.json is a JSON file that contains association details. Here’s a sample:

{
	"InstanceId": YOUR_INSTANCE_ID,
	"DataSetIds": [
		"<DATA_SET_ID>"
		],
	"TargetAccountId": YOUR_ACCOUNT_ID
}

Next, I need to approve (or reject) the request in the AWS Resource Access Manager (RAM) console in the target account. RAM is a service to help you securely share resources across AWS accounts. I navigate to AWS RAM and select Resource shares in the Shared with me section.

Then, I select the resource and select Accept resource share.

At this stage, I can access shared resources from Amazon Connect. Now, I can start creating linked tables from shared tables in AWS Lake Formation. In the Lake Formation console, I navigate to the Tables page and select Create table.

I need to create a Resource link to a shared table. Then, I fill in the details and select the available Database and the Shared table’s region.

Then, when I select Shared table, it will list all the available shared tables that I can access.

Once I select the shared table, it will automatically populate Shared table’s database and Shared table’s owner ID. Once I’m happy with the configuration, I select Create.

To run some queries for the data, I go to the Amazon Athena console.The following is an example of a query that I ran:

With this configuration, I have access to certain Amazon Connect data types. I can even visualize the data by integrating with Amazon QuickSight. The following screenshot show some visuals in the Amazon QuickSight dashboard with data from Amazon Connect.

Customer voice
During the preview period, we heard lots of feedback from our customers about Amazon Connect analytics data lake. Here’s what our customer say:

Joulica is an analytics platform supporting insights for software like Amazon Connect and Salesforce. Tony McCormack, founder and CEO of Joulica, said, “Our core business is providing real-time and historical contact center analytics to Amazon Connect customers of all sizes. In the past, we frequently had to set up complex data pipelines, and so we are excited about using Amazon Connect analytics data lake to simplify the process of delivering actionable intelligence to our shared customers.”

Things you need to know

Pricing — Amazon Connect analytics data lake is available for you to use up to 2 years of data without any additional charges in Amazon Connect. You only need to pay for any services you use to interact with the data.
Availability — Amazon Connect analytics data lake is generally available in the following AWS Regions: US East (N. Virginia), US West (Oregon), Africa (Cape Town), Asia Pacific (Mumbai, Seoul, Singapore, Sydney, Tokyo), Canada (Central), and Europe (Frankfurt, London)
Learn more — For more information, please visit Analytics data lake documentation page.

Happy building,
— Donnie

Name	Value
S3Bucket	Value of the S3 bucket where the output files will be stored
tablesToTrack	List of tables to track as JSON converted to string
Tmp	/tmp