Blueprint

The following tables is the CCIE R&S Blueprint, it is a combination of DOC-4375 and DOC-6864.

DOC- 4375		DOC- 6864	Correlated Topics from DOC-4375 and DOC-6864 (same on both shown in purple)
1		1	Implement Layer 2 Technologies
		1.2	Catalyst Configuration
		1.2.24.	SNMP Management on the Switch
		1.2.25.	Telnet and SSH Management on the Switch
		1.2.26.	Controlling Inbound and Outbound Telnet on the Switch
		1.2.27.	Regular and Smart Macros
		1.2.28.	Switch Banners
		1.2.29.	UDLD
		1.2.30.	Switch Virtual Interfaces (SVIs) for IP Routing
		1.2.31.	Router on a Stick
		1.2.34.	IP Routing on the Switch Using RIPv2, EIGRP, OSPF, and BGP
		1.2.35.	IP Phones to Connect to the Catalyst Switch
		1.2.36.	Dot1q Tunneling
1.1			Implement Spanning Tree Protocol (STP)
	a		802.1d
		1.2.17.	Selecting the Root Bridge for VLANs in a PVST Environment
	b		802.1w
	c	1.2.16.	801.1s MSTP
		1.2.18.	Selecting the Root Bridge for an MST Instance in an MST Environment
		1.2.10.	PortFast
	d	1.2.11.	Loop guard
	e		Root guard
	f	1.2.12.	Bridge protocol data unit (BPDU) guard
		1.2.15.	BackboneFast
		1.2.09.	Optimizing STP by STP Timers
		1.2.13.	BPDU Filters
		1.2.14.	UplinkFast
	g	6.4.1.	Storm control
	h		Unicast flooding
	i		Port roles, failure propagation, and loop guard operation
		1.2.19.	Setting the Port Priority to Designate the Forwarding Ports
1.2			Implement VLAN and VLAN Trunking Protocol (VTP)
		1.2.03.	Creating, Deleting, and Editing VLANs
		1.2.04.	VTP in Client/Server Mode
		1.2.05.	VTP in Transparent Mode
		1.2.06.	VTP Authentication
		1.2.07.	VTP Pruning
1.3			Implement trunk and trunk protocols, EtherChannel, and load-balance
		1.2.01.	Trunks Using an Industry-Standard Encapsulation
		1.2.02.	Trunks Using a Cisco Proprietary Encapsulation
		1.2.08.	Controlling VLANs That Cross a Trunk
		1.2.20.	EtherChannel Using an Industry-Standard Protocol
		1.2.21.	EtherChannel Using a Cisco Proprietary Protocol
		1.2.22.	Disabling Protocols on the EtherChannel
		1.2.23.	Load-Balancing Type on the EtherChannel
1.4			Implement Ethernet technologies
	a		Speed and duplex
	b		Ethernet, Fast Ethernet, and Gigabit Ethernet
	c		PPP over Ethernet (PPPoE)
1.5			Implement Switched Port Analyzer (SPAN), Remote Switched Port Analyzer (RSPAN), and flow control
		1.2.32.	SPAN
		1.2.33.	RSPAN
1.6		1.01	Implement Frame Relay
		1.01.1	Frame Relay Multipoint Links on a Physical Interface Using Inverse ARP
		1.01.2	Frame Relay Multipoint Links on a Physical Interface Without Using Inverse ARP
		1.01.3.	Frame Relay Multipoint Link on a Subinterface Using Inverse ARP
		1.01.4.	Frame Relay Multipoint Link on a Subinterface Without Using Inverse ARP
		1.01.5.	Frame Relay Point-to-Point Subinterfaces
		1.01.6.	PVC with a Multipoint Interface on One Side and a Subinterface on the Other Side
		1.01.7.	Authentication on a Frame Relay Link Using PPP
	a		Local Management Interface (LMI)
	b		Traffic shaping
	c		Full mesh
	d		Hub and spoke
	e		Discard eligible (DE)
		1.3	Other Layer 2 Technologies
1.7			Implement High-Level Data Link Control (HDLC) and PPP
		1.3.1.	HDLC
		1.3.2.	PPP
		1.3.3.	PPP over Ethernet

