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

For this workload, the access pattern is centered on each user’s activity history over time (the company is planning a marketing campaign based on each user’s activity). In DynamoDB, the most effective way to store and query time-ordered events per entity is to use a composite primary key where the entity identifier is the partition key and a time attribute is the sort key . Therefore, using user ID as the partition key groups all events for a given user together, and using timestamp as the sort key allows efficient retrieval in chronological order and supports range queries (for example, “activities in the last 7 days” or “between two dates”).

This design also helps maximize provisioned throughput efficiency and reduce throttling risk because it distributes data across partitions based on the partition key values (user IDs). With many users, writes and reads naturally spread across multiple partition key values rather than concentrating on a small set. The sort key further enables multiple activity records per user without overwriting items and supports precise queries without scanning.

Option B (product ID as partition key) does not align with the stated marketing need (per-user activity). It would cluster all users’ actions for a popular product into the same partition key, increasing the chance of hot partitions and throttling. Option C also risks hot partitions for popular product IDs; auto scaling helps capacity management but does not fix poor key distribution or hot-key access patterns. Option D (monotonic counter as partition key) is particularly problematic: sequential keys can create uneven distribution and a throughput bottleneck pattern, and it does not support user-centric queries efficiently.

Thus, A best matches the data model (user events over time), supports efficient queries, and reduces throttling risk by distributing workload across user IDs.

The goal is minimal downtime during deployment and fast rollback if problems occur. In Elastic Beanstalk, the approach that best satisfies both is a blue/green deployment.

With blue/green, the developer deploys the new application version to a separate environment (green) while the current production environment (blue) continues serving traffic. Once validation is complete (health checks, smoke tests), the developer performs a controlled CNAME swap (or routing switch) so traffic shifts from blue to green with near-zero downtime. This reduces risk because the existing environment remains intact and can immediately resume traffic if issues are detected.

Rollback time is also minimized because reverting is simply switching traffic back to the original environment (swap back), rather than rolling back changes across the same environment.

Why the other options are weaker:

All-at-once (C) introduces the highest downtime and risk because it replaces all instances at once, potentially taking the application fully offline and making rollback slower.

Rolling (A) reduces downtime compared to all-at-once, but instances are still updated in-place; if issues appear mid-deployment, rollback is more complex and slower than swapping environments.

Rolling with additional batches (B) can further reduce capacity impact by adding extra instances during deployment, but rollback still involves reversing updates in the same environment and is typically slower than blue/green.

Therefore, deploying to a new environment and using blue/green provides the least downtime and the fastest rollback.

Secrets Management: AWS Secrets Manager is designed specifically for storing and managing sensitive credentials.

Built-in Rotation: Secrets Manager provides automatic secret rotation functionality, enhancing security posture significantly.

IAM Integration: IAM policies and roles grant fine-grained access to ECS Fargate, ensuring the principle of least privilege.

Reduced Overhead: This solution centralizes secrets management and automates rotation, reducing operational overhead compared to the other options.