3V0-21.23 Exam Dumps - VMware vSphere 8.x Advanced Design

The solution will deploy VMware vSphere Enterprise Plus on all hosts within the cluster.

VMware vSphere Enterprise Plus offers advanced networking and storage features that will support the required high availability, performance, and management capabilities. Features such as Distributed Switches and Network I/O Control (NIOC) are critical to meeting the business-critical application and performance requirements for the latency-sensitive stock trading application.

The solution will deploy a single vSphere Distributed Switch with each host connected to it.

A vSphere Distributed Switch (VDS) is ideal for managing network configurations centrally across multiple hosts, which meets the requirement for centralized vSphere operational management. It also ensures consistent network configurations and simplifies network management at scale.

The solution will configure Network I/O control to ensure that system-level bandwidth does not impact workload network traffic.

Network I/O Control (NIOC) is essential for prioritizing network traffic, ensuring that latency-sensitive workloads are not impacted by other system-level or less critical traffic. This is crucial for the performance requirements of the stock trading application.

AES-NI BIOS setting:

Encryption, especially VM Encryption in vSphere, is CPU-intensive because it requires the processing power to encrypt and decrypt data. By enabling AES-NI (Advanced Encryption Standard New Instructions) in the BIOS, ESXi hosts can take advantage of hardware-based acceleration for encryption tasks. This reduces the load on the CPU, thus improving the performance of encryption operations and lowering CPU utilization.

De-duplication effectiveness:

When data is encrypted at the ESXi host level (via VM Encryption), the deduplication process on the storage system becomes less effective. This is because encrypted data is presented as random data, meaning that even identical data blocks will appear different due to encryption. Therefore, deduplication technologies that rely on identifying duplicate data blocks will not be able to achieve the same level of efficiency when the data is encrypted at rest.

A business outcome refers to a result or impact that directly contributes to the strategic goals of the organization, typically focusing on long-term objectives or future benefits. In this case, building a strong foundation for future projects, including cloud infrastructures, aligns with the business goal of positioning the organization for future success and scalability. This outcome is about preparing the organization for the future, which is a key business-driven result.

Based on VMware vSphere 8.x Advanced documentation, the architect is designing a vSphere-based solution to meet three specific requirements: a recovery point objective (RPO) of 15 minutes, a primary and secondary site, and support for orchestration to address application dependencies. The solution must include two VMware technologies that collectively satisfy these requirements.

Requirements Analysis:

Recovery Point Objective (RPO) of 15 minutes: The solution must ensure that no more than 15 minutes of data is lost in a disaster, requiring frequent data replication or synchronization between sites.

Primary and secondary site: The solution must support a disaster recovery (DR) architecture with two distinct sites, implying replication or failover capabilities between them.

Orchestration to address application dependencies: The solution must provide automated recovery workflows to manage the startup order and dependencies of multi-tier applications (e.g., ensuring a database starts before an application server).

Evaluation of Options:

A. vSAN stretched cluster:

Why incorrect: A vSAN stretched cluster provides high availability and disaster recovery by synchronously replicating data across two sites, achieving near-zero RPO and RTO. However, it is designed for high-availability scenarios within a single vSphere cluster spanning sites, not traditional DR with orchestration. vSAN stretched clusters do not natively provide orchestration for application dependencies (e.g., automated recovery plans or startup order), which is a key requirement. Additionally, stretched clusters require low-latency, high-bandwidth connections (typically <5ms RTT), which is not guaranteed in the provided information. This option does not fully meet the orchestration requirement.

B. vSphere HA:

Why incorrect: vSphere High Availability (HA) provides automatic VM restarts within a cluster in case of host failures, but it operates within a single site and does not support replication or failover between primary and secondary sites. vSphere HA does not address the 15-minute RPO requirement, as it does not replicate data, nor does itprovide orchestration for application dependencies across sites. This option is unsuitable for a multi-site DR scenario.

C. Site Recovery Manager:

Why correct: VMware Site Recovery Manager (SRM) is a disaster recovery solution designed for automated failover and failback between primary and secondary sites. SRM supports orchestration of recovery plans, allowing the architect to define the startup order and dependencies of multi-tier applications (e.g., starting a database before an application server). When paired with vSphere Replication, SRM can achieve an RPO of 15 minutes by orchestrating the failover of replicated VMs. SRM meets the requirements for primary/secondary site support, orchestration for application dependencies, and integration with replication technologies to achieve the required RPO.

VMware vSphere 8 documentation highlights SRM for automated DR orchestration, supporting recovery plans and integration with vSphere Replication for site-to-site failover.

D. vSphere Fault Tolerance:

Why incorrect: vSphere Fault Tolerance (FT) provides continuous availability by maintaining a live secondary VM on another host within the same site, with zero RPO and RTO for host failures. However, FT is not designed for multi-site disaster recovery, as it operates within a single cluster and does not replicate data between sites. FT also lacks orchestration capabilities for application dependencies and is resource-intensive, unsuitable for large-scale DR scenarios. This option does not meet the multi-site or orchestration requirements.

E. vSphere Replication:

Why correct: vSphere Replication is a hypervisor-based replication solution that asynchronously replicates VMs from a primary site to a secondary site, supporting an RPO as low as 15 minutes. It integrates with SRM to provide orchestrated recovery, ensuring application dependencies are addressed through SRM’s recovery plans. vSphere Replication meets the 15-minute RPO requirement and supports the primary/secondary site architecture by enabling data replication. When used with SRM, it provides a complete DR solution.

Enable vSphere with Tanzu on a cluster deployed at a remote location.

VMware Cloud Foundation remote clusters can be deployed to extend the functionality of vSphere with Tanzu to remote locations. This allows for containerized workloads to be managed and orchestrated using the same tools as the primary environment, providing consistent management of Tanzu clusters across multiple sites.

Provide resources for virtual machines at an edge location.

Remote clusters can be deployed at edge locations to provide computing resources for workloads that need to run close to the data source. This use case is particularly useful for applications that require low latency or need to process data locally before sending it to the central cloud infrastructure.

The customer's requirement for making it easy to identify and apply patches or updates to ESXi hosts, including pre-staging the files, is focused on simplifying the management of the vSphere environment. This is a key aspect of manageability, which refers to the ease with which IT administrators can handle tasks like patching, updates, and configuration management in a consistent and efficient manner.