CCIE Data Center
Exam Number 400-151
Associated Certifications CCIE Data Center
Duration 120 minutes (90 – 110 questions)
This exam certifies expert-level skills to plan, design, implement, operate, and troubleshoot complex Data Center infrastructure. It accesses the ability to understand the requirements of Data Centers, how different components in the Data Center interoperate, and ability to translate it into the device configurations.
Exam Description
The Cisco CCIE Data Center Written Exam (400-151) certifies expert-level skills to plan, design, implement, operate, and troubleshoot complex Data Center infrastructure. It accesses the ability to understand the requirements of Data Centers, how different components in the Data Center interoperate, and ability to translate it into the device configurations.
An Evolving Technologies section is included in the Written exam only. It will enable candidates to bridge their core technology expertise with knowledge of the evolving technologies that are being adopted at an accelerated pace, such as cloud, IoT, and network programmability.
It has been recalibrated and will consist of three subdomains and a total of five tasks for which the expected depth of knowledge will be focused on conceptual comprehension. The Evolving Technologies section will account for 10 percent of the total score while the remaining core technologies will account for 90 percent.
The following topics are general guidelines for the content likely to be included on the exam. However, other related topics may also appear on any specific delivery of the exam. In order to better reflect the contents of the exam and for clarity purposes, the guidelines below may change at any time without notice.
1.0 Cisco Data Center L2/L3 Technologies
1.1 Design Implement and Troubleshoot Complex Layer 2 Technologies
1.1.a Design, Implement and Troubleshoot Highly Available and redundant topologies for example vPC, fabricpath, STP
1.1.b Design, Implement and Troubleshoot Data Center Layer 2 overlays for example VXLAN, OTV, EVPN
1.1.c Design, Implement and Troubleshoot Network management protocols for example PTP, NTP, DNS, DHCP
1.1.d Design, Implement and Troubleshoot Traffic management for example queuing, policing, shaping
1.1.e Design, Implement and Troubleshoot layer 2 security features for example port security, MACsec, ACL, private vlans
1.2 Design, Implement and Troubleshoot Complex Layer 3 Technologies
1.2.a Design, Implement and Troubleshoot Routing Protocols and features for example OSPF, ISIS, MBGP, IBGP, PBR, BFD
1.2.b Design, Implement and Troubleshoot Layer 3 Overlay Protocols for example OTV, LISP
1.2.c Design, Implement and Troubleshoot Multicast protocols for example PIM, IGMP, RP, BSR
1.2.d Design, Implement and Troubleshoot layer 3 security features for example CoPP, ACL’s, DAI, ip source guard
1.2.e Design, Implement and Troubleshoot Monitoring services for example Netflow
1.3 Design, Implement and Troubleshoot External Fabric Connectivity
1.3.a Design, Implement and Troubleshoot policy driven External Fabric Connectivity for example L2/L3 connectivity
2.0 Cisco Data Center Network Services
2.1 Design, Implement and Troubleshoot Service Insertion and Redirection
2.1.a Design, Implement and Troubleshoot Service Insertion and Redirection for example LB, vPATH, ITD, RISE
2.2 Design, Implement and Troubleshoot network services
2.2.a Design, Implement and Troubleshoot network services for example policy drivenL4-L7 services
3.0 Data Center Storage Networking and Compute
3.1 Configure and Troubleshoot Data Center Storage Protocols
3.1.a Describe, Configure and Troubleshoot infrastructure to support Block Storage Protocols for example FC, FCoE, iSCSI, DCB
3.1.b Configure and Troubleshoot infrastructure to support File Storage Protocols for example NFS, CIFS
3.2 Design, Implement and Troubleshoot Data Center Storage Networking Features
3.2.a Design, Implement and Troubleshoot Data Center Storage Networking Features for example zoning, multihop technologies
3.3 Implement and Troubleshoot Compute resources
3.3.a Implement and Troubleshoot Compute policies and pools for example SAN/LAN policies, boot policies, profiles
3.3.b Analyze and Troubleshoot Compute resources using tools such as UCS Central, UCSM
3.4 Design, Implement and Troubleshoot Data Center Compute Connectivity
3.4.a Design, Implement and Troubleshoot Data Center Compute Connectivity for example SAN/LAN uplinks, rack server integration, fabric ports, appliance ports
