Plug-and-Play Regularization on Magnitude for 3D Near-Field MIMO Imaging

The proposed learning-based approach can be adapted for other imaging technologies by adjusting the network architecture and training data to suit the specific characteristics of the new imaging modality. For instance, in medical imaging applications such as MRI or CT scans, the input data format and noise characteristics may differ from radar imaging. Therefore, the deep denoiser network would need to be trained on relevant datasets that mimic the noise patterns and image structures typical of medical images. Additionally, different regularization functions may need to be explored based on the unique properties of each imaging technology.

Enforcing regularization only on magnitudes in complex-valued reconstructions can have limitations in scenarios where phase information is crucial for accurate reconstruction. In some applications, such as SAR imaging or materials characterization using radar signals, phase information carries important details about object properties that cannot be captured solely through magnitude regularization. Ignoring phase information entirely could lead to loss of critical features in the reconstructed images and potentially degrade overall performance. Additionally, enforcing regularization only on magnitudes might not fully exploit all available prior knowledge about complex-valued reflectivity distributions. Complex-valued data contain both amplitude (magnitude) and phase components that are inherently linked; neglecting one aspect during reconstruction could result in suboptimal solutions.

Advancements in deep learning are expected to significantly impact the future development of plug-and-play reconstruction methods by enhancing their adaptability and performance across various applications: Improved Denoising Capabilities: Deep learning techniques enable more sophisticated denoisers with enhanced ability to learn complex patterns from noisy data. This leads to better restoration of high-quality images even from highly corrupted measurements. Enhanced Generalization: Deep neural networks have shown remarkable generalization capabilities when trained on diverse datasets. This allows plug-and-play methods utilizing deep priors to perform well across a wide range of imaging scenarios without extensive fine-tuning. Efficient Training Procedures: Advances in optimization algorithms and hardware acceleration make it easier to train deep networks efficiently, reducing computational costs associated with developing plug-and-play frameworks based on learned priors. Incorporation of Domain-Specific Knowledge: Deep learning models can incorporate domain-specific knowledge through transfer learning or specialized architectures tailored for specific tasks within plug-and-play frameworks.