Title: CCNA Guide to Cisco Networking
1CCNA Guide to Cisco Networking
2Objectives
- Describe WAN standards
- Explain the WAN connection methods
- Discuss WAN data link protocols
- Understand the WAN Physical layer
- Recognize the various WAN physical topologies
- Emerging WAN connection methods
3WAN Standardization
- Organizations that create standards
- International Organization for Standards (ISO)
- American National Standards Institute (ANSI)
- Electronic Industries Alliance (EIA)
- Internet Engineering Task Force (IETF)
- International Telecommunications
Union-telecommunication (ITU-T)
4WAN Connection Methods
- Four connection methods
- Dedicated point-to-point
- Also known as a leased line
- Point-to-multipoint
- Time division multiplexing
- Circuit-switched
- Packet-switched
- Standards organizations define several types of
Data Link protocols used on WAN connections
5WAN Connection Methods (continued)
6WAN Connection Methods (continued)
7WAN Connection Methods (continued)
8WAN Data Link Protocols
- Three categories of Data Link protocols used for
WAN - Interface to IBM enterprise data centers
- Synchronous Data Link Control (SDLC)
- WAN connections using peer devices
- High-level Data Link Control (HDLC)
- Point-to-Point Protocol (PPP)
- Switched or relay services
- X.25/Link Access Procedure Balanced (LAPB)
- Frame Relay
9WAN Data Link Protocols (continued)
- Three categories of Data Link protocols used for
WAN (continued) - Switched or relay services (continued)
- Integrated Services Digital Network (ISDN)/Link
Access Procedure D-channel (LAPD) - Asynchronous Transfer Mode (ATM)
10WAN Data Link Protocols (continued)
- SDLC
- IBM hosts system communication over WAN links
- Point-to-point
- Point-to-multipoint
- Connections between
- Remote devices
- Central mainframe
- Synchronous communication
11WAN Data Link Protocols (continued)
- HDLC
- Default protocol on WAN links
- Also known as Advanced Data Communications
Control Procedure (ADCCP) - Superset of the SDLC protocol
- Point-to-point
- Point-to-multipoint
- Supports full-duplex and half-duplex
12WAN Data Link Protocols (continued)
- HDLC (continued)
- Synchronous and asynchronous
- Default HDLC does not support multiple protocols
- Cisco HDLC allows for multiple protocols
13WAN Data Link Protocols (continued)
- PPP
- SLIP
- Further extends default HDLC by providing a
protocol field - Dial-up
- Leased lines
- Network Control Protocols (NPCs)
- Can transfer IP, IPX, AppleTalk and other network
layer protocols
14WAN Data Link Protocols (continued)
- PPP (continued)
- PPP provides the following connections
- Router-to-router
- Host-to-router
- Host-to-host
- Physical interfaces for PPP
- Asynchronous serial
- ISDN/synchronous serial
- High-speed Serial Interface (HSSI)
15WAN Data Link Protocols (continued)
16WAN Data Link Protocols (continued)
- X.25/LAPD
- Packet-switching
- Widely implemented for international
communications - Connections over virtual circuits
- Create to function over existing unreliable
analog telecommunication lines - Errors correction and flow control
- Older than OSI, does not directly translate
17WAN Data Link Protocols (continued)
18WAN Data Link Protocols (continued)
- Frame Relay
- A Data Link protocol
- A service
- Improved upon X.25 standard
- Operates between 56 Kbps and 45 Mbps
- Higher layer protocols provide error checking and
flow control - Packet-switching
- Shared bandwidth with other frame relay
subscribers
19WAN Data Link Protocols (continued)
- Frame Relay (continued)
- Defines the connection between
- Customer premise equipment (CPE)
- Service providers local access switching
equipment - Operates on almost any Physical layer interface
- Two types of virtual circuits
- Switched virtual circuits (SVC)
- Permanent virtual circuits (PVC)
- Uses statistical multiplexing to allocate
bandwidth
20WAN Data Link Protocols (continued)
- Frame Relay (continued)
- Congestion control
- Forward explicit congestion notification (FECN)
- Backward explicit congestion notification (BECN)
- Configuration considerations
- Local access rate
- Committed information rate (CIR)
- Committed burst size (CBS)
- Excess burst size (EBS)
21WAN Data Link Protocols (continued)
- Frame Relay (continued)
- Configuration considerations (continued)
- Data link connection identifier (DLCI)
- Local Management interface (LMI)
- Discard eligible (DE)
22WAN Data Link Protocols (continued)
- ISDN/LAPD
- Circuit-switched technology
- Dedicated circuit for the length of the
transmission - Two types of ISDN
- Basic rate interface (BRI)
- Primary rate interface (PRI)
- Bandwidth
- BRI 128 kbps
- PRI 1.544 mbps
23WAN Data Link Protocols (continued)
- ISDN/LAPD (continued)
- B-channels (bearer channels)
- 64-kbps
- D-channel (delta or data channel)
- BRI 16 kbps
- PRI 64 kbps
- BRI
- Two B channels
- One D channel
- PRI
- 23 B channels
- One D channel
24WAN Data Link Protocols (continued)
- ATM
- Used within and between LAN connections
- Based on Frame Relay technology
