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Introduction
The AWS Certified Solutions Architect – Associate (SAA-C03) exam is intended
for individuals who perform in a solutions architect role. The exam validates a
candidate’s ability to use AWS technologies to design solutions based on the AWS
Well-Architected Framework.
The exam also validates a candidate’s ability to complete the following
tasks:
• Design solutions that incorporate AWS services to meet current business
requirements and future projected needs
• Design architectures that are secure, resilient, high-performing, and
cost-optimized
• Review existing solutions and determine improvements
Target candidate description
The target candidate should have at least 1 year of hands-on experience
designing cloud solutions that use AWS services.
For a detailed list of specific tools and technologies that might be covered on
the exam, as well as lists of in-scope and out-of-scope AWS services, refer to
the Appendix.
Exam content Response types
There are two types of questions on the exam:
• Multiple choice: Has one correct response and three incorrect responses (distractors)
• Multiple response: Has two or more correct responses out of five or more
response options
Select one or more responses that best complete the statement or answer the
question. Distractors, or incorrect answers, are response options that a
candidate with incomplete knowledge or skill might choose. Distractors are
generally plausible responses that match the content area.
Unanswered questions are scored as incorrect; there is no penalty for guessing.
The exam includes 50 questions that will affect your score.
Unscored content
The exam includes 15 unscored questions that do not affect your score. AWS
collects information about candidate performance on these unscored questions to
evaluate these questions for future use as scored questions. These unscored
questions are not identified on the exam.
Exam results
The AWS Certified Solutions Architect – Associate exam is a pass or fail
exam. The exam is scored against a minimum standard established by AWS
professionals who follow certification industry best practices and guidelines.
Your results for the exam are reported as a scaled score of 100–1,000. The
minimum passing score is 720. Your score shows how you performed on the exam as
a whole and whether or not you passed. Scaled scoring models help equate scores
across multiple exam forms that might have slightly different difficulty levels.
Your score report could contain a table of classifications of your performance
at each section level. This information provides general feedback about your
exam performance. The exam uses a compensatory scoring model, which means that
you do not need to achieve a passing score in each section. You need to pass
only the overall exam.
Each section of the exam has a specific weighting, so some sections have more
questions than other sections have. The table contains general information that
highlights your strengths and weaknesses. Use caution when interpreting
section-level feedback. Candidates who pass the exam will not receive this
additional information.
Content outline
This exam guide includes weightings, test domains, and task statements for the
exam. It is not a comprehensive listing of the content on the exam. However,
additional context for each of the task statements is available to help guide
your preparation for the exam. The following table lists the main content
domains and their weightings. The table precedes the complete exam content
outline, which includes the additional context. The percentage in each domain
represents only scored content.
Domain 1: Design Secure Architectures 30%
Domain 2: Design Resilient Architectures 26%
Domain 3: Design High-Performing Architectures 24%
Domain 4: Design Cost-Optimized Architectures 20%
Domain 1: Design Secure Architectures
Task Statement 1: Design secure access to AWS resources.
Knowledge of:
• Access controls and management across multiple accounts
• AWS federated access and identity services (for example, AWS Identity and
Access Management [IAM], AWS Single Sign-On [AWS SSO])
• AWS global infrastructure (for example, Availability Zones, AWS Regions)
• AWS security best practices (for example, the principle of least privilege)
• The AWS shared responsibility model
Skills in:
• Applying AWS security best practices to IAM users and root users (for
example, multi-factor authentication [MFA])
• Designing a flexible authorization model that includes IAM users, groups,
roles, and policies
• Designing a role-based access control strategy (for example, AWS Security
Token Service [AWS STS], role switching, cross-account access)
• Designing a security strategy for multiple AWS accounts (for example, AWS
Control Tower, service control policies [SCPs])
• Determining the appropriate use of resource policies for AWS services
• Determining when to federate a directory service with IAM roles
Task Statement 2: Design secure workloads and applications.
