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FMNet: latent feature-wise mapping network for cleaning up noisy micro-doppler spectrogram

FMNet: latent feature-wise mapping network for cleaning up noisy micro-doppler spectrogram
FMNet: latent feature-wise mapping network for cleaning up noisy micro-doppler spectrogram

Micro-Doppler signatures contain considerable information about target dynamics. However, the radar sensing systems are easily affected by noisy surroundings, resulting in uninterpretable motion patterns on the micro-Doppler spectrogram (μ -DS). Meanwhile, radar returns often suffer from multipath, clutter, and interference. These issues lead to difficulty in, for example, motion feature extraction and activity classification using micro-Doppler signatures. In this article, we propose a latent feature-wise mapping strategy, called feature mapping network (FMNet), to transform measured spectrograms so that they more closely resemble the output from a simulation under the same conditions. Based on measured spectrogram and the matched simulated data, our framework contains three parts: an encoder which is used to extract latent representations/features, a decoder outputs reconstructed spectrogram according to the latent features, and a discriminator minimizes the distance of latent features of measured and simulated data. We demonstrate the FMNet with six activities data and two experimental scenarios, and final results show strong enhanced patterns and can keep actual motion information to the greatest extent. On the other hand, we also propose a novel idea which trains a classifier with only simulated data and predicts new measured samples after cleaning them up with the FMNet. From final classification results, we can see significant improvements.

Activity classification, Adversarial autoencoder (AAE), Deep learning (DL), Feature mapping, Micro-Doppler spectrogram (μ-DS), Passive WiFi radar (PWR), Variational autoencoder (VAE)
0196-2892
Tang, Chong
9409c6d1-69d2-4598-8b43-bbb7f51f6fe2
Li, Wenda
3a3026d2-6265-4fb9-9b4e-22082087909e
Vishwakarma, Shelly
c98f51e0-a07e-4b21-becd-75d7249643ea
Shi, Fangzhan
4272572e-25fa-4e77-be3e-953400f2278e
Julier, Simon J.
235e7de9-827e-4fb8-bc04-46e93136ac43
Chetty, Kevin
324e29d3-cdf5-4e2b-9b78-5fad57f4e4d0
Tang, Chong
9409c6d1-69d2-4598-8b43-bbb7f51f6fe2
Li, Wenda
3a3026d2-6265-4fb9-9b4e-22082087909e
Vishwakarma, Shelly
c98f51e0-a07e-4b21-becd-75d7249643ea
Shi, Fangzhan
4272572e-25fa-4e77-be3e-953400f2278e
Julier, Simon J.
235e7de9-827e-4fb8-bc04-46e93136ac43
Chetty, Kevin
324e29d3-cdf5-4e2b-9b78-5fad57f4e4d0

Tang, Chong, Li, Wenda, Vishwakarma, Shelly, Shi, Fangzhan, Julier, Simon J. and Chetty, Kevin (2022) FMNet: latent feature-wise mapping network for cleaning up noisy micro-doppler spectrogram. IEEE Transactions on Geoscience and Remote Sensing, 60. (doi:10.1109/TGRS.2021.3121211).

Record type: Article

Abstract

Micro-Doppler signatures contain considerable information about target dynamics. However, the radar sensing systems are easily affected by noisy surroundings, resulting in uninterpretable motion patterns on the micro-Doppler spectrogram (μ -DS). Meanwhile, radar returns often suffer from multipath, clutter, and interference. These issues lead to difficulty in, for example, motion feature extraction and activity classification using micro-Doppler signatures. In this article, we propose a latent feature-wise mapping strategy, called feature mapping network (FMNet), to transform measured spectrograms so that they more closely resemble the output from a simulation under the same conditions. Based on measured spectrogram and the matched simulated data, our framework contains three parts: an encoder which is used to extract latent representations/features, a decoder outputs reconstructed spectrogram according to the latent features, and a discriminator minimizes the distance of latent features of measured and simulated data. We demonstrate the FMNet with six activities data and two experimental scenarios, and final results show strong enhanced patterns and can keep actual motion information to the greatest extent. On the other hand, we also propose a novel idea which trains a classifier with only simulated data and predicts new measured samples after cleaning them up with the FMNet. From final classification results, we can see significant improvements.

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More information

Published date: 2022
Additional Information: Publisher Copyright: © 1980-2012 IEEE.
Keywords: Activity classification, Adversarial autoencoder (AAE), Deep learning (DL), Feature mapping, Micro-Doppler spectrogram (μ-DS), Passive WiFi radar (PWR), Variational autoencoder (VAE)
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Identifiers

Local EPrints ID: 503400
URI: http://eprints.soton.ac.uk/id/eprint/503400
DOI: doi:10.1109/TGRS.2021.3121211
ISSN: 0196-2892
PURE UUID: c44abd4e-8416-4397-9801-0660ad0fd431
ORCID for Shelly Vishwakarma: ORCID iD orcid.org/0000-0003-1035-3259

Catalogue record

Date deposited: 30 Jul 2025 16:52
Last modified: 31 Jul 2025 02:03

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Contributors

Author: Chong Tang
Author: Wenda Li
Author: Shelly Vishwakarma ORCID iD
Author: Fangzhan Shi
Author: Simon J. Julier
Author: Kevin Chetty

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