English

Edge Computing for Physics-Driven AI in Computational MRI: A Feasibility Study

Image and Video Processing 2025-06-05 v1 Artificial Intelligence Hardware Architecture Computer Vision and Pattern Recognition Machine Learning Medical Physics

Abstract

Physics-driven artificial intelligence (PD-AI) reconstruction methods have emerged as the state-of-the-art for accelerating MRI scans, enabling higher spatial and temporal resolutions. However, the high resolution of these scans generates massive data volumes, leading to challenges in transmission, storage, and real-time processing. This is particularly pronounced in functional MRI, where hundreds of volumetric acquisitions further exacerbate these demands. Edge computing with FPGAs presents a promising solution for enabling PD-AI reconstruction near the MRI sensors, reducing data transfer and storage bottlenecks. However, this requires optimization of PD-AI models for hardware efficiency through quantization and bypassing traditional FFT-based approaches, which can be a limitation due to their computational demands. In this work, we propose a novel PD-AI computational MRI approach optimized for FPGA-based edge computing devices, leveraging 8-bit complex data quantization and eliminating redundant FFT/IFFT operations. Our results show that this strategy improves computational efficiency while maintaining reconstruction quality comparable to conventional PD-AI methods, and outperforms standard clinical methods. Our approach presents an opportunity for high-resolution MRI reconstruction on resource-constrained devices, highlighting its potential for real-world deployment.

Keywords

Cite

@article{arxiv.2506.03183,
  title  = {Edge Computing for Physics-Driven AI in Computational MRI: A Feasibility Study},
  author = {Yaşar Utku Alçalar and Yu Cao and Mehmet Akçakaya},
  journal= {arXiv preprint arXiv:2506.03183},
  year   = {2025}
}

Comments

IEEE International Conference on Future Internet of Things and Cloud (FiCloud), 2025

R2 v1 2026-07-01T02:57:35.023Z