Knowledge of:
• Application configuration and credentials security
• AWS service endpoints
• Control ports, protocols, and network traffic on AWS
• Secure application access
• Security services with appropriate use cases (for example, Amazon Cognito,
Amazon GuardDuty, Amazon Macie)
• Threat vectors external to AWS (for example, DDoS, SQL injection)
Skills in:
• Designing VPC architectures with security components (for example,
security groups, route tables, network ACLs, NAT gateways)
• Determining network segmentation strategies (for example, using public subnets
and private subnets)
• Integrating AWS services to secure applications (for example, AWS Shield, AWS
WAF, AWS SSO, AWS Secrets Manager)
• Securing external network connections to and from the AWS Cloud (for example,
VPN, AWS Direct Connect)
Task Statement 3: Determine appropriate data security controls.
Knowledge of:
• Data access and governance
• Data recovery
• Data retention and classification
• Encryption and appropriate key management
Skills in:
• Aligning AWS technologies to meet compliance requirements
• Encrypting data at rest (for example, AWS Key Management Service [AWS KMS])
• Encrypting data in transit (for example, AWS Certificate Manager [ACM] using
TLS)
• Implementing access policies for encryption keys
• Implementing data backups and replications
• Implementing policies for data access, lifecycle, and protection
• Rotating encryption keys and renewing certificates
Domain 2: Design Resilient Architectures
Task Statement 1: Design scalable and loosely coupled architectures.
Knowledge of:
• API creation and management (for example, Amazon API Gateway, REST API)
• AWS managed services with appropriate use cases (for example, AWS Transfer
Family, Amazon Simple Queue Service [Amazon SQS], Secrets Manager)
• Caching strategies
• Design principles for microservices (for example, stateless workloads compared
with stateful workloads)
• Event-driven architectures
• Horizontal scaling and vertical scaling
• How to appropriately use edge accelerators (for example, content delivery
network [CDN])
• How to migrate applications into containers
• Load balancing concepts (for example, Application Load Balancer)
• Multi-tier architectures
• Queuing and messaging concepts (for example, publish/subscribe)
• Serverless technologies and patterns (for example, AWS Fargate, AWS Lambda)
• Storage types with associated characteristics (for example, object, file,
block)
• The orchestration of containers (for example, Amazon Elastic Container Service
[Amazon ECS], Amazon Elastic Kubernetes Service [Amazon EKS])
• When to use read replicas
• Workflow orchestration (for example, AWS Step Functions)
Skills in:
• Designing event-driven, microservice, and/or multi-tier architectures
based on requirements
• Determining scaling strategies for components used in an architecture design
• Determining the AWS services required to achieve loose coupling based on
requirements
• Determining when to use containers
• Determining when to use serverless technologies and patterns
• Recommending appropriate compute, storage, networking, and database
technologies based on requirements
• Using purpose-built AWS services for workloads
Task Statement 2: Design highly available and/or fault-tolerant architectures.
Knowledge of:
• AWS global infrastructure (for example, Availability Zones, AWS Regions,
Amazon Route 53)
• AWS managed services with appropriate use cases (for example, Amazon
Comprehend, Amazon Polly)
• Basic networking concepts (for example, route tables)
• Disaster recovery (DR) strategies (for example, backup and restore, pilot
light, warm standby, active-active failover, recovery point objective [RPO],
recovery time objective [RTO])
• Distributed design patterns
• Failover strategies
• Immutable infrastructure
• Load balancing concepts (for example, Application Load Balancer)
• Proxy concepts (for example, Amazon RDS Proxy)
• Service quotas and throttling (for example, how to configure the service
quotas for a workload in a standby environment)
• Storage options and characteristics (for example, durability, replication)
• Workload visibility (for example, AWS X-Ray)
Skills in:
• Determining automation strategies to ensure infrastructure integrity
• Determining the AWS services required to provide a highly available and/or
fault-tolerant architecture across AWS Regions or Availability Zones
• Identifying metrics based on business requirements to deliver a highly
available solution
• Implementing designs to mitigate single points of failure
• Implementing strategies to ensure the durability and availability of data (for
example, backups)
• Selecting an appropriate DR strategy to meet business requirements
• Using AWS services that improve the reliability of legacy applications and
applications not built for the cloud (for example, when application changes are
not possible)
• Using purpose-built AWS services for workloads
Domain 3: Design High-Performing Architectures
Task Statement 1: Determine high-performing and/or scalable storage solutions.