3.5 Design, Implement and Troubleshoot Virtual and Physical End Point Connectivity
3.5.a Design, Implement and Troubleshoot Virtual and Physical End Point Connectivity
4.0 Data Center Automation and Orchestration
4.1 Implement and Troubleshoot Data Center Automation
4.1.a Implement and Troubleshoot Data Center Automation using methods such as REST API implemented by scripting languages including Python
4.2 Implement and Troubleshoot Data Center Orchestration Tools
4.2.a Implement and Troubleshoot Data Center Orchestration using Tools such as UCSD, UCS Central, CPO
4.3 Integrate Cisco Cloud offerings into existing Data Center infrastructure
4.3.a Describe and Integrate Cisco Cloud technologies into existing Data Center infrastructure using solutions such as Cisco ONE Enterprise cloud Suite
5.0 Data Center Fabric Infrastructure
5.1 Design, Implement and Troubleshoot policy and non-policy driven Internal Fabric Connectivity
5.1.a Design, Implement and Troubleshoot policy and non-policy driven Internal Fabric connectivity for example ECMP, ISIS, inband mgmt, VXLAN
5.2 Design, Implement and Troubleshoot Infrastructure policies and elements
5.2.a Design, Implement and Troubleshoot policy driven Infrastructure for example interface policies, MGMT policies
5.2.b Configure and Troubleshoot physical infrastructure components for example controllers, switches
5.2.c Analyze and Troubleshoot logical infrastructure elements using health indicators
6.0 Evolving Technologies
6.1 Cloud
6.1.a Compare and contrast Cloud deployment models
6.1.a [i] Infrastructure, platform, and software services (XaaS)
6.1.a [ii] Performance and reliability
6.1.a [iii] Security and privacy
6.1.a [iv] Scalability and interoperability
6.1.b Describe Cloud implementations and operations
6.1.b [i] Automation and orchestration
6.1.b [ii] Workload mobility
6.1.b [iii] Troubleshooting and management
6.1.b [iv] OpenStack components
6.2 Network Programmability (SDN)
6.2.a Describe functional elements of network programmability (SDN) and how they interact
6.2.a [i] Controllers
6.2.a [ii] APIs
6.2.a [iii] Scripting
6.2.a [iv] Agents
6.2.a [v] Northbound vs. Southbound protocols
6.2.b Describe aspects of virtualization and automation in network environments
6.2.b [i] DevOps methodologies, tools and workflows
6.2.b [ii] Network/application function virtualization (NFV, AFV)
6.2.b [iii] Service function chaining
6.2.b [iv] Performance, availability, and scaling considerations
6.3 Internet of Things (IoT)
6.3.a Describe architectural framework and deployment considerations for Internet of Things
6.3.a [i] Performance, reliability and scalability
6.3.a [ii] Mobility
6.3.a [iii] Security and privacy
6.3.a [iv] Standards and compliance
6.3.a [v] Migration
6.3.a [vi] Environmental impacts on the network
QUESTION: No: 1
Which I ETF standard is the most efficient messaging protocol used in an |oT network?
A. SNMP
B. HTTP
C. CoAP
D. MQTI
Answer: C
QUESTION: No: 2
Within an ACI fabric, a routing protocol is needed to assist with route redistribution between the outside
networks and the internal fabric. Which routing protocol is needed to run in the fabric at location 1 to allow
the VM access to the networks advertised by the external Layer 3 network.
A. eBGP
B. OSPF
C. MP-BGP
D. iBGP
E. IS-IS
Answer: C
QUESTION: No: 3
How do you manually configure a vNIC MAC address?
A. Use the mac -address-table static command.
B. Modify the dynamic vNIC connection policy.
C. Use the set identity dynamic-mac command.
D. Modify the adapter policy.
Answer: D
QUESTION: No: 4
Which two statements about import and export route control in an ACI fabric are t rue? (Choose two.)
A. Prefixes learned from OSPF/EIGRP L30urs are never permitted inbound by default.
B. Prefixes learned from BGP L3outs cannot be filtered inbound.
C. Export route control controls if the prefixes are redistributed from NIP-BGP to the egress leaf.
D. Prefixes permitted inbound are redistributed into NIP-BGP at the ingress leaf.
Answer: C,D
QUESTION: No: 5
While doing service insertion with vASA with route peering, which two parts must be configured? (Choose
two.)
A. The path for interfaces must be specified when the L4-L7 device is created.
B. The route peering profile must be specified when the L4-L7 Service Graph template is created.
C. The VNI name must be specified when the L4-L7 device is created.
D. The chassis must be specified when the L4-L7 device is created.
Answer: A,B
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