Amazon Web Services DVA-C02 Exam With Confidence Using Practice Dumps

Amazon CloudFront field-level encryption is specifically designed to protect sensitive fields in HTTP requests. It allows CloudFront to encrypt specific request fields at the edge using asymmetric encryption, ensuring that only authorized application components that possess the private key can decrypt the data.

This approach ensures that sensitive fields remain encrypted throughout transit and processing, while non-sensitive fields can still be accessed normally. This satisfies the requirement that only specific parts of the application can decrypt the data.

Field-level encryption is a native CloudFront capability and is far more secure and scalable than implementing custom encryption logic in Lambda@Edge or Lambda functions. AWS documentation emphasizes using built-in CloudFront security features to minimize operational overhead and reduce the risk of cryptographic implementation errors.

Options A and B introduce unnecessary complexity and custom cryptographic handling, which AWS generally discourages when managed services are available. Option D only secures transport and access control and does not encrypt individual data fields.

Therefore, CloudFront field-level encryption with asymmetric keys is the AWS-recommended and correct solution.

The requirements describe a Git-driven workflow where each new branch automatically gets its own deployment with minimal setup and management. AWS Amplify is designed for exactly this use case for web (and supporting mobile backends): it integrates directly with Git providers and offers continuous deployment. Amplify’s feature branch deployments automatically create a separate deployment (and typically a distinct preview URL) for each connected branch, enabling developers to test and review changes per branch without manually provisioning environments.

With Amplify, the developer connects the repository once, selects the branches to deploy, and Amplify automatically builds and deploys the application whenever code changes are pushed. When a new branch is added, Amplify can be configured to deploy it as a separate environment, providing isolated testing, previewing, and validation. This dramatically reduces operational overhead because Amplify manages build settings, hosting, SSL, and branch-based environments without needing custom CI/CD wiring.

Option A (ECR + ECS + GitHub Actions) can support branch deployments, but it requires substantial operational work: container build pipelines, task/service management, networking, scaling, and environment isolation per branch. Option B (Elastic Beanstalk) can manage deployments, but branch-based automatic deployments are not as native; creating separate environments and managing application versions typically requires more manual steps or additional automation. Option C (Lambda aliases) is not a general-purpose web/mobile deployment approach and does not naturally map “new Git branch” to an isolated deployment environment without significant custom tooling.

Therefore, D is the best fit with the least operational overhead: use AWS Amplify with feature branch deployments to automatically create and manage separate deployments for Git branches.

Why Option C is Correct:Implementing a connection pool in the Redis client reduces connection overhead and avoids frequent connection establishment, which helps to reduce latency and connection failures.

Why Other Options are Incorrect:

Option A: Exponential backoff retry strategies help with transient failures but do not resolve latency caused by frequent connection establishment.

Option B: Storing scores in application memory adds complexity and risks inconsistency.

Option D: Adding more nodes is unnecessary unless the cluster is under heavy load. Latency due to connection failures is better addressed at the application level.

AWS Documentation References:

Amazon ElastiCache Best Practices