Knowledge of:
• Hybrid storage solutions to meet business requirements
• Storage services with appropriate use cases (for example, Amazon S3, Amazon
Elastic File System [Amazon EFS], Amazon Elastic Block Store [Amazon EBS])
• Storage types with associated characteristics (for example, object, file,
block)
Skills in:
• Determining storage services and configurations that meet performance
demands
• Determining storage services that can scale to accommodate future needs
Task Statement 2: Design high-performing and elastic compute solutions.
Knowledge of:
• AWS compute services with appropriate use cases (for example, AWS Batch,
Amazon EMR, Fargate)
• Distributed computing concepts supported by AWS global infrastructure and edge
services
• Queuing and messaging concepts (for example, publish/subscribe)
• Scalability capabilities with appropriate use cases (for example, Amazon EC2
Auto Scaling, AWS Auto Scaling)
• Serverless technologies and patterns (for example, Lambda, Fargate)
• The orchestration of containers (for example, Amazon ECS, Amazon EKS)
Skills in:
• Decoupling workloads so that components can scale independently
• Identifying metrics and conditions to perform scaling actions
• Selecting the appropriate compute options and features (for example, EC2
instance types) to meet business requirements
• Selecting the appropriate resource type and size (for example, the amount of
Lambda memory) to meet business requirements
Task Statement 3: Determine high-performing database solutions.
Knowledge of:
• AWS global infrastructure (for example, Availability Zones, AWS Regions)
• Caching strategies and services (for example, Amazon ElastiCache)
• Data access patterns (for example, read-intensive compared with
write-intensive)
• Database capacity planning (for example, capacity units, instance types,
Provisioned IOPS)
• Database connections and proxies
• Database engines with appropriate use cases (for example, heterogeneous
migrations, homogeneous migrations)
• Database replication (for example, read replicas)
• Database types and services (for example, serverless, relational compared with
non-relational, in-memory)
Skills in:
• Configuring read replicas to meet business requirements
• Designing database architectures
• Determining an appropriate database engine (for example, MySQL compared with
PostgreSQL)
• Determining an appropriate database type (for example, Amazon Aurora, Amazon
DynamoDB)
• Integrating caching to meet business requirements
Task Statement 4: Determine high-performing and/or scalable network
architectures.
Knowledge of:
• Edge networking services with appropriate use cases (for example, Amazon
CloudFront, AWS Global Accelerator)
• How to design network architecture (for example, subnet tiers, routing, IP
addressing)
• Load balancing concepts (for example, Application Load Balancer)
• Network connection options (for example, AWS VPN, Direct Connect, AWS
PrivateLink)
Skills in:
• Creating a network topology for various architectures (for example,
global, hybrid, multi-tier)
• Determining network configurations that can scale to accommodate future needs
• Determining the appropriate placement of resources to meet business
requirements
• Selecting the appropriate load balancing strategy
Task Statement 5: Determine high-performing data ingestion and transformation
solutions.
Knowledge of:
• Data analytics and visualization services with appropriate use cases (for
example, Amazon Athena, AWS Lake Formation, Amazon QuickSight)
• Data ingestion patterns (for example, frequency)
• Data transfer services with appropriate use cases (for example, AWS DataSync,
AWS Storage Gateway)
• Data transformation services with appropriate use cases (for example, AWS
Glue)
• Secure access to ingestion access points
• Sizes and speeds needed to meet business requirements
• Streaming data services with appropriate use cases (for example, Amazon
Kinesis)
Skills in:
• Building and securing data lakes
• Designing data streaming architectures
• Designing data transfer solutions
• Implementing visualization strategies
• Selecting appropriate compute options for data processing (for example, Amazon
EMR)
• Selecting appropriate configurations for ingestion
• Transforming data between formats (for example, .csv to .parquet)
Domain 4: Design Cost-Optimized Architectures
Task Statement 1: Design cost-optimized storage solutions.