2		2	Implement IPv4
2.1			Implement IP version 4 (IPv4) addressing, subnetting, and variable-length subnet masking (VLSM)
		2.1.	IPv4 Addressing
		2.1.1.	IPv4 Addressing
		2.1.2.	IPv4 Subnetting
		2.1.3.	IPv4 VLSM
2.2			Implement IPv4 tunneling and Generic Routing Encapsulation (GRE)
2.3			Implement IPv4 RIP version 2 (RIPv2)
2.4		2.2.	Implement IPv4 Open Shortest Path First (OSPF) OSPFv2
	a		Standard OSPF areas
	b	2.2.06.	Stub area
	c	2.2.07.	Totally stubby area
	d	2.2.08.	Not-so-stubby-area (NSSA)
		2.2.09.	NSSA and Stub Areas
	e		Totally NSSA
		2.2.10.	NSSA and Totally Stubby Areas
	f		Link-state advertisement (LSA) types
	g		Adjacency on a point-to-point and on a multi-access network
		2.2.01.	OSPF on a Broadcast Multicast Access Network (Ethernet)
		2.2.02.	OSPF over a Frame Relay Multipoint Network by Changing Network Types
		2.2.03.	OSPF over a Frame Relay Multipoint Network by Using the neighbor Command
		2.2.04.	OSPF over a Frame Relay Point-to-Point Network
		2.2.05.	Virtual Links
	h		OSPF graceful restart
2.5		2.3.	Implement IPv4 Enhanced Interior Gateway Routing Protocol (EIGRP)
		2.3.1.	Basic EIGRP
	a		Best path
	b		Loop-free paths
	c		EIGRP operations when alternate loop-free paths are available, and when they are not available
	d		EIGRP queries
	e		Manual summarization and autosummarization
	f		EIGRP stubs
		2.3.3.	EIGRP Stub on Routers and Switches
		2.3.2.	Passive Interfaces
		2.3.4.	EIGRP Update—Bandwidth Control
		2.3.5.	Changing the Administrative Distance of EIGRP
		2.3.6.	Unequal-Cost Load Balancing for EIGRP
2.6			Implement IPv4 Border Gateway Protocol (BGP)
	a		Next hop
		2.5.	IBGP
		2.5.3.	Next-Hop Attribute
	b		Peering
		2.5.1.	IBGP Peering
		2.6.1.	EBGP Peering
		2.6.2.	EBGP Peering Based on Loopbacks
	c		Internal Border Gateway Protocol (IBGP) and External Border Gateway Protocol (EBGP)
		2.5.2.	Advertising Routes in BGP
		2.5.4.	Route Reflectors
		2.5.5.	Redundancy by Neighbor Relationships Based on Loopbacks
		2.6.	EBGP
		2.7.	BGP Advanced Features
		2.7.01.	Filtering Using ACLs
		2.7.02.	Filtering Using Prefix Lists
		2.7.03.	Filtering Using AS Path Filters
		2.7.04.	Redistributing Connected Routes into BGP
		2.7.05.	Redistributing Dynamic Routing Protocols into BGP
		2.7.06.	BGP Aggregation
		2.7.07.	BGP Aggregation with the Summary Only Parameter
		2.7.08.	BGP Aggregation with Suppress Maps
		2.7.09.	BGP Aggregation with Unsuppress Maps
		2.7.10.	BGP Best-Path Selection – Weight
		2.7.11.	BGP Best-Path Selection – Local Preference
		2.7.12.	BGP Best-Path Selection – MED
		2.7.13.	BGP Communities – No-Export
		2.7.14.	BGP Communities – No-Advertise
		2.7.15.	BGP Confederation
		2.7.16.	BGP Local AS
		2.7.17.	Working with Private AS Numbers
		2.7.18.	Route Dampening
		2.7.19.	Conditional Advertising
		2.7.20.	Peer Groups
2.7			Implement policy routing
2.8		2.8	Implement Performance Routing (PfR) and Cisco Optimized Edge Routing (OER)
2.9			Implement filtering, route redistribution, summarization, synchronization, attributes, and other advanced features
		2.4.	Filtering, Redistribution, and Summarization
		2.4.01.	Route Filtering for OSPF Within the Area Using a Distribute List with an ACL and Prefix Lists
		2.4.02.	Route Filtering for OSPF Between Areas
		2.4.03.	Summarization of OSPF Routes Between Areas
		2.4.04.	Summarization of External Routers Within OSPF
		2.4.05.	Filtering with a Distribute List Using an ACL and Prefix Lists
		2.4.06.	Using Advanced ACLs and a Prefix List for Filtering Routes
		2.4.07.	Summarizing Routes with EIGRP
		2.4.08.	Route Summarization for RIP
		2.4.09.	Redistribution Between OSPF and EIGRP
		2.4.10.	Redistribution Between RIP and EIGRP
		2.4.11.	Redistribution Between RIP and OSPF
		2.4.12.	Redistribution of Directly Connected Routes
		2.4.13.	Redistribution of Static Routes
		2.4.14.	Redistribution with Filtering Using ACLs and Prefix Lists
		2.4.15	Redistribution with Filtering Using Route Tagging

