TY - JOUR
T1 - MiPhDUO
T2 - microwave imaging via physics-informed deep unrolled optimization
AU - Zumbo, Sabrina
AU - Mandija, Stefano
AU - Isernia, Tommaso
AU - Bevacqua, Martina T.
N1 - Publisher Copyright:
© 2024 IOP Publishing Ltd.
PY - 2024/4
Y1 - 2024/4
N2 - Microwave imaging (MWI) is a non-invasive technique that can identify unknown scatterer objects’ features while offering advantages such as low cost and portable devices with respect to other imaging methods. However, MWI faces challenges in solving the underlying inverse scattering problem, which involves recovering target properties from its scattered fields. Existing methods include linearized and non-linear optimization approaches, but they have limitations respectively in terms of range of validity and computational complexity (in view of the possible occurrence of ‘false solutions’). In recent years, learning-based approaches have emerged as they can allow real-time imaging but usually lack generalizability and a direct connection to the underlying physics. This paper proposes a physics-informed approach that combines convolutional neural networks with physics-based calculations. It is based on a few cascaded operations, making use of the gradient of the relevant cost function, and successively improving the estimation of the unknown target. The proposed approach is assessed using simulated as well as experimental Fresnel data. The results show that the integration of physics with deep learning can contribute to improve reconstruction accuracy, generalizability, and computational efficiency in MWI.
AB - Microwave imaging (MWI) is a non-invasive technique that can identify unknown scatterer objects’ features while offering advantages such as low cost and portable devices with respect to other imaging methods. However, MWI faces challenges in solving the underlying inverse scattering problem, which involves recovering target properties from its scattered fields. Existing methods include linearized and non-linear optimization approaches, but they have limitations respectively in terms of range of validity and computational complexity (in view of the possible occurrence of ‘false solutions’). In recent years, learning-based approaches have emerged as they can allow real-time imaging but usually lack generalizability and a direct connection to the underlying physics. This paper proposes a physics-informed approach that combines convolutional neural networks with physics-based calculations. It is based on a few cascaded operations, making use of the gradient of the relevant cost function, and successively improving the estimation of the unknown target. The proposed approach is assessed using simulated as well as experimental Fresnel data. The results show that the integration of physics with deep learning can contribute to improve reconstruction accuracy, generalizability, and computational efficiency in MWI.
KW - convolutional neural network
KW - inverse problem
KW - inverse scattering problem
KW - microwave imaging
UR - http://www.scopus.com/inward/record.url?scp=85186697061&partnerID=8YFLogxK
U2 - 10.1088/1361-6420/ad2b99
DO - 10.1088/1361-6420/ad2b99
M3 - Article
AN - SCOPUS:85186697061
SN - 0266-5611
VL - 40
JO - Inverse Problems
JF - Inverse Problems
IS - 4
M1 - 045017
ER -