Knowledge of:
• Access options (for example, an S3 bucket with Requester Pays object
storage)
• AWS cost management service features (for example, cost allocation tags,
multi-account billing)
• AWS cost management tools with appropriate use cases (for example, AWS Cost
Explorer, AWS Budgets, AWS Cost and Usage Report)
• AWS storage services with appropriate use cases (for example, Amazon FSx,
Amazon EFS, Amazon S3, Amazon EBS)
• Backup strategies
• Block storage options (for example, hard disk drive [HDD] volume types, solid
state drive [SSD] volume types)
• Data lifecycles
• Hybrid storage options (for example, DataSync, Transfer Family, Storage
Gateway)
• Storage access patterns
• Storage tiering (for example, cold tiering for object storage)
• Storage types with associated characteristics (for example, object, file,
block)
Skills in:
• Designing appropriate storage strategies (for example, batch uploads to Amazon
S3 compared with individual uploads)
• Determining the correct storage size for a workload
• Determining the lowest cost method of transferring data for a workload to AWS
storage
• Determining when storage auto scaling is required
• Managing S3 object lifecycles
• Selecting the appropriate backup and/or archival solution
• Selecting the appropriate service for data migration to storage services
• Selecting the appropriate storage tier
• Selecting the correct data lifecycle for storage
• Selecting the most cost-effective storage service for a workload
Task Statement 2: Design cost-optimized compute solutions.
Knowledge of:
• AWS cost management service features (for example, cost allocation tags,
multi-account billing)
• AWS cost management tools with appropriate use cases (for example, Cost
Explorer, AWS Budgets, AWS Cost and Usage Report)
• AWS global infrastructure (for example, Availability Zones, AWS Regions)
• AWS purchasing options (for example, Spot Instances, Reserved Instances,
Savings Plans)
• Distributed compute strategies (for example, edge processing)
• Hybrid compute options (for example, AWS Outposts, AWS Snowball Edge)
• Instance types, families, and sizes (for example, memory optimized, compute
optimized, virtualization)
• Optimization of compute utilization (for example, containers, serverless
computing, microservices)
• Scaling strategies (for example, auto scaling, hibernation)
Skills in:
• Determining an appropriate load balancing strategy (for example,
Application Load Balancer [Layer 7] compared with Network Load Balancer [Layer
4] compared with Gateway Load Balancer)
• Determining appropriate scaling methods and strategies for elastic workloads
(for example, horizontal compared with vertical, EC2 hibernation)
• Determining cost-effective AWS compute services with appropriate use cases
(for example, Lambda, Amazon EC2, Fargate)
• Determining the required availability for different classes of workloads (for
example, production workloads, non-production workloads)
• Selecting the appropriate instance family for a workload
• Selecting the appropriate instance size for a workload
Task Statement 3: Design cost-optimized database solutions.
Knowledge of:
• AWS cost management service features (for example, cost allocation tags,
multi-account billing)
• AWS cost management tools with appropriate use cases (for example, Cost
Explorer, AWS Budgets, AWS Cost and Usage Report)
• Caching strategies
• Data retention policies
• Database capacity planning (for example, capacity units)
• Database connections and proxies
• Database engines with appropriate use cases (for example, heterogeneous
migrations, homogeneous migrations)
• Database replication (for example, read replicas)
• Database types and services (for example, relational compared with
non-relational, Aurora, DynamoDB)
Skills in:
• Designing appropriate backup and retention policies (for example, snapshot
frequency)
• Determining an appropriate database engine (for example, MySQL compared with
PostgreSQL)
• Determining cost-effective AWS database services with appropriate use cases
(for example, DynamoDB compared with Amazon RDS, serverless)
• Determining cost-effective AWS database types (for example, time series
format, columnar format)
• Migrating database schemas and data to different locations and/or different
database engines
Task Statement 4: Design cost-optimized network architectures.
