1 / 1

Optics In Routers Isaac Keslassy, Da Chuang, Nick McKeown

R. R. In. In. Input. Output. Linecard Rack 1. Out. Out. Fixed Laser/Modulator. Detector. Out. Out. 1. 1. 2. 3. 2. 2R/N. In. In. L = 16 160Gb/s linecards. L = 16 160Gb/s linecards. l. l. 1. 1. Out. Out. 1. N. 1. 1. l. l. l. l. ,. ,. l. l. 1. 2. 1.

isra
Download Presentation

Optics In Routers Isaac Keslassy, Da Chuang, Nick McKeown

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. R R In In Input Output Linecard Rack 1 Out Out Fixed Laser/Modulator Detector Out Out 1 1 2 3 2 2R/N In In L = 16 160Gb/s linecards L = 16 160Gb/s linecards l l 1 1 Out Out 1 N 1 1 l l l l , , l l 1 2 1 2 Linecard 1 Linecard 1 2 2 2 1 l l … … N N In In l l N Out Out N Input Output l l 1 1 2 1 l l 2 2 , l l , l l Linecard 2 Linecard 2 1 2 1 2 2 2 2 3 Out Out … l l … In In NxN AWGR N N l l Out Out N N Input Output l l 1 1 N N-1 N N l l l l , , l l 1 2 1 2 Linecard N Linecard N 2 2 1 N l l … … Out Out N Optics N l l N N 2 N 2 3 4 1 N 4 3 1 1 1 1 L 2 2 L L 2 L 2 1 Electronics Electronics Switch Fabric R R R R R R Scheduler R R R/N R/N In R/N R/N R/N R/N R/N R/N R R In R/N R/N R/N R/N R/N R/N R/N R R R/N In R/N R/N Uniform Multiplexing Uniform Demultiplexing Uniform Demultiplexing Uniform Multiplexing Linecard Rack G = 40 Switch Rack < 100W Group/Rack 1 Group/Rack 1 Uniform Spreading 40 x 40 static MEMS L = 16 160Gb/s linecards 1 2 Static MEMS Switch Static MEMS Switch Group/RackG Group/RackG 55 56 Optics In RoutersIsaac Keslassy, Da Chuang, Nick McKeown Wireline Thrust Router Wish List Stanford 100Tb/s Router Typical Router Architecture Scale to High Linecard Speeds • No Centralized Scheduler • Optical Switch Fabric • Low Packet-Processing Complexity Scale to High Number of Linecards • High Number of Linecards • Fault-Tolerance to Linecard Failures Provide Performance Guarantees • 100% Throughput Guarantee • Delay Guarantee • No Packet Reordering • “Optics in Routers” project • http://yuba.stanford.edu/or/ • Some challenging numbers: • 100Tb/s • R=160Gb/s linecard rate • N=640 linecards • Should provide performance guarantees A Single Combined Mesh AWGR-Based Solution Load-Balanced Switch R R R/N R/N In R/N R/N R/N R/N R/N R/N R R In R/N R/N R/N R/N R/N R/N R/N R R R/N In R/N R/N Bounding Reordering by Bounding Δ High Number of Linecards: Use Hierarchical Mesh FOFF (Full Ordered Frames First) Algorithm • Property 1: FOFF maintains packet order. • Property 2: FOFF maintains an average packet delay within constant from ideal output-queued router. • Corollary:FOFF has 100% throughput for any adversarial traffic. • Property 3: FOFF has O(1) complexity. • Property 4: FOFF is distributed. Fault-Tolerance to Linecard Failures: Use MEMS Switches Implementation of a 100Tb/s Load-Balanced Router Summary • The load-balanced switch • Does not need any centralized scheduling • Can use a mesh • Using FOFF • It keeps packets in order • It guarantees 100% throughput • With the electro-optical architecture • It scales to high port numbers • It tolerates linecard failure

More Related