Wenjun Hu scite author profile

This paper proposes COPE, a new architecture for wireless mesh networks. In addition to forwarding packets, routers mix (i.e., code) packets from different sources to increase the information content of each transmission. We show that intelligently mixing packets increases network throughput. Our design is rooted in the theory of network coding. Prior work on network coding is mainly theoretical and focuses on multicast traffic. This paper aims to bridge theory with practice; it addresses the common case of unicast traffic, dynamic and potentially bursty flows, and practical issues facing the integration of network coding in the current network stack. We evaluate our design on a 20-node wireless network, and discuss the results of the first testbed deployment of wireless network coding. The results show that COPE largely increases network throughput. The gains vary from a few percent to several folds depending on the traffic pattern, congestion level, and transport protocol.

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On Practical Network Coding for Wireless Environments

Katabi

Rahul

et al.

170

266

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In this extended abstract, we briefly describe COPE, an opportunistic approach to network coding that provides orders of magnitudes improvement in the throughput of dense wireless mesh networks. COPE supports multiple unicast flows, deals with bursty and unknown demands, and is simple and easy to deploy. Our COPE prototype provides the first implementation of network coding in the wireless environment. It shows the supremacy of opportunistic network coding over current wireless implementations.

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Predictable 802.11 packet delivery from wireless channel measurements

et al. 2010

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RSSI is known to be a fickle indicator of whether a wireless link will work, for many reasons. This greatly complicates operation because it requires testing and adaptation to find the best rate, transmit power or other parameter that is tuned to boost performance. We show that, for the first time, wireless packet delivery can be accurately predicted for commodity 802.11 NICs from only the channel measurements that they provide. Our model uses 802.11n Channel State Information measurements as input to an OFDM receiver model we develop by using the concept of effective SNR. It is simple, easy to deploy, broadly useful, and accurate. It makes packet delivery predictions for 802.11a/g SISO rates and 802.11n MIMO rates, plus choices of transmit power and antennas. We report testbed experiments that show narrow transition regions (<2 dB for most links) similar to the near-ideal case of narrowband, frequency-flat channels. Unlike RSSI, this lets us predict the highest rate that will work for a link, trim transmit power, and more. We use trace-driven simulation to show that our rate prediction is as good as the best rate adaptation algorithms for 802.11a/g, even over dynamic channels, and extends this good performance to 802.11n.

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Tool release

Halperin

Sheth

et al. 2011

SIGCOMM Comput. Commun. Rev.

1,453

140

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We are pleased to announce the release of a tool that records detailed measurements of the wireless channel along with received 802.11 packet traces. It runs on a commodity 802.11n NIC, and records Channel State Information (CSI) based on the 802.11 standard. Unlike Receive Signal Strength Indicator (RSSI) values, which merely capture the total power received at the listener, the CSI contains information about the channel between sender and receiver at the level of individual data subcarriers, for each pair of transmit and receive antennas.Our toolkit uses the Intel WiFi Link 5300 wireless NIC with 3 antennas. It works on up-to-date Linux operating systems: in our testbed we use Ubuntu 10.04 LTS with the 2.6.36 kernel. The measurement setup comprises our customized versions of Intel's closesource firmware and open-source iwlwifi wireless driver, userspace tools to enable these measurements, access point functionality for controlling both ends of the link, and Matlab (or Octave) scripts for data analysis. We are releasing the binary of the modified firmware, and the source code to all the other components.

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ParCast+: Parallel Video Unicast in MIMO-OFDM WLANs

Liu

Luo

et al. 2014

IEEE Trans. Multimedia

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Wenjun Hu

XORs in the Air: Practical Wireless Network Coding

On Practical Network Coding for Wireless Environments

Predictable 802.11 packet delivery from wireless channel measurements

Tool release

ParCast+: Parallel Video Unicast in MIMO-OFDM WLANs

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