Knowledge of:
• AWS cost management service features (for example, cost allocation tags,
multi-account billing)
• AWS cost management tools with appropriate use cases (for example, Cost
Explorer, AWS Budgets, AWS Cost and Usage Report)
• Load balancing concepts (for example, Application Load Balancer)
• NAT gateways (for example, NAT instance costs compared with NAT gateway costs)
• Network connectivity (for example, private lines, dedicated lines, VPNs)
• Network routing, topology, and peering (for example, AWS Transit Gateway, VPC
peering)
• Network services with appropriate use cases (for example, DNS)
Skills in:
• Configuring appropriate NAT gateway types for a network (for example, a
single shared NAT gateway compared with NAT gateways for each Availability Zone)
• Configuring appropriate network connections (for example, Direct Connect
compared with VPN compared with internet)
• Configuring appropriate network routes to minimize network transfer costs (for
example, Region to Region, Availability Zone to Availability Zone, private to
public, Global Accelerator, VPC endpoints)
• Determining strategic needs for content delivery networks (CDNs) and edge
caching
• Reviewing existing workloads for network optimizations
• Selecting an appropriate throttling strategy
• Selecting the appropriate bandwidth allocation for a network device (for
example, a single VPN compared with multiple VPNs, Direct Connect speed)
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Question 1:
A software development company is using serverless computing with AWS Lambda to
build and run applications without having to set up or manage servers. They have
a Lambda function that connects to a MongoDB Atlas, which is a popular Database
as a Service (DBaaS) platform and also uses a third party API to fetch certain
data for their application. One of the developers was instructed to create the
environment variables for the MongoDB database hostname, username, and password
as well as the API credentials that will be used by the Lambda function for DEV,
SIT, UAT, and PROD environments.
Considering that the Lambda function is storing sensitive database and API
credentials, how can this information be secured to prevent other developers in
the team, or anyone, from seeing these credentials in plain text? Select the
best option that provides maximum security.
A. Enable SSL encryption that leverages on AWS CloudHSM to store and encrypt the
sensitive information.
B. AWS Lambda does not provide encryption for the environment variables. Deploy
your code to an EC2 instance instead.
C. There is no need to do anything because, by default, AWS Lambda already
encrypts the environment variables using the AWS Key Management Service.
D. Create a new KMS key and use it to enable encryption helpers that leverage on
AWS Key Management Service to store and encrypt the sensitive information.
Correct Answer: D
Explanation
When you create or update Lambda functions that use environment variables, AWS
Lambda encrypts them using the AWS Key Management Service. When your Lambda
function is invoked, those values are decrypted and made available to the Lambda
code.
The first time you create or update Lambda functions that use environment
variables in a region, a default service key is created for you automatically
within AWS KMS. This key is used to encrypt environment variables. However, if
you wish to use encryption helpers and use KMS to encrypt environment variables
after your Lambda function is created, you must create your own AWS KMS key and
choose it instead of the default key. The default key will give errors when
chosen. Creating your own key gives you more flexibility, including the ability
to create, rotate, disable, and define access controls, and to audit the
encryption keys used to protect your data.
Question 2:
A company hosted an e-commerce website on an Auto Scaling group of EC2
instances behind an Application Load Balancer. The Solutions Architect noticed
that the website is receiving a large number of illegitimate external requests
from multiple systems with IP addresses that constantly change. To resolve the
performance issues, the Solutions Architect must implement a solution that would
block the illegitimate requests with minimal impact on legitimate traffic.
Which of the following options fulfills this requirement?
A. Create a regular rule in AWS WAF and associate the web ACL to an Application
Load Balancer.
B. Create a rate-based rule in AWS WAF and associate the web ACL to an
Application Load Balancer.
C. Create a custom rule in the security group of the Application Load Balancer
to block the offending requests.
D. Create a custom network ACL and associate it with the subnet of the
Application Load Balancer to block the offending requests.
Correct Answer: B
Question 4:
There was an incident in your production environment where the user data
stored in the S3 bucket has been accidentally deleted by one of the Junior
DevOps Engineers. The issue was escalated to your manager and after a few days,
you were instructed to improve the security and protection of your AWS
resources.
What combination of the following options will protect the S3 objects in your
bucket from both accidental deletion and overwriting? (Select TWO.)
