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

This solution allows the fastest response for the query because it enables the query to use a single partition key value (the Product ID) and a range of sort key values (the Product Rating) to find the matching items. A global secondary index (GSI) is an index that has a partition key and an optional sort key that are different from those on the base table. A GSI can be created at any time and can be queried or scanned independently of the base table. A local secondary index (LSI) is an index that has the same partition key as the base table, but a different sort key. An LSI can only be created when the base table is created and must be queried together with the base table partition key. Using a GSI with Product ID as the partition key and Review ID as the sort key will not allow the query to use a range of sort key values to find the highest ratings. Using an LSI with Product ID as the partition key and Product Rating as the sort key will not work because Product ID is not the partition key of the base table. Using an LSI with Review ID as the partition key and Product ID as the sort key will not allow the query to use a single partition key value to find the matching items.

The requirement is to automatically delete objects for basic users after 90 days with the least development effort. Amazon S3 provides a built-in, fully managed feature for this: S3 Lifecycle configuration rules . Lifecycle rules can filter objects by prefix (and/or tags) and then perform actions such as expiring (deleting) objects after a specified number of days since creation. Because the bucket does not have versioning enabled, the relevant action is to expire the current object after the retention period.

Option C matches this exactly: create an S3 Lifecycle rule that applies only to objects under the basic/ prefix and configure the rule to expire current versions after 90 days . S3 then automatically and continuously enforces the policy without any code, scheduling, or operational maintenance. This is typically the lowest-effort and most reliable approach because it is handled by S3 itself.

Option A requires writing and operating a Lambda function plus a scheduler, handling pagination, permissions, error handling, retries, and potential costs and throttling when scanning large buckets. That is more development and operational effort than a lifecycle rule. Option B is incorrect because it targets the premium/ prefix, but premium objects must be retained indefinitely. Option D refers to delete markers and unfinished multipart uploads; delete markers are relevant primarily for versioned buckets , and cleaning up multipart uploads does not implement the required “delete basic objects after 90 days” behavior.

Therefore, the correct solution is C : use an S3 Lifecycle rule scoped to the basic/ prefix to expire objects after 90 days, achieving automated retention with minimal development effort.

By default, an Auto Scaling group uses EC2 status checks to determine instance health. EC2 status checks confirm that an instance is running and reachable at the infrastructure level, but they do not validate that the application is healthy behind the load balancer. In this scenario, the ALB is returning HTTP 502 errors and the target group shows instances as unhealthy, meaning the application is failing health checks (or not responding correctly). However, because the Auto Scaling group is using the default EC2 health check type, it does not consider these instances unhealthy for replacement.

AWS recommends configuring the Auto Scaling group to use ELB health checks when instances serve traffic behind an ALB or NLB. With ELB health checks enabled, Auto Scaling evaluates target health as reported by the load balancer target group. If the ALB marks an instance unhealthy, the Auto Scaling group will treat that instance as unhealthy and terminate and replace it automatically, restoring capacity with healthy targets.

Why the other options are insufficient:

Cooldown period (A) affects scaling timing, not health replacement logic.

Lifecycle hook changes (B) can help with initialization timing, but they do not cause Auto Scaling to replace instances based on ALB target health unless ELB health checks are enabled.

Health check grace period (D) delays health evaluation after launch, which can reduce premature replacement, but it still won’t replace instances based on ALB target group status unless the health check type is ELB.

Therefore, switching the Auto Scaling group health check type to Elastic Load Balancing (ELB) is the correct fix.