Robust Large-scale Metasurface Inverse Design Using Phaseless Data with Invertible Neural Network

On-demand manipulation of electromagnetic (EM) far-fields has greatly accelerated the extension of intelligent metasurfaces in diverse applications. An important prerequisite for most of the effective utilizations boils down to the precise and expeditious determination of far-field. However, the exi...

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Bibliographic Details
Published in:IEEE transactions on antennas and propagation 2024-10, p.1-1
Main Authors: Wang, Zhedong, Qian, Chao, Saifullah, Yasir, Fang, Yuan, Li, Er-Ping, Chen, Hongsheng
Format: Article
Language:English
Subjects:
intelligent metasurfaces
inverse design
invertible neural network
Online Access:Get full text
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Summary:On-demand manipulation of electromagnetic (EM) far-fields has greatly accelerated the extension of intelligent metasurfaces in diverse applications. An important prerequisite for most of the effective utilizations boils down to the precise and expeditious determination of far-field. However, the existence of one-to-many mapping between the far-field space and metasurface space renders the inverse-design neural network hard to converge and ill-posed, especially in the case of phaseless far-field. In the work, we introduce an invertible neural network (INN) based generation-elimination framework. By introducing extra trainable latent variables in inverse training, the model can largely mitigate the impact by the phaseless far-field, which is the chief culprit of the one-to-many issue. The INN also provides a powerful stochastically generative capability based on trained latent space. An elimination network is cascaded to INN, where groups of nominated patterns from INN will be screen and eliminate the inferior metasurface patterns. Both simulated and experimental results demonstrate that the far-field match degrees are improved by up to 50%, compared with the case of general deep neural network (DNN), meanwhile retaining a competitive process cycle within 1 ms. This cost-effective and rapid scheme can be deployed on metasurfaces with larger scale to significantly improve signal strength and the quality of wireless communication for Internet of Things (IoT) devices.
ISSN:0018-926X
1558-2221
DOI:10.1109/TAP.2024.3484014