A. Enable Versioning
B. Enable Amazon S3 Intelligent-Tiering
C. Provide access to S3 data strictly through pre-signed URL only
D. Enable Multi-Factor Authentication Delete
E. Disallow S3 Delete using an IAM bucket policy
Correct Answer: B,D
Question 5:
A popular social media website uses a CloudFront web distribution to serve
their static contents to their millions of users around the globe. They are
receiving a number of complaints recently that their users take a lot of time to
log into their website. There are also occasions when their users are getting
HTTP 504 errors. You are instructed by your manager to significantly reduce the
user’s login time to further optimize the system.
Which of the following options should you use together to set up a
cost-effective solution that can improve your application’s performance? (Select
TWO.)
A. Customize the content that the CloudFront web distribution delivers to your
users using Lambda@Edge, which allows your Lambda functions to execute the
authentication process in AWS locations closer to the users.
B. Deploy your application to multiple AWS regions to accommodate your users
around the world. Set up a Route 53 record with latency routing policy to route
incoming traffic to the region that provides the best latency to the user.
C. Configure your origin to add a Cache-Control max-age directive to your
objects, and specify the longest practical value for max-age to increase the
cache hit ratio of your CloudFront distribution.
D. Set up an origin failover by creating an origin group with two origins.
Specify one as the primary origin and the other as the second origin which
CloudFront automatically switches to when the primary origin returns specific
HTTP status code failure responses.
E. Use multiple and geographically disperse VPCs to various AWS regions then
create a transit VPC to connect all of your resources. In order to handle the
requests faster, set up Lambda functions in each region using the AWS Serverless
Application Model (SAM) service.
Correct Answer: A,D
Question 6:
A company is using Amazon S3 to store frequently accessed data. When an
object is created or deleted, the S3 bucket will send an event notification to
the Amazon SQS queue. A solutions architect needs to create a solution that will
notify the development and operations team about the created or deleted objects.
Which of the following would satisfy this requirement?
A. Create a new Amazon SNS FIFO topic for the other team. Grant Amazon S3
permission to send the notification to the second SNS topic.
B. Set up another Amazon SQS queue for the other team. Grant Amazon S3
permission to send a notification to the second SQS queue.
C. Set up an Amazon SNS topic and configure two Amazon SQS queues to poll the
SNS topic. Grant Amazon S3 permission to send notifications to Amazon SNS and
update the bucket to use the new SNS topic.
D. Create an Amazon SNS topic and configure two Amazon SQS queues to subscribe
to the topic. Grant Amazon S3 permission to send notifications to Amazon SNS and
update the bucket to use the new SNS topic.
Correct Answer: D
Appendix
Which key tools, technologies, and concepts might be covered on the exam?
The following is a non-exhaustive list of the tools and technologies that could
appear on the exam. This list is subject to change and is provided to help you
understand the general scope of services, features, or technologies on the exam.
The general tools and technologies in this list appear in no particular order.
AWS services are grouped according to their primary functions. While some of
these technologies will likely be covered more than others on the exam, the
order and placement of them in this list is no indication of relative weight or
importance:
• Compute
• Cost management
• Database
• Disaster recovery
• High performance
• Management and governance
• Microservices and component decoupling
• Migration and data transfer
• Networking, connectivity, and content delivery
• Resiliency
• Security
• Serverless and event-driven design principles
• Storage
AWS services and features
Analytics:
