Two-dimensional direction-of-arrival estimation using stacked intelligent metasurfaces
Two-dimensional direction-of-arrival estimation using stacked intelligent metasurfaces
Stacked intelligent metasurfaces (SIM) are capable of emulating reconfigurable physical neural networks by relying on electromagnetic (EM) waves as carriers. They can also perform various complex computational and signal processing tasks. A SIM is constructed by densely integrating multiple metasurface layers, each consisting of a large number of small meta-atoms that can control the EM waves passing through it. In this paper, we harness a SIM for two-dimensional (2D) direction-of-arrival (DOA) estimation. In contrast to the conventional designs, an advanced SIM in front of the receiver array automatically carries out the 2D discrete Fourier transform (DFT) as the incident waves propagate through it. As a result, the receiver array directly observes the angular spectrum of the incoming signal. In this context, the DOA estimates can be readily obtained by using probes to detect the energy distribution on the receiver array. This avoids the need for power-thirsty radio frequency (RF) chains. To enable SIM to perform the 2D DFT, we formulate the optimization problem of minimizing the fitting error between the SIM’s EM response and the 2D DFT matrix. Furthermore, a gradient descent algorithm is customized for iteratively updating the phase shift of each meta-atom in SIM. To further improve the DOA estimation accuracy, we configure the phase shift pattern in
the zeroth layer of the SIM to generate a set of 2D DFT matrices associated with orthogonal spatial frequency bins. Additionally, we analytically evaluate the performance of the proposed SIMbased DOA estimator by deriving a tight upper bound for the mean square error (MSE). Our numerical simulations verify the capability of a well-trained SIM to perform DOA estimation and corroborate our theoretical analysis. It is demonstrated that a SIM having an optical computational speed achieves an MSE of 10-4 for DOA estimation.
An, Jiancheng
5fa38cfb-6010-4404-a39c-f03c68f248c5
Yuen, Chau
0dd04333-bade-4812-b3df-a416597f1325
Guan, Yong Liang
b79fbba2-56fe-448f-b421-cab91ee3bfb8
Renzo, Marco di
950fb927-43b2-4b8f-b387-9b0a2e669f15
Debbah, Mérouane
fe23e026-1926-49c7-97d7-425ad555152a
Poor, H. Vincent
2ce6442b-62db-47b3-8d8e-484e7fad51af
Hanzo, Lajos
66e7266f-3066-4fc0-8391-e000acce71a1
An, Jiancheng
5fa38cfb-6010-4404-a39c-f03c68f248c5
Yuen, Chau
0dd04333-bade-4812-b3df-a416597f1325
Guan, Yong Liang
b79fbba2-56fe-448f-b421-cab91ee3bfb8
Renzo, Marco di
950fb927-43b2-4b8f-b387-9b0a2e669f15
Debbah, Mérouane
fe23e026-1926-49c7-97d7-425ad555152a
Poor, H. Vincent
2ce6442b-62db-47b3-8d8e-484e7fad51af
Hanzo, Lajos
66e7266f-3066-4fc0-8391-e000acce71a1
An, Jiancheng, Yuen, Chau and Guan, Yong Liang
,
et al.
(2024)
Two-dimensional direction-of-arrival estimation using stacked intelligent metasurfaces.
IEEE Journal on Selected Areas in Communications.
(In Press)
Abstract
Stacked intelligent metasurfaces (SIM) are capable of emulating reconfigurable physical neural networks by relying on electromagnetic (EM) waves as carriers. They can also perform various complex computational and signal processing tasks. A SIM is constructed by densely integrating multiple metasurface layers, each consisting of a large number of small meta-atoms that can control the EM waves passing through it. In this paper, we harness a SIM for two-dimensional (2D) direction-of-arrival (DOA) estimation. In contrast to the conventional designs, an advanced SIM in front of the receiver array automatically carries out the 2D discrete Fourier transform (DFT) as the incident waves propagate through it. As a result, the receiver array directly observes the angular spectrum of the incoming signal. In this context, the DOA estimates can be readily obtained by using probes to detect the energy distribution on the receiver array. This avoids the need for power-thirsty radio frequency (RF) chains. To enable SIM to perform the 2D DFT, we formulate the optimization problem of minimizing the fitting error between the SIM’s EM response and the 2D DFT matrix. Furthermore, a gradient descent algorithm is customized for iteratively updating the phase shift of each meta-atom in SIM. To further improve the DOA estimation accuracy, we configure the phase shift pattern in
the zeroth layer of the SIM to generate a set of 2D DFT matrices associated with orthogonal spatial frequency bins. Additionally, we analytically evaluate the performance of the proposed SIMbased DOA estimator by deriving a tight upper bound for the mean square error (MSE). Our numerical simulations verify the capability of a well-trained SIM to perform DOA estimation and corroborate our theoretical analysis. It is demonstrated that a SIM having an optical computational speed achieves an MSE of 10-4 for DOA estimation.
Text
JSAC_Two_Dimensional_Direction_of_Arrival_Estimation_Using_Stacked_Intelligent_Metasurfaces (1)
- Accepted Manuscript
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Accepted/In Press date: 19 April 2024
Identifiers
Local EPrints ID: 489843
URI: http://eprints.soton.ac.uk/id/eprint/489843
ISSN: 1558-0008
PURE UUID: a6e2a05d-5934-4684-b9d4-81c321b9bf03
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Date deposited: 03 May 2024 16:33
Last modified: 04 May 2024 01:32
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Contributors
Author:
Jiancheng An
Author:
Chau Yuen
Author:
Yong Liang Guan
Author:
Marco di Renzo
Author:
Mérouane Debbah
Author:
H. Vincent Poor
Author:
Lajos Hanzo
Corporate Author: et al.
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