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3V04122 NSX Design (3V0-41.22)
The course teaches advanced NSX design, covering architecture, routing, security, services, and multi‑site strategies, enabling professionals to create scalable, secure software‑defined networks and integrate them with VMware environments.
135
Minutes
60
Questions
300/500
Passing Score
$250
Exam Cost
Who Should Take This
Network architects, senior engineers, and solutions designers with at least three years of VMware NSX experience should enroll. They aim to deepen strategic design skills, master multi‑site deployments, and lead complex security and routing implementations across enterprise data centers and cloud‑native environments.
What's Covered
1
Domain 1: NSX Architecture
2
Domain 2: Routing Design
3
Domain 3: Security Design
4
Domain 4: Services Design
5
Domain 5: Multi-Site Design
6
Domain 6: Operations Design
7
Domain 7: Migration Design
What's Included in AccelaStudy® AI
Adaptive Knowledge Graph
Practice Questions
Lesson Modules
Console Simulator Labs
Exam Tips & Strategy
20 Activity Formats
Course Outline
70 learning goals
1
Domain 1: NSX Architecture
2 topics
Logical Design
- Apply NSX logical network architecture design including transport zones, segments, and policy model configuration and operational procedures for enterprise VMware environments.
- Apply NSX logical network architecture design including transport zones, segments, and policy model best practices including deployment standards and integration with related components.
- Analyze NSX logical network architecture design including transport zones, segments, and policy model configuration and data to identify issues, performance bottlenecks, and optimization opportunities.
- Analyze NSX logical network architecture design including transport zones, segments, and policy model tradeoffs between different implementation approaches evaluating complexity, cost, and operational impact.
- Design a NSX logical network architecture design including transport zones, segments, and policy model strategy that satisfies enterprise requirements for scalability, performance, security, and governance.
Physical Integration
- Apply NSX physical network integration design including TEP networking, uplink configuration, and MTU techniques for complex scenarios requiring multi-component coordination and integration.
- Apply NSX physical network integration design including TEP networking, uplink configuration, and MTU integration with monitoring, automation, and third-party systems for unified management.
- Analyze NSX physical network integration design including TEP networking, uplink configuration, and MTU failures and degradation using diagnostic tools, logs, and metrics to determine root causes.
- Analyze the operational impact of NSX physical network integration design including TEP networking, uplink configuration, and MTU changes on dependent services and infrastructure stability.
- Design comprehensive NSX physical network integration design including TEP networking, uplink configuration, and MTU procedures including automation, monitoring, escalation, and documentation.
2
Domain 2: Routing Design
2 topics
Gateway Topology
- Apply Tier-0/Tier-1 gateway topology design including BGP, ECMP, and multi-tenant VRF routing configuration and operational procedures for enterprise VMware environments.
- Apply Tier-0/Tier-1 gateway topology design including BGP, ECMP, and multi-tenant VRF routing best practices including deployment standards and integration with related components.
- Analyze Tier-0/Tier-1 gateway topology design including BGP, ECMP, and multi-tenant VRF routing configuration and data to identify issues, performance bottlenecks, and optimization opportunities.
- Analyze Tier-0/Tier-1 gateway topology design including BGP, ECMP, and multi-tenant VRF routing tradeoffs between different implementation approaches evaluating complexity, cost, and operational impact.
- Design a Tier-0/Tier-1 gateway topology design including BGP, ECMP, and multi-tenant VRF routing strategy that satisfies enterprise requirements for scalability, performance, security, and governance.
Edge Architecture
- Apply edge node architecture design including sizing, placement, cluster configuration, and HA mode techniques for complex scenarios requiring multi-component coordination and integration.
- Apply edge node architecture design including sizing, placement, cluster configuration, and HA mode integration with monitoring, automation, and third-party systems for unified management.
- Analyze edge node architecture design including sizing, placement, cluster configuration, and HA mode failures and degradation using diagnostic tools, logs, and metrics to determine root causes.
- Analyze the operational impact of edge node architecture design including sizing, placement, cluster configuration, and HA mode changes on dependent services and infrastructure stability.
