FPGA-Based Machine Learning: Platforms, Applications, Design Considerations, Challenges, and Future Directions

Abstract

Field-Programmable Gate Arrays (FPGAs) have emerged as a promising platform for accelerating machine learning tasks due to their high parallelism, low latency, and hardware customization ability. In this paper, the authors provide an overview of popular FPGA platforms for machine learning and compare the tradeoffs among FPGAs, GPUs, and CPUs for machine learning. The authors also present specific applications of machine learning based on FPGAs, including those in autonomous driving and healthcare. Additionally, the paper explores FPGA design considerations, such as architecture, resource utilization, and power consumption. Nonetheless, obstacles persist in the realm of FPGA-based machine learning that require attention. Identifying the ideal balance between adaptability and performance, considering factors such as space, energy usage, and latency, is still challenging. As the capabilities of FPGAs expand, there is a significant need for devices that have a smaller footprint, reduced power consumption, and minimized delays. The paper emphasizes the necessity of ongoing research in the field of FPGA-based machine learning to address these issues and continue enhancing the performance and effectiveness of machine learning systems.