Abstract
Ultrasound and radar signals are highly beneficial for medical imaging as they are non-invasive and non-ionizing. Traditional imaging techniques have limitations in terms of contrast and physical interpretation. Quantitative medical imaging can display various physical properties such as speed of sound, density, conductivity, and relative permittivity. This makes it useful for a wider range of applications, including improving cancer detection, diagnosing fatty liver, and fast stroke imaging. However, current quantitative imaging techniques that estimate physical properties from received signals, such as Full Waveform Inversion, are time-consuming and tend to converge to local minima, making them unsuitable for medical imaging. To address these challenges, we propose a neural network based on the physical model of wave propagation, which defines the relationship between the received signals and physical properties. Our network can reconstruct multiple physical properties in less than one second for complex and realistic scenarios, using data from only eight elements. We demonstrate the effectiveness of our approach for both radar and ultrasound signals.
Original language | English |
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Pages (from-to) | 1175-1190 |
Number of pages | 16 |
Journal | IEEE TRANSACTIONS ON COMPUTATIONAL IMAGING |
Volume | 10 |
Early online date | 2 Aug 2024 |
DOIs | |
State | Published - 2024 |
Keywords
- Deep learning
- full waveform inversion
- medical imaging
- model-based
- quantitative imaging
- radar
- ultrasound
All Science Journal Classification (ASJC) codes
- Computational Mathematics
- Signal Processing
- Computer Science Applications