- Design comprehensive edge node architecture design including sizing, placement, cluster configuration, and HA mode procedures including automation, monitoring, escalation, and documentation.
3
Domain 3: Security Design
2 topics
Micro-Segmentation
- Apply micro-segmentation policy architecture design with zone-based security and dynamic membership configuration and operational procedures for enterprise VMware environments.
- Apply micro-segmentation policy architecture design with zone-based security and dynamic membership best practices including deployment standards and integration with related components.
- Analyze micro-segmentation policy architecture design with zone-based security and dynamic membership configuration and data to identify issues, performance bottlenecks, and optimization opportunities.
- Analyze micro-segmentation policy architecture design with zone-based security and dynamic membership tradeoffs between different implementation approaches evaluating complexity, cost, and operational impact.
- Design a micro-segmentation policy architecture design with zone-based security and dynamic membership strategy that satisfies enterprise requirements for scalability, performance, security, and governance.
Advanced Security
- Apply IDS/IPS, malware prevention, and NDR design for comprehensive east-west and north-south protection techniques for complex scenarios requiring multi-component coordination and integration.
- Apply IDS/IPS, malware prevention, and NDR design for comprehensive east-west and north-south protection integration with monitoring, automation, and third-party systems for unified management.
- Analyze IDS/IPS, malware prevention, and NDR design for comprehensive east-west and north-south protection failures and degradation using diagnostic tools, logs, and metrics to determine root causes.
- Analyze the operational impact of IDS/IPS, malware prevention, and NDR design for comprehensive east-west and north-south protection changes on dependent services and infrastructure stability.
- Design comprehensive IDS/IPS, malware prevention, and NDR design for comprehensive east-west and north-south protection procedures including automation, monitoring, escalation, and documentation.
4
Domain 4: Services Design
2 topics
Load Balancer Design
- Apply load balancer architecture design selecting NSX native LB vs ALB for application requirements configuration and operational procedures for enterprise VMware environments.
- Apply load balancer architecture design selecting NSX native LB vs ALB for application requirements best practices including deployment standards and integration with related components.
- Analyze load balancer architecture design selecting NSX native LB vs ALB for application requirements configuration and data to identify issues, performance bottlenecks, and optimization opportunities.
- Analyze load balancer architecture design selecting NSX native LB vs ALB for application requirements tradeoffs between different implementation approaches evaluating complexity, cost, and operational impact.
- Design a load balancer architecture design selecting NSX native LB vs ALB for application requirements strategy that satisfies enterprise requirements for scalability, performance, security, and governance.
VPN Design
- Apply VPN architecture design for site-to-site IPsec and L2 VPN network extension scenarios techniques for complex scenarios requiring multi-component coordination and integration.
- Apply VPN architecture design for site-to-site IPsec and L2 VPN network extension scenarios integration with monitoring, automation, and third-party systems for unified management.
- Analyze VPN architecture design for site-to-site IPsec and L2 VPN network extension scenarios failures and degradation using diagnostic tools, logs, and metrics to determine root causes.
- Analyze the operational impact of VPN architecture design for site-to-site IPsec and L2 VPN network extension scenarios changes on dependent services and infrastructure stability.
- Design comprehensive VPN architecture design for site-to-site IPsec and L2 VPN network extension scenarios procedures including automation, monitoring, escalation, and documentation.
5
Domain 5: Multi-Site Design
2 topics
Federation Design
- Apply NSX federation architecture design for multi-site policy consistency and stretched segments configuration and operational procedures for enterprise VMware environments.
- Apply NSX federation architecture design for multi-site policy consistency and stretched segments best practices including deployment standards and integration with related components.
- Analyze NSX federation architecture design for multi-site policy consistency and stretched segments configuration and data to identify issues, performance bottlenecks, and optimization opportunities.
- Analyze NSX federation architecture design for multi-site policy consistency and stretched segments tradeoffs between different implementation approaches evaluating complexity, cost, and operational impact.
- Design a NSX federation architecture design for multi-site policy consistency and stretched segments strategy that satisfies enterprise requirements for scalability, performance, security, and governance.
