Rate-achieving policy in finite-horizon throughput region for multi-user interference channels

Yirui Cong; Xiangyun Zhou; Rodney A. Kennedy

doi:10.1109/GLOCOM.2016.7842198

Rate-achieving policy in finite-horizon throughput region for multi-user interference channels

Yirui Cong, Xiangyun Zhou, Rodney A. Kennedy

Research output: Contribution to journal › Conference article › peer-review

Abstract

This paper studies a wireless network consisting of multiple transmitter-receiver pairs sharing the same spectrum where interference is regarded as noise. Previously, the throughput region of such a network was characterized for either one time slot or an infinite time horizon. This work aims to close the gap by investigating the throughput region for transmissions over a finite time horizon. We derive an efficient algorithm to examine the achievability of any given rate in the finite-horizon throughput region and provide the rate-achieving policy. The computational efficiency of our algorithm comes from the use of A∗ search with a carefully chosen heuristic function and a tree pruning strategy. We also show that the celebrated max-weight algorithm which finds all achievable rates in the infinite-horizon throughput region fails to work for the finite-horizon throughput region.

Original language	English
Article number	7842198
Journal	Proceedings - IEEE Global Communications Conference, GLOBECOM
DOIs	https://doi.org/10.1109/GLOCOM.2016.7842198
Publication status	Published - 2016
Event	59th IEEE Global Communications Conference, GLOBECOM 2016 - Washington, United States Duration: 4 Dec 2016 → 8 Dec 2016

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title = "Rate-achieving policy in finite-horizon throughput region for multi-user interference channels",

abstract = "This paper studies a wireless network consisting of multiple transmitter-receiver pairs sharing the same spectrum where interference is regarded as noise. Previously, the throughput region of such a network was characterized for either one time slot or an infinite time horizon. This work aims to close the gap by investigating the throughput region for transmissions over a finite time horizon. We derive an efficient algorithm to examine the achievability of any given rate in the finite-horizon throughput region and provide the rate-achieving policy. The computational efficiency of our algorithm comes from the use of A∗ search with a carefully chosen heuristic function and a tree pruning strategy. We also show that the celebrated max-weight algorithm which finds all achievable rates in the infinite-horizon throughput region fails to work for the finite-horizon throughput region.",

author = "Yirui Cong and Xiangyun Zhou and Kennedy, {Rodney A.}",

note = "Publisher Copyright: {\textcopyright} 2016 IEEE.; 59th IEEE Global Communications Conference, GLOBECOM 2016 ; Conference date: 04-12-2016 Through 08-12-2016",

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AU - Zhou, Xiangyun

AU - Kennedy, Rodney A.

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N2 - This paper studies a wireless network consisting of multiple transmitter-receiver pairs sharing the same spectrum where interference is regarded as noise. Previously, the throughput region of such a network was characterized for either one time slot or an infinite time horizon. This work aims to close the gap by investigating the throughput region for transmissions over a finite time horizon. We derive an efficient algorithm to examine the achievability of any given rate in the finite-horizon throughput region and provide the rate-achieving policy. The computational efficiency of our algorithm comes from the use of A∗ search with a carefully chosen heuristic function and a tree pruning strategy. We also show that the celebrated max-weight algorithm which finds all achievable rates in the infinite-horizon throughput region fails to work for the finite-horizon throughput region.

AB - This paper studies a wireless network consisting of multiple transmitter-receiver pairs sharing the same spectrum where interference is regarded as noise. Previously, the throughput region of such a network was characterized for either one time slot or an infinite time horizon. This work aims to close the gap by investigating the throughput region for transmissions over a finite time horizon. We derive an efficient algorithm to examine the achievability of any given rate in the finite-horizon throughput region and provide the rate-achieving policy. The computational efficiency of our algorithm comes from the use of A∗ search with a carefully chosen heuristic function and a tree pruning strategy. We also show that the celebrated max-weight algorithm which finds all achievable rates in the infinite-horizon throughput region fails to work for the finite-horizon throughput region.

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JO - Proceedings - IEEE Global Communications Conference, GLOBECOM

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T2 - 59th IEEE Global Communications Conference, GLOBECOM 2016

Y2 - 4 December 2016 through 8 December 2016

ER -

Rate-achieving policy in finite-horizon throughput region for multi-user interference channels

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