FDoF: Enhancing Channel Utilization for 802.11ac

Multi-user multiple input multiple output (MU-MIMO) enables a multi-antenna access point to serve multiple users simultaneously, and has been adopted as the IEEE 802.11ac standard. While several PHY-MAC designs have recently been proposed to improve the throughput performance of a MU-MIMO WLAN, they...

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Bibliographic Details
Published in:IEEE/ACM transactions on networking 2018-02, Vol.26 (1), p.465-477
Main Authors: Lin, Chi-Han, Chen, Yi-Ting, Lin, Kate Ching-Ju, Chen, Wen-Tsuen
Format: Article
Language:English
Subjects:
access protocol
Idling
Interference
Local area networks
MIMO
Multiplexing
Power management
Precoding
Resource management
Signal to noise ratio
Streams
Throughput
Wireless LAN
Wireless networks
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Summary:Multi-user multiple input multiple output (MU-MIMO) enables a multi-antenna access point to serve multiple users simultaneously, and has been adopted as the IEEE 802.11ac standard. While several PHY-MAC designs have recently been proposed to improve the throughput performance of a MU-MIMO WLAN, they, however, usually assume that all the concurrent streams are of roughly equal length. In reality, users usually have frames with heterogeneous lengths even after aggregation, leading to different lengths of a transmission time. Hence, the concurrent transmission opportunities might not always be fully utilized when some streams finish earlier than the others in a transmission opportunity. To resolve this inefficiency, this paper presents full degree-of-freedom (FDoF), a PHY-MAC design that exploits a novel power allocation scheme to reduce the idle channel time and further leverages frame padding to better utilize the spatial multiplexing gain. Unlike traditional MIMO power allocation, which aims at maximizing the theoretical sum-rate, FDoF's power allocation explicitly considers heterogeneous frame lengths and minimizes the channel time required to finish concurrent frames, as a result improving the effective throughput. FDoF's padding protocol then identifies proper users to reuse the remaining idle channel time, while preventing this padding from harming all the ongoing streams. Our evaluation via large-scale trace-driven simulations demonstrates that FDoF's improves the throughput by up to 2.83\times , or by 1.36\times on average, as compared to the conventional 802.11ac. By combining FDoF's power allocation with frame padding, the average throughput gain can be further increased to 1.75\times .
ISSN:1063-6692
1558-2566
DOI:10.1109/TNET.2017.2785880