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Cabrillo College. CCNP Semester 5 Building Scalable Cisco Networks Rick Graziani, Instructor with Mark McGregor version 1. Scalable Networks. Scalability: Th e ability to grow and adapt without major redesign or reinstallation
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Cabrillo College CCNP Semester 5 Building Scalable Cisco Networks Rick Graziani, Instructor with Mark McGregor version 1
Scalable Networks • Scalability: The ability to grow and adapt without major redesign or reinstallation • More often than not, poor design prevents a network from scaling gracefully, not outdated protocols or underpowered devices.
Three-Layer Design Model • Conceptual only • There will be contradictions and some devices may be argued as one type of device or another.
Layered models can be difficult to comprehend. • Exact composition can vary from network to network. Sample 3-layer hierarchy
The Core Layer • Core Layer:provide an optimized and reliable transport structure by forwarding traffic at very high speeds. • Core routers switch packets – fast. • No ACLs, no redistribution, no fancy packet manipulation.
The Distribution Layer • Distribution Layer : provides boundary definition by using access-lists and other filters to limit what gets into the core. Thus, this layer defines policy for the network. • Distribution routers apply routing policies using ACLs, route maps, distribute lists and redistribution.
The Access Layer • Access Layer : feeds traffic into the network. End users access the network via the access layer. • Access Layer routers employ ACLs designed to prevent unauthorized users from gaining entry and give remote sites access to the network via Frame Relay, ISDN, or leased lines.
An access router 2600, 2500, 1700, and 1600 Series
A distribution router 3600, 4500, and 4000 series
A core router 12000, 7500, 7200, and 7000 series
Product Lines (know this!) • Core layer • 12000, 7500, 7200, 7000 • Distribution layer • 3600, 4500, 4000 • Access layer • 2600, 2500, 1700, 1600
Reliable and Available • 24x7 • Failures need to be isolated and recovery invisible to the user • Uses scalable routing protocols (OSPF, EIGRP) • Reachability: Uses complex metrics instead of hop count • Fast convergence time: How they update other routers with new information • Congestion control: Less traffic overhead, incremental updates and route summarization
Reliable and Available • Alternate paths • Core layer: redundancy • Remote sites with mission critical data: redundant links • Tunnels • Allow for non-IP layer-3 packets (IPX) to be encapsulated in IP packets • Allows for IP only policies and routing • Other functions as well • Dial Backup • ISDN, POTS
Reliable and Available • Load balancing (See Tech Note - McGregor) • Distribute traffic across multiple links to the same destination • Equal-cost-load-balancing: Same cost/metric • Unequal-cost-load-balancing: Different cost/metric • Per-packet load balancing (process-switching) • Router alternates paths on a per-packet basis • Allows for more proportional load balancing than per-destination load balancing • Requires more CPU processing • Per-destination load balancing (fast switching) • The first packet’s destination address is cached, so all packets destined for the same address will take the same path
Making the Network Responsive • Routers can prioritize traffic based on protocol information such as TCP port numbers. • Priority may be important on routers that maintain slow WAN connections. • First come, first served transmission may cause unacceptable responsiveness for delay-sensitive traffic as the router must empty its buffer of another user’s file upload of a long train of packets.
Making the Network Responsive • Cisco addresses priority and responsiveness through queuing, the process the router uses to schedule packets for transmission. (Sem 6) • Queuing: FIFO, Priority, Custom, WFQ • FIFO Queuing (First-In First-Out) - Sem 6 • Prioritizes packets in the order which they arrived • Fastest of the four methods • Cisco default on all interfaces faster than E1 (2.048 Mbps)
Making the Network Responsive • Priority Queuing - Sem 6 • Highest priority traffic gets dispatched before any other packets • Assign traffic to one of four output queues: high, medium, normal, or low • Router will check high queue first. When high queue is empty, the router checks medium queue, etc. • Disadvantage: A lower priority queue may never get serviced or with an acceptable time frame if a higher priority queue is always being serviced
Making the Network Responsive • Custom Queuing - Sem 6 • Allows for up to 16 queues • Solves problem of Priority Queuing • Administrator reserves a minimum amount of bandwidth for each queue • Higher priority traffic can be put in a queue that receives more bandwidth • Each queue is serviced sequentially until the number of bytes transmitted exceeds the configured bandwidth for that queue
Making the Network Responsive • WFQ (Weighted Fair Queuing) - Sem 6 • Priority and Custom Queuing required administrator to predefine priorities and configure access lists • WFQ uses a complex algorithm to automatically allocate bandwidth to all types of network traffic, but prioritizes delay-sensitive packets so that high-volume conversations don’t consume all the available bandwidth. • WFQ breaks up large trains of packets so that low-volume conversations don’t get overrun by large file transfers of any other heavy traffic. • Cisco default on all interfaces E1 (2.048 Mbps) and slower.
Making the Network Efficient • Access Lists - Sem 5 • Snapshot Routing - Sem 6 • Compression - Sem 6 • Dial-on-Demand Routing - Sem 6 • Route Summarization - Sem 5 • Incremental Updates - Sem 5
Making the Network Efficient • Access Lists - Sem 5 • Prevents (permit or deny) unnecessary, undesirable or unauthorized traffic • Snapshot Routing - Sem 6 • Cisco IOS feature that allows distance-vector routers to exchange their complete tables during initial connection, and then only during active periods. • Router takes snapshot of table during quiet periods (dialup link is down) and then exchange tables only during active periods (dialup link is up) when interesting traffic brings up the link.
Making the Network Efficient • Dial-on-Demand Routing (DDR) - Sem 6 • Router waits for interesting traffic before activating the link, commonly used with ISDN. • Route Summarization - Sem 5 • Route aggregation or route summarization • Number of entries in the routing table can be reduced if the router uses one network address and mask to represent multiple networks or subnetworks. • Incremental Updates - Sem 5 • Routing protocols (OSPF, EIGRP) send routing updates that contain information only about routes that have been changed and only when there is a change.
Making the Network Adaptable • Coexistence of multiple routed (IP, IPX) and routing protocols (RIP, OSPF). • Route Redistribution • Allows routing information to be shared (redistributed) among two or more different routing protocols. • Ex: RIP routes into OSFP area
Making the Network Accessible but Secure • Allows users to connect easily over a wide variety of technologies, if necessary. • Dialup and Dedicated Access - Sem 6 • T1/E1, PSTN, ISDN, etc. • Switched Access - Sem 6 • Frame Relay, X.25, ATM, etc. • Secure • PAP, CHAP, TACACS+, RADIUS, etc.
IP Addressing: VLSM, CIDR Routing Overview OSPF: Single Area and Multiarea EIGRP Route Optimization BGP “Security” Labs! Coming up!