Cisco 352-001 Certification Exam Syllabus

352-001 Syllabus, Design Expert Exam Questions PDF, Cisco 352-001 Dumps Free, Design Expert PDF, 352-001 Dumps, 352-001 PDF, Design Expert VCE, 352-001 Questions PDF, Cisco Design Expert Questions PDF, Cisco 352-001 VCEA great way to start the Cisco Certified Design Expert (CCDE) preparation is to begin by properly appreciating the role that syllabus and study guide play in the Cisco 352-001 certification exam. This study guide is an instrument to get you on the same page with Cisco and understand the nature of the Cisco Design Expert exam.

Our team of experts has composed this Cisco 352-001 exam preparation guide to provide the overview about Cisco CCDE Design Written Exam exam, study material, sample questions, practice exam and ways to interpret the exam objectives to help you assess your readiness for the Cisco CCDE exam by identifying prerequisite areas of knowledge. We recommend you to refer the simulation questions and practice test listed in this guide to determine what type of questions will be asked and the level of difficulty that could be tested in the Cisco Design Expert certification exam.

Cisco 352-001 Exam Overview:

Exam Name
 CCDE Design Written Exam
Exam Number 352-001 CCDE
Exam Price $450 USD
Duration 120 minutes
Number of Questions 90-110
Passing Score Variable (750-850 / 1000 Approx.)
Exam Registration PEARSON VUE
Sample Questions Cisco 352-001 Sample Questions
Practice Exam Cisco Certified Design Expert Practice Test

Cisco 352-001 Exam Topics:

Section Weight Objectives
Layer 2 Control Plane 24%

1. Describe fast convergence techniques and mechanisms

  • Down detection
  • Interface dampening

2. Describe loop detection and mitigation protocols

  • Spanning tree types
  • Spanning tree tuning techniques

3. Describe mechanisms that are available for creating loop-free topologies

  • REP
  • Multipath
  • Switch clustering
  • Flex links
  • Loop detection and mitigation

4. Describe the effect of transport mechanisms and their interaction with routing protocols over different types of links

5. Describe multicast routing concepts

6. Describe the effect of fault isolation and resiliency on network design

  • Fault isolation
  • Fate sharing
  • Redundancy
  • Virtualization
  • Segmentation
Layer 3 Control Plane 33%

1. Describe route aggregation concepts and techniques

  • Purpose of route aggregation
  • When to leak routes / avoid suboptimal routing
  • Determine aggregation location and techniques

2. Describe the theory and application of network topology layering

  • Layers and their purposes in various environments

3. Describe the theory and application of network topology abstraction

  • Purpose of link state topology summarization
  • Use of link state topology summarization

4. Describe the effect of fault isolation and resiliency on network design or network reliability

  • Fault isolation
  • Fate sharing
  • Redundancy

5. Describe metric-based traffic flow and modification

  • Metrics to modify traffic flow
  • Third-party next hop

6. Describe fast convergence techniques and mechanisms

  • Protocol timers
  • Loop-free alternates

7. Describe factors affecting convergence

  • Recursion
  • Microloops
  • Transport

8. Describe unicast routing protocol operation [OSPF, EIGRP, ISIS, BGP, and RIP] in relation to network design

  • Neighbor relationships
  • Loop-free paths
  • Flooding domains and stubs
  • iBGP scalability

9. Analyze operational costs and complexity

  • Routing policy
  • Redistribution methods

10. Describe the interaction between routing protocols and topologies

11. Describe generic routing and addressing concepts

  • Policy-based routing
  • NAT
  • Subnetting
  • RIB-FIB relationships

12. Describe multicast routing concepts

  • General multicast concepts
  • Source specific
  • MSDP/anycast
  • PIM
  • mVPN

13. Describe IPv6 concepts and operation

  • General IPv6 concepts
  • IPv6 security
  • IPv6 transition techniques
Network Virtualization 15%

1. Describe Layer 2 and Layer 3 tunnelling technologies

  • Tunnelling for security
  • Tunnelling for network extension
  • Tunnelling for resiliency
  • Tunnelling for protocol integration
  • Tunnelling for traffic optimization

2. Analyze the implementation of tunnelling

  • Tunnelling technology selection
  • Tunnelling endpoint selection
  • Tunnelling parameter optimization of end-user applications
  • Effects of tunnelling on routing
  • Routing protocol selection and tuning for tunnels
Design Considerations 18%

1. Analyze various QoS performance metrics

  • Application requirements
  • Performance metrics

2. Describe types of QoS techniques

  • Classification and marking
  • Shaping
  • Policing
  • Queuing

3. Identify QoS strategies based on customer requirements

  • DiffServ
  • IntServ

4. Identify network management requirements

5. Identify network application reporting requirements

6. Describe technologies, tools, and protocols that are used for network management

7. Describe the reference models and processes that are used in network management, such as FCAPS, ITIL®, and TOGAF

8. Describe best practices for protecting network infrastructure

  • Secure administrative access
  • Control plane protection

9. Describe best practices for protecting network services

  • Deep packet inspection
  • Data plane protection

10. Describe tools and technologies for identity management

11. Describe tools and technologies for IEEE 802.11 wireless deployment

12. Describe tools and technologies for optical deployment

13. Describe tools and technologies for SAN fabric deployment
Evolving Techonologies v1.1 10%

1. Cloud

  • Compare and contrast public, private, hybrid, and multicloud design considerations
    - Infrastructure, platform, and software as a service (XaaS)
    - Performance, scalability, and high availability
    - Security implications, compliance, and policy
    - Workload migration
  • Describe cloud infrastructure and operations
    - Compute virtualization (containers and virtual machines)
    - Connectivity (virtual switches, SD-WAN and SD-Access
    - Virtualization functions (NFVi, VNF, and L4/L6
    - Automation and orchestration tools (CloudCenter, Cisco DNA-center, and Kubernetes)

2. Network programmability (SDN)

  • Describe architectural and operational considerations for a programmable network
    - Data models and structures (YANG, JSON and XML
    - Controller based network design (policy driven configuration and northbound/ southbound APIs
    - Configuration management tools (agent and agentless) and version control systems (Git and SVN
    - Device programmability (gRPC, NETCONF and RESTCONF)

3. Internet of things (IoT)

  • Describe architectural framework and deployment considerations for IoT
    - IoT technology stack (IoT Network Hierarchy, data acquisition and flow)
    - IoT standards and protocols (characteristics within IT and OT environment)
    - IoT security (network segmentation, device profiling, and secure remote)

Cisco CCDE Exam Description:

Cisco CCDE® Written Exam tests a candidate's combined knowledge of routing protocols, internetworking theory and design principles. It assesses a candidate's understanding of network design in the areas of routing, tunneling, Quality of Service, Management, Cost, Capacity, and Security. This exam combines in-depth technical concepts with Network Design principles. Product-specific knowledge including version of code, implementation and operations specific concepts are not tested on the CCDE exam. The exam is closed book and no outside reference materials are allowed.

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