AREN Networking in the K-12 Community Rick Bagwell Nichols Research A labama R esearch and E ducation N etwork (Formerly the Alabama Supercomputer Network)
AREN Ethernet –Shared, Switched, Fast, Gigabit Token Ring FDDI (Fiber Distributed Data Interface) ATM (Asynchronous Transfer Mode) Local Area Network Options (LAN)
AREN Ethernet Types Ethernet –10Base-T (100m, Unshielded Twisted Pair = UTP) –10Base-2 (~200m, Coax) –10Base-5 (500m, Coax) –10Base-FL (2000m=2km, Multimode Fiber) Fast Ethernet –100Base-TX (100m over CAT5 UTP) –100Base-FX (2000m=2km over MM Fiber) Gigabit Ethernet –1000Base-SX (300m over MM Fiber) –1000Base-LX (550m over MM Fiber, 3000m over SM Fiber)
AREN Ethernet 10 Mbps CSMA/CD –Carrier Sense Multiple Access with Collision Detection Can be configured with cable, hubs, or switches
AREN Common Ethernet Topologies (non-segmented)
AREN Limitations of Cascaded Hub Topology Distance limitations of UTP or Fiber Network size limited by the rule –just remember hosts cannot talk to each other if they are connected through more than 4 hubs or repeaters One Broadcast Domain –collisions likely as number of hosts increases Users generally don’t know about the rule and just keep on adding hubs at random points
AREN Limitations of Stacked Hub Topology All hosts must be within 100m of the stack when using UTP Using fiber to overcome distance limitations is useful for MDF to IDF connections but is cost prohibitive to the desktop “Stackables” use proprietary interconnects One broadcast domain
AREN Limitations of 10Base-2 and 10Base-5 Difficult to troubleshoot –Terminations, Terminations, Terminations rule must be strictly enforced Cable infrastructure does not support upgrades to Fast or Gigabit Ethernet. Difficult to troubleshoot –Terminations, Terminations, Terminations
AREN Ethernet: The Next Generation Layer 2 switches (Ethernet, FastE, GigE) –Switching decisions are made based on MAC address –Segments network into separate traffic domains –Broadcasts are still heard by all hosts –Does not affect IP subnetting
AREN Ethernet: The Next Generation (cont.) Layer 3 switches (Ethernet, FastE, GigE) –Switching decisions are made based on MAC and IP addresses –High-speed ASIC-based routing –Can usually be configured as Layer2/Layer3 switches on a per-port basis –Layer 3 switching takes place between subnets
AREN Ethernet: The Next Generation (cont. again) Layer 4 “switches” (Ethernet, FastE, GigE) –Switching decisions are based on Application, MAC and IP addresses –Can usually be configured as Layer2/3/4 switches on a per-port basis –Layer 3 switching takes place between subnets –Layer 4 “switching” is used to provide QoS and multimedia services
AREN Ethernet Network Design Pointers Use Ethernet switching as much as possible –Limit the number of hosts sharing a switched port –Switched to the desktop is nice but expensive Use Layer 3 switching (routing) for large (>200 hosts) networks and high-performance. Use Fiber between MDF and IDFs when distance exceeds 100m (300ft to be conservative) Do NOT use Fiber to the desktop unless you are made of money
AREN How do I connect my schools to each other and to the Internet? The same general answer applies for almost every choice of WAN connection technology. –Routers at each school are connected via some WAN technology to the other routers in the school system –Schools are on different IP subnets Internet access –Usually obtained for the school system by connecting a single location to the Internet with a high-speed connection. –Other schools in the system can access the Internet by routing through the central location. –Can be purchased on a school by school basis This option can be MUCH more expensive and likely gains little, if anything, in the way of performance.
AREN Typical School System Network
AREN Wide Area Network Options (WAN) –DS1 (a.k.a T1) –Fractional DS1 (Frac. T1) –Frame Relay –Cable Modem –ISDN –xDSL –Private/Leased Fiber (or copper) –Wireless
AREN What is a “T1” and how does it work ?? High speed “phone” line –digital –1.544Mbps (if all 24 channels are used) –24 “phone” lines Used by phone companies between COs Used by businesses between offices Used by Networking folks for Data
AREN Advantages and Disadvantages of T1 Lines for School System Networking Advantages: –Reasonable WAN speed (1.5Mbps) –An educational tariff is available for T1s in Alabama. –Full T1’s are almost always less expensive than Frame Relay (due to the edu. Tariff) –Telco is responsible for insuring that the line stays operational Disadvantages: –Bandwidth is limited (1.5Mbps) –Requires more router ports at central site than Frame Relay but large systems can use Channelized DS3
AREN What is Frame Relay and how does it work ?? Circuit switched network technology You purchase access to the “cloud” –usually a T1 or fractional T1 Virtual connections are made across the cloud to connect schools (PVCs) A Committed Information Rate (CIR) can be purchased that guarantees a level of performance
AREN Frame Relay Example
AREN Advantages and Disadvantages of Frame Relay for School System Networking Advantages: –Reasonable WAN speed (64kbps Mbps) When T1 or Fract. T1 is the transport –Buy bandwidth only when you need it **** –One serial port at the central site can support multiple incoming PVCs –Telco is responsible for insuring connectivity Disadvantages: –No educational tariff is currently available in Alabama. –Full T1’s are almost always less expensive than Frame Relay (due to the edu. Tariff) This is true even when low CIRs or no CIRs are compared to T1s
AREN Cable Modems and xDSL High-speed (256kbps -- 10Mbps) wide area connectivity that can be used to connect schools or for Internet access Usually only available in the larger cities (Huntsville, Birmingham, Montgomery, Mobile) Too early to recommend or dismiss as a technology for school system use –Both Cable Modem systems and xDSL can and often are over- subscribed –Some sort of service level agreement should be obtained before either of these technologies are considered
AREN ISDN (Integrated Services Digital Network) Designed to be a digital phone service –BRI: 2B+D (Basic Rate Interface) –PRI: 23B+D (Primary Rate Interface) Telco’s frown on “nailing up” ISDN connections Limited bandwidth (64-128kbps for BRI) Good solution for “dial backup” –if you can afford dial backup
AREN Private or Leased Fiber Optic Lines My personal favorite Extremely high bandwidth available (1Gbps is easily obtained) Can economically use Fast Ethernet over such and infrastructure (100Mbps) No recurring costs (T1 min. is $ per month) Must either obtain right-of-way or have existing fiber donated by telco or power company
AREN Wireless WAN/MAN Good solution in Flat areas or when a mountain is nearby –line of sight is required !!! High Bandwidth solutions are available (2Mbps--155Mbps) 10Mbps is now very economical No recurring cost (unless leased) Leasing provides insurance against malfunction or the weather My second choice if fiber is unavailable
AREN Unconventional Wisdom (at least some people would say so) Never use managed Ethernet hubs –most of the functionality is never used –much more expensive than “dumb” hubs –exception to this rule: VLANs on hubs The only use for Fiber Optics is between IDFs and the MDF when the distance is over 300ft Almost never buy Frame Relay for connecting schools in a single system to each other (Educational T1s are cheaper). Always compare all WAN options (T1, Frame, Fiber, Wireless, etc.) Use network appliances and/or LINUX systems for Internet servers. Having a trained Network Manager makes ALL the difference –Don’t have to rely completely on vendors and contractors Get network advice from someone other than the vendor before purchasing
AREN Contact Information Rick Bagwell Network Engineer Nichols Research Corporation (Contractor for AREN) Voice: (256) FAX:(256) or-