HackMan: hacking commodity millimeter-wave hardware for a measurement study
The extremely high frequency of Millimeter-Wave technology warrants Gbps throughput for the next-generation wireless communication systems, but mmWave signals also suffer from severe path loss due to high attenuation. To compensate for this loss, mmWave radios establish communication links via direc...
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sg-ntu-dr.10356-1611432022-08-16T08:18:20Z HackMan: hacking commodity millimeter-wave hardware for a measurement study Cai, Chao Chen, Zhen Luo, Jun Zhu, Linwei Hu, Menglan School of Computer Science and Engineering Engineering::Computer science and engineering Millimeter-Wave Technology Beam Control The extremely high frequency of Millimeter-Wave technology warrants Gbps throughput for the next-generation wireless communication systems, but mmWave signals also suffer from severe path loss due to high attenuation. To compensate for this loss, mmWave radios establish communication links via directional beams so as to increase channel gains and communication range. Until recently, the measurement studies on mmWave technology were mainly based on prototypes built from band-limited Software Defined Radio, which could not characterize performance in realistic settings. Latest studies using commodity hardware reports straightforward measurements on the impact of environment settings but did not present deep analysis on the correlations of low-layer information. Meanwhile, those studies lack the ability to configure commodity devices under controlled settings, for instance, a single beam pattern for experimentation, thus failing to perform deeper analysis on low-layer protocol parameters. In this paper, we conduct extensive measurements in typical indoor settings, utilizing 802.11ad-compliant commodity hardware. Different from earlier studies, we hack the firmware and gain the privilege to modify physical layer settings online, enabling us to gain more insights under controlled settings.Essentially, we have demonstrated that (1) Signal-to-Noise Ratio, the criteria for beam control, may not be positively correlated with throughput, (2) sticking to a single beam pattern during data transmission can lead to both channel gains and throughput improvement, and (3) only independent cross-links could interfere with each other while multi-links coordinated by one AP experience no interference. These insights lead us to rethink the existing beam control policy. 2022-08-16T08:18:20Z 2022-08-16T08:18:20Z 2020 Journal Article Cai, C., Chen, Z., Luo, J., Zhu, L. & Hu, M. (2020). HackMan: hacking commodity millimeter-wave hardware for a measurement study. Wireless Networks, 26(7), 5411-5425. https://dx.doi.org/10.1007/s11276-020-02402-3 1022-0038 https://hdl.handle.net/10356/161143 10.1007/s11276-020-02402-3 2-s2.0-85087413117 7 26 5411 5425 en Wireless Networks © 2020 Springer Science+Business Media, LLC, part of Springer Nature. All rights reserved. |
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Engineering::Computer science and engineering Millimeter-Wave Technology Beam Control Cai, Chao Chen, Zhen Luo, Jun Zhu, Linwei Hu, Menglan HackMan: hacking commodity millimeter-wave hardware for a measurement study |
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The extremely high frequency of Millimeter-Wave technology warrants Gbps throughput for the next-generation wireless communication systems, but mmWave signals also suffer from severe path loss due to high attenuation. To compensate for this loss, mmWave radios establish communication links via directional beams so as to increase channel gains and communication range. Until recently, the measurement studies on mmWave technology were mainly based on prototypes built from band-limited Software Defined Radio, which could not characterize performance in realistic settings. Latest studies using commodity hardware reports straightforward measurements on the impact of environment settings but did not present deep analysis on the correlations of low-layer information. Meanwhile, those studies lack the ability to configure commodity devices under controlled settings, for instance, a single beam pattern for experimentation, thus failing to perform deeper analysis on low-layer protocol parameters. In this paper, we conduct extensive measurements in typical indoor settings, utilizing 802.11ad-compliant commodity hardware. Different from earlier studies, we hack the firmware and gain the privilege to modify physical layer settings online, enabling us to gain more insights under controlled settings.Essentially, we have demonstrated that (1) Signal-to-Noise Ratio, the criteria for beam control, may not be positively correlated with throughput, (2) sticking to a single beam pattern during data transmission can lead to both channel gains and throughput improvement, and (3) only independent cross-links could interfere with each other while multi-links coordinated by one AP experience no interference. These insights lead us to rethink the existing beam control policy. |
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School of Computer Science and Engineering |
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School of Computer Science and Engineering Cai, Chao Chen, Zhen Luo, Jun Zhu, Linwei Hu, Menglan |
| format |
Article |
| author |
Cai, Chao Chen, Zhen Luo, Jun Zhu, Linwei Hu, Menglan |
| author_sort |
Cai, Chao |
| title |
HackMan: hacking commodity millimeter-wave hardware for a measurement study |
| title_short |
HackMan: hacking commodity millimeter-wave hardware for a measurement study |
| title_full |
HackMan: hacking commodity millimeter-wave hardware for a measurement study |
| title_fullStr |
HackMan: hacking commodity millimeter-wave hardware for a measurement study |
| title_full_unstemmed |
HackMan: hacking commodity millimeter-wave hardware for a measurement study |
| title_sort |
hackman: hacking commodity millimeter-wave hardware for a measurement study |
| publishDate |
2022 |
| url |
https://hdl.handle.net/10356/161143 |
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1743119557839552512 |