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Human Silhouette and Skeleton Video Synthesis Through Wi-Fi Signals

Danilo Avola

Department of Computer Science, Sapienza University of Rome Via Salaria, 113, Rome, 00198, Italy

E-mail Address: avola@di.uniroma1.it

Corresponding author.

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Marco Cascio

Department of Computer Science, Sapienza University of Rome Via Salaria, 113, Rome, 00198, Italy

E-mail Address: cascio@di.uniroma1.it

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Luigi Cinque

Department of Computer Science, Sapienza University of Rome Via Salaria, 113, Rome, 00198, Italy

E-mail Address: cinque@di.uniroma1.it

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Alessio Fagioli

Department of Computer Science, Sapienza University of Rome Via Salaria, 113, Rome, 00198, Italy

E-mail Address: fagioli@di.uniroma1.it

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, and

Gian Luca Foresti

Department of Computer Science, Mathematics and Physics, University of Udine, Via delle Scienze 206, Udine, 33100, Italy

E-mail Address: gianluca.foresti@uniud.it

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https://doi.org/10.1142/S0129065722500150Cited by:11 (Source: Crossref)

Abstract

The increasing availability of wireless access points (APs) is leading toward human sensing applications based on Wi-Fi signals as support or alternative tools to the widespread visual sensors, where the signals enable to address well-known vision-related problems such as illumination changes or occlusions. Indeed, using image synthesis techniques to translate radio frequencies to the visible spectrum can become essential to obtain otherwise unavailable visual data. This domain-to-domain translation is feasible because both objects and people affect electromagnetic waves, causing radio and optical frequencies variations. In the literature, models capable of inferring radio-to-visual features mappings have gained momentum in the last few years since frequency changes can be observed in the radio domain through the channel state information (CSI) of Wi-Fi APs, enabling signal-based feature extraction, e.g. amplitude. On this account, this paper presents a novel two-branch generative neural network that effectively maps radio data into visual features, following a teacher–student design that exploits a cross-modality supervision strategy. The latter conditions signal-based features in the visual domain to completely replace visual data. Once trained, the proposed method synthesizes human silhouette and skeleton videos using exclusively Wi-Fi signals. The approach is evaluated on publicly available data, where it obtains remarkable results for both silhouette and skeleton videos generation, demonstrating the effectiveness of the proposed cross-modality supervision strategy.

Keywords:

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