• Amazon Athena • AWS Data Exchange • AWS Data Pipeline • Amazon EMR • AWS Glue • Amazon Kinesis • AWS Lake Formation • Amazon Managed Streaming for Apache Kafka (Amazon MSK) • Amazon OpenSearch Service (Amazon Elasticsearch Service) • Amazon QuickSight • Amazon Redshift Application Integration: • Amazon AppFlow • AWS AppSync • Amazon EventBridge (Amazon CloudWatch Events) • Amazon MQ • Amazon Simple Notification Service (Amazon SNS) • Amazon Simple Queue Service (Amazon SQS) • AWS Step Functions Version 1.0 SAA-C03 12 | PAGE AWS Cost Management: • AWS Budgets • AWS Cost and Usage Report • AWS Cost Explorer • Savings Plans Compute: • AWS Batch • Amazon EC2 • Amazon EC2 Auto Scaling • AWS Elastic Beanstalk • AWS Outposts • AWS Serverless Application Repository • VMware Cloud on AWS • AWS Wavelength Containers: • Amazon Elastic Container Registry (Amazon ECR) • Amazon Elastic Container Service (Amazon ECS) • Amazon ECS Anywhere • Amazon Elastic Kubernetes Service (Amazon EKS) • Amazon EKS Anywhere • Amazon EKS Distro Database: • Amazon Aurora • Amazon Aurora Serverless • Amazon DocumentDB (with MongoDB compatibility) • Amazon DynamoDB • Amazon ElastiCache • Amazon Keyspaces (for Apache Cassandra) • Amazon Neptune • Amazon Quantum Ledger Database (Amazon QLDB) • Amazon RDS • Amazon Redshift • Amazon Timestream Developer Tools: • AWS X-Ray Front-End Web and Mobile: • AWS Amplify • Amazon API Gateway • AWS Device Farm • Amazon Pinpoint Machine Learning: • Amazon Comprehend • Amazon Forecast • Amazon Fraud Detector • Amazon Kendra • Amazon Lex • Amazon Polly • Amazon Rekognition • Amazon SageMaker • Amazon Textract • Amazon Transcribe • Amazon Translate Management and Governance: |
• AWS Auto Scaling • AWS CloudFormation • AWS CloudTrail • Amazon CloudWatch • AWS Command Line Interface (AWS CLI) • AWS Compute Optimizer • AWS Config • AWS Control Tower • AWS License Manager • Amazon Managed Grafana • Amazon Managed Service for Prometheus • AWS Management Console • AWS Organizations • AWS Personal Health Dashboard • AWS Proton • AWS Service Catalog • AWS Systems Manager • AWS Trusted Advisor • AWS Well-Architected Tool Media Services: |
Out-of-scope AWS services and features The following is a non-exhaustive list of AWS services and features that are not covered on the exam. These services and features do not represent every AWS offering that is excluded from the exam content. Analytics: • Amazon CloudSearch Application Integration: • Amazon Managed Workflows for Apache Airflow (Amazon MWAA) AR and VR: • Amazon Sumerian Blockchain: • Amazon Managed Blockchain Compute: • Amazon Lightsail Database: • Amazon RDS on VMware Developer Tools: • AWS Cloud9 • AWS Cloud Development Kit (AWS CDK) • AWS CloudShell • AWS CodeArtifact • AWS CodeBuild • AWS CodeCommit • AWS CodeDeploy • Amazon CodeGuru • AWS CodeStar • Amazon Corretto • AWS Fault Injection Simulator (AWS FIS) • AWS Tools and SDKs Front-End Web and Mobile: • Amazon Location Service Game Tech: • Amazon GameLift • Amazon Lumberyard Internet of Things: • All services Version 1.0 SAA-C03 16 | PAGE Machine Learning: • Apache MXNet on AWS • Amazon Augmented AI (Amazon A2I) • AWS DeepComposer • AWS Deep Learning AMIs (DLAMI) • AWS Deep Learning Containers • AWS DeepLens • AWS DeepRacer • Amazon DevOps Guru • Amazon Elastic Inference • Amazon HealthLake • AWS Inferentia • Amazon Lookout for Equipment • Amazon Lookout for Metrics • Amazon Lookout for Vision • Amazon Monitron • AWS Panorama • Amazon Personalize • PyTorch on AWS • Amazon SageMaker Data Wrangler • Amazon SageMaker Ground Truth • TensorFlow on AWS Management and Governance: • AWS Chatbot • AWS Console Mobile Application • AWS Distro for OpenTelemetry • AWS OpsWorks Media Services: • AWS Elemental Appliances and Software • AWS Elemental MediaConnect • AWS Elemental MediaConvert • AWS Elemental MediaLive • AWS Elemental MediaPackage • AWS Elemental MediaStore • AWS Elemental MediaTailor • Amazon Interactive Video Service (Amazon IVS) Migration and Transfer: • Migration Evaluator (formerly TSO Logic) Networking and Content Delivery: • AWS App Mesh • AWS Cloud Map Version 1.0 SAA-C03 17 | PAGE Quantum Technologies: • Amazon Braket Robotics: • AWS RoboMaker Satellite: • AWS Ground Station |
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