- Cell-switched technology
- Circuit-oriented in the sense that ATM cells
follow the same path for the duration of the
connection - Cell are fixed length of 53 bytes
25WAN Data Link Protocols (continued)
- ATM (continued)
- Provides high-speed data transmission
- No error correction like X.25
- Bandwidth up to 10 gbps
26WAN Physical Layer
27WAN Connections
- Provide connections between two LANs
- Connections between
- Channels service unit/ data service unit CSU/DSU
- Router
- Routers now include internal CSU/DSU
- Data terminal equipment (DTE)
- Data-circuit terminating equipment (DCE)
28WAN Connections (continued)
- Demarcation or demarc
- Point of presence (POP)
- Local loop or last mile
- Central office switch (CO)
- Toll network
29WAN Physical Standards
- Physical WAN serial interface standards
- EIA/TIA-232
- EIA/TIA-449
- EIA-530
- High-Speed Serial Interface (HSSI)
- V.24
- V.35
- X.25
30WAN Physical Standards (continued)
- Physical WAN serial interface standards
(continued) - X.21
- G.703
31WAN Topologies
- WAN topologies
- Peer
- Star
- Partial mesh
- Mesh
32WAN Topologies (continued)
33WAN Topologies (continued)
- Peer topology
- Daisy-chained
- Simplest WAN topology
- Least expensive
- Easy to configure
- No redundancy
34WAN Topologies (continued)
- Star topology
- Most implemented design
- Also know as the hub-and-spoke topology
- Simple hierarchical design
- One central router acting as the hub
- Several edge routers connect to hub
35WAN Topologies (continued)
- Full mesh
- Most expensive topology
- Most fault-tolerant design
- Each router has a connection to every other
router - Partial mesh
- Compromise between star and full mesh
- Connection are made according to need and traffic
flow
36Emerging WAN Connection Methods
- Broadband access
- Two new WAN connection methods
- Digital subscriber lines (DSL)
- Cable access with cable modem
- DSL
- Two types of DSL
- Asynchronous DSL
- Symmetric DSL
37Emerging WAN Connection Methods (continued)
- DSL (continued)
- Modulates voice and data over existing copper
phone lines - Download speeds vary
- 256 kbps to faster than T1 (1.544 mbps)
- Upload speeds are typically slower than download
speeds - Speed and cost are attractive
- Distance limitations to CO
38Emerging WAN Connection Methods (continued)
- Cable access and cable modems
- Uses existing cable TV infrastructure
- Shared bandwidth
- Distance limitation not an issue like DSL
- Need VPN!
39Summary
- WANs connect LANs in geographically separate
areas - WAN connections typically function at the
Physical and Data Link layers of the OSI
reference model, and are made over serial
connections - WAN connections operate at a lower speed than LAN
connections, and can be made as point-to-point,
point-to-multipoint, and switched WAN connections - You can use several different data link protocols
for WAN connections
40Summary (continued)
- The different types of WAN connections are (1)
interfaces to IBM mainframes provided by SDLC
(2) WAN connections using peer devices with HDLC
and PPP and (3) switched or relayed services
including X.25, Frame Relay, ATM, and ISDN - X.25 is the oldest of the switched or relayed
services and provides the least efficient service
because of its excessive error checking - Frame Relay is an enhancement over X.25 because
it is faster and does not provide redundant error
checking
41Summary (continued)
- ATM is similar to Frame Relay, except that it
uses fixed-length cells instead of
variable-length packets - In addition, the ATM protocol can be used on LANs
as well as WANs - ISDN is a leased digital line that can support
X.25 and Frame Relay connections, among others - ISDN comes in PRI and BRI levels
42Summary (continued)
- BRI only provides 128-Kbps throughput over two
B-channels, and 16 Kbps over one D-channel that
is used for controlling the connection - PRI provides 23 B-channels of 64 Kbps each and
one 64-Kbps D-channel for controlling the
connection - This allows PRI to offer 1.544-Mbps throughput
- The Physical layer WAN connections concern the
interface between the DTE and DCE
43Summary (continued)
- The DTE is the endpoint of the users network,
which connects to the WAN interface - This is typically a router, computer, or terminal
of some type - The WAN service provider usually provides the
DCE, which is often a CSU/DSU, modem, or terminal
adapter - The DCE is then connected to a demarc, which is a
communications facility owned by the WAN service
provider - The local loop is the connection (usually copper
cable) that links the demarcation to the WAN
service providers CO switch, which is actually
part of the toll network or PSTN
44Summary (continued)
- The physical WAN topologies are
- Peer, which is simply customer facilities
connected in a daisy-chained fashion - Star, which involves connecting remote customer
facilities to a central facility - Full mesh, which connects every location to every
other location - Partial mesh, which provides redundancy only
where necessary