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Transcript
How To Build a Redundant, Fault Tolerant, Load Balanced, Traffic Managed Wireless network a bella mia company A Little Background Jeremy Kinsey or“Jer” to his friends. CEO and Co-Founder of Bella Mia, Inc. Been an ISP for 8 years Been a WISP for 4 years Part-15 WISP of the Year WISPCON III Part-15 Member Regular Speaker at WISPCON, WCA, P15. Located in South East Wisconsin So you are a Wireless ISP But how do you make your system Redundant? Some Assumptions • You have at least 2 WPOPS (Wireless Points of Presence) • You already have a redundant network, ie., are running BGP, have two providers, etc. • You have a good understanding of Cisco Routers and various routing protocols. Assuming you have all that, lets take a look at how things break down. Break down of Redundant WPOP Setup NOC Your Network Operations Center Connected to multiple Providers Running BGP WPOP 1 Your Wireless POP/Tower Land line from your NOC Cisco Router PTP Wireless Link to Tower 2 Cisco Router Bandwidth Manager WPOP 2 Your other Wireless POP/Tower Land Line from your NOC Cisco Router PTP Wireless Link to Tower 1 Lets Start at the WPOP • 3 180 degree Sectors • 3 runs of Heliax • 4 Access Points • Cisco Router • UPS • Switch Where do the pieces fit? • One Sector per side of tower • One Radio per sector • UPS, Radio, Switch, Router in enclosure at tower base. • Router Wired and or Wireless Link to NOC The Big Picture Wireless PTP WPOP 2 WPOP 1 T1 or Wireless or both T1 or Wireless Bandwidth Manager Internet Router NOC So what do we have? Redundancy at the WPOP (multiple separate radios & antennas) Redundancy in the entire system (multiple paths, using multiple technologies, traffic re-routed on the fly) Shared bandwidth (load balanced traffic, and bandwidth delivered where it is needed on demand) Another Key Point! Maintenanc e! _ Imagine Near Zero Down Time • Easily add to existing infrastructure • Upgrade Remote Devices • Replace Downed Gear But does it Work? Well Let’s See it in Action! Some Examples WPOP 1 Aggregate Traffic WPOP 2 Aggregate Traffic Traffic Flow over PTP between WPOP 1 & WPOP 2 What does it look like when a pipe goes down? PTP under normal PTP with 1 Link Down conditions • 1 Pipe goes down, traffic automatically re-routed over backup link • Pipe comes back up, PTP traffic will return to normal • Your users never know what happened Where do you go from here? Endless Expansion! Wireless PTP WPOP 3 Wireless PTP WPOP 1 Wireless PTP WPOP 2 T1 T1 Bandwidth Manager Wireless PTP to NOC Internet WPOP 4 Router NOC So How Do I Do It? • Now for the routing side of the “Keeping It Up”session • Josh Easton, CTO Bella Mia, Inc. • Routing protocols used and why OSPF • Open Shortest Path First • Allows for redundancy • Smarter routing of traffic Brief intro to OSPF • Every network link (T1, ethernet, etc.) has a cost • When multiple paths are available, lowest cost path is chosen • Total cost of a path is the sum of the costs of each segment • Costs can be manipulated to route your traffic ideally Example of SPF: Mapping How does OSPF fit in? Cost = 96 Wireless PTP WPOP 1 T1 T1 Cost = 64 WPOP 2 Cost = 64 Bandwidth Manager Internet Router NOC Why these costs? • T1 has a default cost of 64 • Wireless link is manually set at cost of 96 • Traffic from WPOP1 to WPOP2 will take the wireless PTP link if it’s available, else it will use T1s • Traffic from WPOP1 to Internet goes via the local T1, else via the wireless PTP link to WPOP2 and then via WPOP2’s T1 Sample Cisco router config interface Ethernet0 ip address 10.0.0.1 255.255.255.0 ! Just an example ip ospf message-digest key 1 md5 <Put OSPF password ip ospf cost 96 exit interface Serial0 ip address 10.0.1.1 255.255.255.0 ! Just an example ip ospf message-digest key 1 md5 <Put OSPF password exit router ospf 100 redistribute connected subnets redistribute static subnets network 10.0.0.1 0.0.0.0 area 0 network 10.0.1.1 0.0.0.0 area 0 default-information originate always area 0 authentication message-digest ospf log-adjacency-changes exit ip address here> ip address here> OSPF in a larger network Cost = 10 Wireless PTP WPOP 3 Cost = 96 Wireless PTP WPOP 1 Cost = 10 Wireless PTP Cost = 64 Cost = 64 T1 WPOP 2 T1 Bandwidth Manager Wireless PTP to NOC Cost = 63 Internet WPOP 4 Router NOC Why these costs? • Cost from WPOP4 to NOC is manually set at 63 • Traffic from one WPOP to another WPOP will use the wireless backbone by default • WPOP3 and WPOP4 use WPOP4’s link to the NOC to get on the Internet • WPOP1 and WPOP2 use their T1s to get on the Internet • If any link goes down, traffic will be routed around the damage Questions? Presentation presented and created by Jeremy Kinsey and Josh Easton Thank you for your attention! A PPT copy of the presentation can also be found online at: http://wispconvi.mia.net/ppt/keeping-it-up.ppt You can contact me via email with further questions at: [email protected] www.wisconsinwireless.net a bella mia company Copyright 2004 bella mia, inc