DR Networking
- Apply disaster recovery network design including IP mobility and traffic failover automation techniques for complex scenarios requiring multi-component coordination and integration.
- Apply disaster recovery network design including IP mobility and traffic failover automation integration with monitoring, automation, and third-party systems for unified management.
- Analyze disaster recovery network design including IP mobility and traffic failover automation failures and degradation using diagnostic tools, logs, and metrics to determine root causes.
- Analyze the operational impact of disaster recovery network design including IP mobility and traffic failover automation changes on dependent services and infrastructure stability.
- Design comprehensive disaster recovery network design including IP mobility and traffic failover automation procedures including automation, monitoring, escalation, and documentation.
6
Domain 6: Operations Design
2 topics
Monitoring Design
- Apply NSX monitoring architecture with Traceflow, flow analysis, and Aria Operations for Networks configuration and operational procedures for enterprise VMware environments.
- Apply NSX monitoring architecture with Traceflow, flow analysis, and Aria Operations for Networks best practices including deployment standards and integration with related components.
- Analyze NSX monitoring architecture with Traceflow, flow analysis, and Aria Operations for Networks configuration and data to identify issues, performance bottlenecks, and optimization opportunities.
- Analyze NSX monitoring architecture with Traceflow, flow analysis, and Aria Operations for Networks tradeoffs between different implementation approaches evaluating complexity, cost, and operational impact.
- Design a NSX monitoring architecture with Traceflow, flow analysis, and Aria Operations for Networks strategy that satisfies enterprise requirements for scalability, performance, security, and governance.
Troubleshooting Design
- Apply network troubleshooting framework design with diagnostic workflows and escalation procedures techniques for complex scenarios requiring multi-component coordination and integration.
- Apply network troubleshooting framework design with diagnostic workflows and escalation procedures integration with monitoring, automation, and third-party systems for unified management.
- Analyze network troubleshooting framework design with diagnostic workflows and escalation procedures failures and degradation using diagnostic tools, logs, and metrics to determine root causes.
- Analyze the operational impact of network troubleshooting framework design with diagnostic workflows and escalation procedures changes on dependent services and infrastructure stability.
- Design comprehensive network troubleshooting framework design with diagnostic workflows and escalation procedures procedures including automation, monitoring, escalation, and documentation.
7
Domain 7: Migration Design
2 topics
Network Migration
- Apply network migration design for transitioning from physical/VLAN to NSX overlay networking configuration and operational procedures for enterprise VMware environments.
- Apply network migration design for transitioning from physical/VLAN to NSX overlay networking best practices including deployment standards and integration with related components.
- Analyze network migration design for transitioning from physical/VLAN to NSX overlay networking configuration and data to identify issues, performance bottlenecks, and optimization opportunities.
- Analyze network migration design for transitioning from physical/VLAN to NSX overlay networking tradeoffs between different implementation approaches evaluating complexity, cost, and operational impact.
- Design a network migration design for transitioning from physical/VLAN to NSX overlay networking strategy that satisfies enterprise requirements for scalability, performance, security, and governance.
Kubernetes Integration
- Apply NSX integration design for Kubernetes pod networking, network policies, and load balancing techniques for complex scenarios requiring multi-component coordination and integration.
- Apply NSX integration design for Kubernetes pod networking, network policies, and load balancing integration with monitoring, automation, and third-party systems for unified management.
- Analyze NSX integration design for Kubernetes pod networking, network policies, and load balancing failures and degradation using diagnostic tools, logs, and metrics to determine root causes.
- Analyze the operational impact of NSX integration design for Kubernetes pod networking, network policies, and load balancing changes on dependent services and infrastructure stability.
- Design comprehensive NSX integration design for Kubernetes pod networking, network policies, and load balancing procedures including automation, monitoring, escalation, and documentation.
Scope
Included Topics
- NSX advanced design including network architecture, routing topology, micro-segmentation strategy, edge design, multi-site federation, services design, and operations framework.
- Enterprise-level VMware technology knowledge for NSX Design.
Not Covered
- Implementation details beyond stated certification scope.
- Vendor-specific third-party configurations.
- Current pricing and partner program details.
Official Exam Page
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