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

The correct answer is B because Amazon EventBridge is designed for building loosely coupled event-driven architectures . In this scenario, when an order is placed, the order processing system can publish a single event to an EventBridge event bus. Then, multiple independent consumers can react to that event through separate rules and targets . This matches the requirement to update inventory, send email, notify shipping, and update order history without tightly coupling those actions together.

EventBridge is especially well suited when the company wants to add new processing steps later . A new consumer can be added simply by creating another rule and target for the existing order event, without changing the original order submission code or the existing consumers. This supports extensibility and separation of concerns, which are key goals of event-driven design.

Option A is less appropriate because a single Lambda function that directly calls every downstream system becomes tightly coupled and harder to extend. Option C supports fan-out, but EventBridge provides richer routing, filtering, and event bus semantics for enterprise event-driven workflows. Option D is useful for workflow orchestration, but it creates a more centrally orchestrated pattern rather than the looser publish-and-subscribe model requested in the question.

AWS guidance for modern event-driven architectures emphasizes publishing events and allowing interested services to subscribe independently. EventBridge provides native routing and integration with many AWS services, making it easy to evolve the architecture over time. Therefore, B is the best answer for achieving loose coupling and future extensibility.

This solution will ensure that all orders and updates are stored to Amazon S3 with the least development effort because it uses DynamoDB Streams to capture changes in the DynamoDB table and trigger a Lambda function to write those changes to the S3 bucket. This way, the original Lambda function and API Gateway API endpoint do not need to be modified, and no additional services are required. Option A is not optimal because it will require more development effort to create a new Lambda function and a new API Gateway API endpoint, and to modify the original Lambda function to post updates to the new API endpoint. Option B is not optimal because it will introduce additional costs and complexity to use Amazon Kinesis Data Streams to create a new data stream, and to modify the Lambda function to publish orders to the data stream. Option D is not optimal because it will require more development effort to modify the Lambda function to publish to a new Amazon SNS topic, and to create and subscribe a new Lambda function to the topic.

Amazon S3 event notifications can invoke AWS Lambda functions at very high rates during traffic spikes. In this scenario, up to 500 objects per minute can result in hundreds of concurrent Lambda invocations. By default, Lambda functions share the account’s unreserved concurrency pool , which can cause throttling if the pool is exhausted by sudden bursts.

AWS Lambda reserved concurrency guarantees a specific number of concurrent executions for a function. By configuring reserved concurrency, the developer ensures that sufficient execution capacity is always available for this specific function, regardless of other Lambda workloads in the account. This prevents throttling during high-volume S3 event bursts.

Increasing the timeout (Option A) does not address concurrency limits. Adding a layer (Option B) does not solve invocation throttling. Decreasing memory (Option D) can actually worsen performance and increase execution time.

AWS documentation explicitly recommends reserved concurrency when workloads experience unpredictable or bursty invocation patterns and must run reliably. Therefore, reserving concurrency is the correct and AWS-recommended solution.