Aperiodic geometry design for DOA estimation of broadband sources using compressive sensing
Antenna arrays used in Compressive Sensing (CS) based algorithms are generated randomly to minimize mutual coherence. This scheme, although good for compressive sensing, suffers from practical limitations. Random sampling of antenna aperture is impractical. Rectangular arrays, although uniform, suff...
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sg-ntu-dr.10356-1445232020-11-11T02:20:53Z Aperiodic geometry design for DOA estimation of broadband sources using compressive sensing Asghar, Sayed Zeeshan Ng, Boon Poh School of Electrical and Electronic Engineering Engineering::Electrical and electronic engineering Compressive Sensing Aperiodic Geometry Antenna arrays used in Compressive Sensing (CS) based algorithms are generated randomly to minimize mutual coherence. This scheme, although good for compressive sensing, suffers from practical limitations. Random sampling of antenna aperture is impractical. Rectangular arrays, although uniform, suffer from poor performance when used in CS algorithms. It is particularly ill suited to algorithms designed to estimate DOA of broadband sources, because of the introduction of grating lobes. Aperiodic arrays offer some advantages in the CS scenario. The aperiodic geometries based on Penrose and Danzer tiling are inherently sparse as they utilize a fewer number of sensors as compared to the regular geometries. Based on minimization of mutual coherence, this paper develops a novel optimization scheme, that can generate sparse array geometries offering improved performance for CS algorithms. This paper demonstrates that it is possible to design aperiodic arrays that perform much better than rectangular arrays by using a simple disturbance optimization scheme, that can be applied to other aperiodic geometries as well. A greedy MMV based compressive sensing algorithm, SOMP, is used to evaluate the performance of a number of geometries. Two geometries have been identified that perform better than all other geometries studied, including the random-sampling based geometries. Accepted version 2020-11-11T02:20:53Z 2020-11-11T02:20:53Z 2018 Journal Article Asghar, S. Z., & Ng, B. P. (2019). Aperiodic geometry design for DOA estimation of broadband sources using compressive sensing. Signal Processing, 155, 96-107. doi:10.1016/j.sigpro.2018.09.026 0165-1684 https://hdl.handle.net/10356/144523 10.1016/j.sigpro.2018.09.026 155 96 107 en Signal Processing © 2018 Elsevier B.V. All rights reserved. This paper was published in Signal Processing and is made available with permission of Elsevier B.V. application/pdf |
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Engineering::Electrical and electronic engineering Compressive Sensing Aperiodic Geometry Asghar, Sayed Zeeshan Ng, Boon Poh Aperiodic geometry design for DOA estimation of broadband sources using compressive sensing |
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Antenna arrays used in Compressive Sensing (CS) based algorithms are generated randomly to minimize mutual coherence. This scheme, although good for compressive sensing, suffers from practical limitations. Random sampling of antenna aperture is impractical. Rectangular arrays, although uniform, suffer from poor performance when used in CS algorithms. It is particularly ill suited to algorithms designed to estimate DOA of broadband sources, because of the introduction of grating lobes. Aperiodic arrays offer some advantages in the CS scenario. The aperiodic geometries based on Penrose and Danzer tiling are inherently sparse as they utilize a fewer number of sensors as compared to the regular geometries. Based on minimization of mutual coherence, this paper develops a novel optimization scheme, that can generate sparse array geometries offering improved performance for CS algorithms. This paper demonstrates that it is possible to design aperiodic arrays that perform much better than rectangular arrays by using a simple disturbance optimization scheme, that can be applied to other aperiodic geometries as well. A greedy MMV based compressive sensing algorithm, SOMP, is used to evaluate the performance of a number of geometries. Two geometries have been identified that perform better than all other geometries studied, including the random-sampling based geometries. |
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School of Electrical and Electronic Engineering |
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School of Electrical and Electronic Engineering Asghar, Sayed Zeeshan Ng, Boon Poh |
| format |
Article |
| author |
Asghar, Sayed Zeeshan Ng, Boon Poh |
| author_sort |
Asghar, Sayed Zeeshan |
| title |
Aperiodic geometry design for DOA estimation of broadband sources using compressive sensing |
| title_short |
Aperiodic geometry design for DOA estimation of broadband sources using compressive sensing |
| title_full |
Aperiodic geometry design for DOA estimation of broadband sources using compressive sensing |
| title_fullStr |
Aperiodic geometry design for DOA estimation of broadband sources using compressive sensing |
| title_full_unstemmed |
Aperiodic geometry design for DOA estimation of broadband sources using compressive sensing |
| title_sort |
aperiodic geometry design for doa estimation of broadband sources using compressive sensing |
| publishDate |
2020 |
| url |
https://hdl.handle.net/10356/144523 |
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1688665536460750848 |