3		3	Implement IPv6
		3.1.	IPv6
3.1		3.1.1.	Implement IP version 6 (IPv6) addressing and different addressing types
3.2			Implement IPv6 neighbor discovery
3.3			Implement basic IPv6 functionality protocols
		3.1.2	RIPng
3.4		3.1.4.	Implement tunneling techniques IPv6 Tunneling
3.5		3.1.2.	Implement OSPF version 3 (OSPFv3)
3.6		3.1.3.	Implement EIGRP version 6 (EIGRPv6)
		3.1.5.	IPv6 on a Frame Relay Network – Multipoint
		3.1.6.	IPv6 on a Frame Relay Network – Point-to-Point
3.7			Implement filtering and route redistribution
		3.1.7.	Route Filtering with a Distribute List Using an ACL and Prefix Lists
		3.1.8.	Route Redistribution Between OSPFv3 and EIGRPv6

4			Implement MPLS Layer 3 VPNs
4.1		4	Implement Multiprotocol Label Switching
		4.1.	MPLS Unicast Routing
		4.1.1.	MPLS Unicast Routing Using LDP
		4.1.2.	Controlling Label Distribution
4.2			Implement Layer 3 virtual private networks (VPNs) on provider edge (PE), provider (P), and customer edge (CE) routers
		4.2.	MPLS VPN
		4.2.1.	MPLS VPN Using Static Routing Between PE-CE
		4.2.2.	MPLS VPN Using EIGRP as the PE-CE Routing Protocol
		4.2.3.	MPLS VPN Using OSPF as the PE-CE Routing Protocol
		4.2.4.	MPLS VPN Using EBGP as the PE-CE Routing Protocol
4.3			Implement virtual routing and forwarding (VRF) and Multi-VRF Customer Edge (VRF-Lite)
		4.2.5.	Controlling Route Propagation Using the Route Target with Import and Export Maps
		4.3.	VRF-Lite
		4.3.1.	VRFs at the Customer Sites Using VRF-Lite

5		5	Implement IP Multicast
5.1			Implement Protocol Independent Multicast (PIM) sparse mode
		5.1.3.	PIM Sparse Mode – Static Rendezvous Point
		5.1.4.	PIM Sparse Mode – Multiple Static Rendezvous Points
		5.1.5.	PIM Sparse Mode – Auto Rendezvous Point
		5.1.6.	PIM Sparse Mode with Multiple Rendezvous Points Using the Auto Rendezvous Point
		5.1.	PIM and Bidirectional PIM
		5.1.1.	PIM Dense Mode
		5.1.2.	PIM on an NMBA Network
		5.1.7.	Bidirectional PIM
5.2		5.2.	Implement Multicast Source Discovery Protocol (MSDP)
		5.2.1.	MSDP
		5.2.2.	MSDP to an Anycast Rendezvous Point
5.3			Implement interdomain multicast routing
5.4			Implement PIM Auto-Rendezvous Point (Auto-RP), unicast rendezvous point (RP), and bootstrap router (BSR)
5.5			Implement multicast tools, features, and source-specific multicast
		5.3.	Multicast Tools
		5.3.1.	Multicast Rate Limiting
		5.3.2.	IGMP Filtering on the Switch
		5.3.3.	Use of the Switch to Block Multicast Traffic
		5.3.4.	Multicasting Through a GRE Tunnel
		5.3.5.	Multicast Helper Address
5.6			Implement IPv6 multicast, PIM, and related multicast protocols, such as Multicast Listener Discovery (MLD)
		5.4.	IPv6 Multicast
		5.4.1.	IPv6 Multicast Routing Using PIM
		5.4.2.	IPv6 Multicast Listener Discovery (MLD) Protocol

