DocumentCode
623890
Title
CEDAR: An optimal and distributed strategy for packet recovery in wireless networks
Author
Chenxi Qiu ; Haiying Shen ; Soltani, Sima ; Sapra, Karan ; Hao Jiang ; Hallstrom, Jari
Author_Institution
Dept. of Electr. & Comput. Eng., Clemson Univ., Clemson, SC, USA
fYear
2013
fDate
14-19 April 2013
Firstpage
2859
Lastpage
2867
Abstract
Underlying link-layer protocols of wireless networks use the conventional “store and forward” design paradigm cannot provide highly sustainable reliability and stability in wireless communication, which introduce significant barriers and setbacks in scalability and deployments of wireless networks. In this paper, we propose a Code Embedded Distributed Adaptive and Reliable (CEDAR) link-layer framework that targets low latency and high throughput. CEDAR is the first comprehensive theoretical framework for analyzing and designing distributed and adaptive error recovery for wireless networks. It employs a theoretically-sound framework for embedding channel codes in each packet and performs the error correcting process in selected intermediate nodes in packet´s route. To identify the intermediate nodes for the en/decoding for minimizing average packet latency, we mathematically analyze the average packet delay, using Finite State Markovian Channel model and priority queuing model, and then formalize the problem as a non-linear integer programming problem. Also, we propose a scalable and distributed scheme to solve this problem. The results from real-world testbed “NESTbed” and simulation with Matlab prove that CEDAR is superior to the schemes using hop-by-hop decoding and destination-decoding not only in packet delay but also in throughput. In addition, the simulation results show that CEDAR can achieve the optimal performance in most cases.
Keywords
channel coding; decoding; error correction; error correction codes; packet radio networks; CEDAR; Matlab; adaptive error recovery; average packet delay; average packet latency; channel codes; code embedded distributed adaptive link layer framework; destination decoding; distributed strategy; error correcting process; finite state Markovian channel model; hop by hop decoding; link layer protocols; nonlinear integer programming problem; packet recovery; queuing model; reliable link layer framework; sustainable reliability; wireless communication stability; wireless networks; Bit error rate; Decoding; Delays; Mathematical model; Stability analysis; Wireless communication;
fLanguage
English
Publisher
ieee
Conference_Titel
INFOCOM, 2013 Proceedings IEEE
Conference_Location
Turin
ISSN
0743-166X
Print_ISBN
978-1-4673-5944-3
Type
conf
DOI
10.1109/INFCOM.2013.6567096
Filename
6567096
Link To Document