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Main Authors: Xu, Bin, Banerjee, Ayan, Urooj, Midhat, Gupta, Sandeep K. S.
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2512.17941
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author Xu, Bin
Banerjee, Ayan
Urooj, Midhat
Gupta, Sandeep K. S.
author_facet Xu, Bin
Banerjee, Ayan
Urooj, Midhat
Gupta, Sandeep K. S.
contents Digital twins (DTs) can enable precision healthcare by continually learning a mathematical representation of patient-specific dynamics. However, mission critical healthcare applications require fast, resource-efficient DT learning, which is often infeasible with existing model recovery (MR) techniques due to their reliance on iterative solvers and high compute/memory demands. In this paper, we present a general DT learning framework that is amenable to acceleration on reconfigurable hardware such as FPGAs, enabling substantial speedup and energy efficiency. We compare our FPGA-based implementation with a multi-processing implementation in mobile GPU, which is a popular choice for AI in edge devices. Further, we compare both edge AI implementations with cloud GPU baseline. Specifically, our FPGA implementation achieves an 8.8x improvement in \text{performance-per-watt} for the MR task, a 28.5x reduction in DRAM footprint, and a 1.67x runtime speedup compared to cloud GPU baselines. On the other hand, mobile GPU achieves 2x better performance per watts but has 2x increase in runtime and 10x more DRAM footprint than FPGA. We show the usage of this technique in DT guided synthetic data generation for Type 1 Diabetes and proactive coronary artery disease detection.
format Preprint
id arxiv_https___arxiv_org_abs_2512_17941
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Accelerated Digital Twin Learning for Edge AI: A Comparison of FPGA and Mobile GPU
Xu, Bin
Banerjee, Ayan
Urooj, Midhat
Gupta, Sandeep K. S.
Distributed, Parallel, and Cluster Computing
Artificial Intelligence
Digital twins (DTs) can enable precision healthcare by continually learning a mathematical representation of patient-specific dynamics. However, mission critical healthcare applications require fast, resource-efficient DT learning, which is often infeasible with existing model recovery (MR) techniques due to their reliance on iterative solvers and high compute/memory demands. In this paper, we present a general DT learning framework that is amenable to acceleration on reconfigurable hardware such as FPGAs, enabling substantial speedup and energy efficiency. We compare our FPGA-based implementation with a multi-processing implementation in mobile GPU, which is a popular choice for AI in edge devices. Further, we compare both edge AI implementations with cloud GPU baseline. Specifically, our FPGA implementation achieves an 8.8x improvement in \text{performance-per-watt} for the MR task, a 28.5x reduction in DRAM footprint, and a 1.67x runtime speedup compared to cloud GPU baselines. On the other hand, mobile GPU achieves 2x better performance per watts but has 2x increase in runtime and 10x more DRAM footprint than FPGA. We show the usage of this technique in DT guided synthetic data generation for Type 1 Diabetes and proactive coronary artery disease detection.
title Accelerated Digital Twin Learning for Edge AI: A Comparison of FPGA and Mobile GPU
topic Distributed, Parallel, and Cluster Computing
Artificial Intelligence
url https://arxiv.org/abs/2512.17941