Princeton University / California Institute of Technology / Stable Path Problem / /
IndustryTerm
cooperative protocol / source utilities / given network protocol / theoretical tools / communication infrastructure / given protocol / ad hoc networks / control protocols / end user utilities / optimization algorithm / feasible solution / implementable network / dual descent algorithm / non-cooperative protocol / important applications / communication systems / computational algorithms / wireless cellular network / language to think about layered network / congestion control protocols / energy efficiency / modularized and distributed solution / communication network / congestion control protocol / wireless networks / overall communication network / end-user application utilities / energy / /
Organization
California Institute of Technology / Princeton University / Electrical Engineering Department / /
Person
Steven H. Low / Border Gateway Protocols / John C. Doyle / /
Position
Forward Engineering / Forward / engineer / /
Product
Transmission Control / /
Technology
engineer Border Gateway Protocols / existing algorithm / Distributed algorithm / 1.1 Congestion control protocols / vector field representation Reverse engineering non-cooperative protocol / 1.4 Heterogeneous congestion control protocols / local algorithms / congestion control protocol / Main Method Reverse engineering cooperative protocol / given protocol / MAC protocol / random access / dual descent algorithm / given network protocol / optimization algorithm / /
Layering As Optimization Decomposition Mung Chiang∗, Steven H. Low †, A. Robert Calderbank‡, John C. Doyle§ April 2, 2006 Abstract Network protocols in layered architectures have historically been obtained on an a