6			Implement Network Security
6.01		6.2.	Implement access lists
		6.2.1.	Standard Access Lists
		6.2.2.	Extended Access Lists
		6.2.3.	Time-Based Access Lists
		6.2.4.	Reflexive Access Lists
6.02			Implement Zone Based Firewall
		6.5.3.	Basic Zone-Based Firewall
		6.5.4.	Zone-Based Firewall with Deep Packet Inspection
6.03			Implement Unicast Reverse Path Forwarding (uRPF)
6.04		6.4.8.	Implement IP Source Guard
6.05			Implement authentication, authorization, and accounting (AAA) (configuring the AAA server is not required, only the client-side (IOS) is configured)
		6.1.	AAA and Security Server Protocols
		6.1.1.	Use of a Router to Authenticate Against a AAA Server Using TACACS+
		6.1.2.	Use of a Router to Authenticate Against a AAA Server Using RADIUS
		6.1.3.	Local Privilege Authorization
		6.1.4.	Accounting to a AAA Server Using TACACS+
		6.1.5.	Accounting to a AAA Server Using RADIUS
6.06			Implement Control Plane Policing (CoPP)
6.07			Implement Cisco IOS Firewall
		6.5.	Cisco IOS and Zone-Based Firewalls
		6.5.1.	Basic Cisco IOS Firewall
		6.5.2.	DoS Protection on a Cisco IOS Firewall
6.08		6.7.7.	Implement Cisco IOS Intrusion Prevention System (IPS)
6.09			Implement Secure Shell (SSH)
		6.7.6.	SSH on Routers and Switches
		6.7.8.	Controlling Telnet and SSH Access to the Router and Switch
		6.4.	Catalyst Security
		6.4.2.	Switch Port Security
6.1			Implement 802.1x
		6.4.3.	Dot1x Authentication
		6.4.4.	Dot1x Authentication for VLAN Assignment
		6.4.5.	VLAN Access Maps
		6.4.6.	DHCP Snooping
		6.4.7.	DAI
		6.4.9.	Private VLANs
6.11		6.6.	Implement NAT
		6.6.1.	Dynamic NAT
		6.6.2.	PAT
		6.6.3.	Static NAT
		6.6.4.	Static PAT
		6.6.5.	Policy-Based NAT
6.12			Implement routing protocol authentication
		6.3.	Routing Protocol Security
		6.3.1.	Routing Protocol Authentication for EIGRP
		6.3.2.	Routing Protocol Authentication for OSPF – Area-Wide
		6.3.3.	Routing Protocol Authentication for OSPF – Interface-Specific
		6.3.4.	Routing Protocol Authentication for OSPF Virtual Links
		6.3.5.	Routing Protocol Authentication for BGP
6.13			Implement device access control
6.14		6.7.	Implement security features Other Security Features
		6.7.1.	Configuring the TCP Intercept Feature
		6.7.2.	Configuring Blocking of Fragment Attacks
		6.7.3.	Configuring Switch Security Features
		6.7.4.	Configuring Antispoofing Using an ACL
		6.7.5.	Configuring Antispoofing Using uRPF

7		7	Implement Network Services
7.1		7.2.	Implement Hot Standby Router Protocol (HSRP)
		7.2.1.	HSRP Between Two Routers
		7.2.2.	Pre-empt for HSRP
		7.2.3.	Authentication for HSRP
7.2		7.2.5.	Implement Gateway Load Balancing Protocol (GLBP)
7.3		7.2.4.	Implement Virtual Router Redundancy Protocol (VRRP)
7.4		7.5.	Implement Network Time Protocol (NTP)
		7.5.1.	NTP Using the NTP Master and NTP Server Commands
		7.5.2.	NTP Without Using the NTP Server
		7.5.3.	NTP Using NTP Broadcast Commands
7.5		7.1.	Implement DHCP
		7.1.1.	Configuring DHCP on a Cisco IOS Router
		7.1.2.	Configuring DHCP on a Switch
		7.1.3.	Using a Router and a Switch to Act as a DHCP Relay Agent (Helper Address)
7.6			Implement Web Cache Communication Protocol (WCCP)
		7.3.	IP Services
		7.3.1.	Use of the Router for WCCP
		7.3.2.	Use of the Router to Generate an Exception Dump Using TFTP
		7.3.3.	Use of the Router to Generate an Exception Dump Using FTP
		7.3.4.	Use of the Router to Generate an Exception Dump Using RCP
		7.3.5.	Broadcast Forwarding for Protocols
		7.4.	System Management
		7.4.1.	Telnet Management on the Router and Switch
		7.4.2.	SSH Management on the Router and Switch
		7.4.3.	Disabling Telnet and the SSH Client on the Switch
		7.4.4.	HTTP Management on the Router and Switch
		7.4.5.	Controlling HTTP Management on the Router and Switch

8		8	Implement Quality of Service (QoS)
		8.6.	Catalyst QoS
		8.6.1.	SRR on the Catalyst Switch
8.1		8.5.	Implement Modular QoS CLI (MQC)
	a		Network-Based Application Recognition (NBAR)
		8.5.7.	Using NBAR for QoS
	b		Class-based weighted fair queuing (CBWFQ), modified deficit round robin (MDRR), and low latency queuing (LLQ)
		8.2.	Congestion Management and Congestion Avoidance
		8.2.1.	Priority Queuing
		8.2.2.	Custom Queuing
		8.2.3.	Weighted Fair Queuing
		8.5.2.	Class-Based Weighted Fair Queuing (CB-WFQ)
		8.5.3.	Low Latency Queuing (LLQ)
	c	8.1.	Classification
	d	8.5.1.	Policing
	e		Shaping
		8.5.4.	Shaping Using MQC
	f		Marking
		8.1.1.	Marking Using DSCP
		8.1.2.	Marking Using IP Precedence
		8.1.3.	Marking Using CoS
	g	8.2.4.	Weighted random early detection (WRED) and random early detection (RED)
		8.5.5.	Random Early Detection Using MQC
		8.5.6.	WRED Using MQC
	h	8.4.1.	Compression
8.2			Implement Layer 2 QoS: weighted round robin (WRR), shaped round robin (SRR), and policies
8.3			Implement link fragmentation and interleaving (LFI) for Frame Relay
		8.4.	Link Efficiency Mechanisms
		8.4.2.	Link Fragmentation and Interleaving (LFI) for Frame Relay
8.4			Implement generic traffic shaping
		8.3.	Policing and Shaping
		8.3.1.	CAR Using Rate Limiting Under the Interface
		8.3.2.	Frame Relay Traffic Shaping Using Map Classes
		8.3.3.	Discard Eligible List
		8.5.8.	Discard Eligible Marking Using MQC
8.5		8.2.5.	Implement Resource Reservation Protocol (RSVP)
8.6			Implement Cisco AutoQoS

9		9	Troubleshoot a Network
9.1		9.1.	Troubleshoot complex Layer 2 network issues Troubleshooting Layer 2 Problems
		9.1.1.	Troubleshooting Catalyst Switch Network Issues
		9.1.2.	Troubleshooting Frame Relay Network Issues
9.2		9.2.	Troubleshoot complex Layer 3 network issues Troubleshooting Layer 3 Problems
		9.2.1.	Troubleshooting IP Addressing Network Issues
		9.2.2.	Troubleshooting Routing Protocol Network Issues
		9.2.3.	Troubleshooting Routing Protocol Loop Issues
9.3			Troubleshoot a network in response to application problems
		9.3.	Troubleshooting Application Problems
		9.3.1.	Determining Which Aspects of the Network to Troubleshoot to Determine Network Functionality (Given a Set of Symptoms)
9.4		9.4.	Troubleshoot network services
		9.4.1.	Troubleshooting Misconfigured NTP Setup
		9.4.2.	Troubleshooting Misconfigured DHCP Setup
		9.4.3.	Troubleshooting Misconfigured Telnet and SSH Setup
		9.4.4.	Troubleshooting Misconfigured SNMP Setup
9.5			Troubleshoot network security
		9.5.	Troubleshooting Security Services
		9.5.1.	Troubleshooting Misconfigured ACLs
		9.5.2.	Troubleshooting Misconfigured NAT
		9.5.3.	Troubleshooting Misconfigured AAA Services

10		10	Optimize the Network
10.01			Implement syslog and local logging
		10.1.	Logging
		10.1.1.	Logging to a Remote Syslog Server
		10.1.2.	Logging to the Internal Buffer
10.02			Implement IP Service Level Agreement SLA
		10.5.	SLA
		10.5.1.	IP SLA
10.03		10.6.4.	Implement NetFlow
10.04			Implement SPAN, RSPAN, and router IP traffic export (RITE)
		1.2.32	SPAN (1.5 of original blueprint)
		1.2.33	RSPAN (1.5 of original blueprint)
10.05		10.2.	Implement Simple Network Management Protocol (SNMP)
		10.2.1.	Use of a Router to Communicate to an SNMP Management Station
		10.2.2.	Use of a Router to Generate SNMP Traps
10.06		10.6.3.	Implement Cisco IOS Embedded Event Manager (EEM)
10.07		10.3.	Implement Remote Monitoring (RMON)
		10.3.1.	Use of a Router to Generate SNMP Traps Using RMON
		10.4.	Accounting
		10.4.1.	IP Accounting
		10.6.	Implementing Network Services on the Routers
10.08			Implement FTP
		10.6.1.	Use of a Router as an FTP Server
10.09			Implement TFTP
10.1		10.6.2.	Implement TFTP server on router
10.11		10.6.7.	Implement Secure Copy Protocol (SCP)
10.12			Implement HTTP and HTTPS
		10.6.5.	HTTP and HTTPS on a Router
10.13			Implement Telnet
		10.6.6.	Telnet on a Router