Litcius/Paper detail

Field-Programmable Gate Array Architecture for Deep Learning: Survey and Future Directions

Andrew Boutros, Aman Arora, Vaughn Betz

2025Proceedings of the IEEE10 citationsDOIOpen Access PDF

Abstract

Deep learning (DL) is becoming the cornerstone of numerous applications both in large-scale datacenters and at the edge. Specialized hardware is often necessary to meet the performance requirements of state-of-the-art DL models, but the rapid pace of change in DL models and the wide variety of systems integrating DL make it impossible to create custom computer chips for all but the largest markets. Field-programmable gate arrays (FPGAs) present a unique blend of reprogrammability and direct hardware execution that make them suitable for accelerating DL inference. They offer the ability to customize processing pipelines and memory hierarchies to achieve lower latency and higher energy efficiency compared to general-purpose central processing units (CPUs) and graphics processing units (GPUs), at a fraction of the development time and cost of custom chips. Their diverse and high-speed inputs/outputs (IOs) also enable directly interfacing the FPGA to the network and/or a variety of external sensors, making them suitable for both datacenter and edge use cases. As DL has become an ever more important workload, FPGA architectures are evolving to enable higher DL performance. In this article, we survey both academic and industrial <italic xmlns:mml="http://www.w3.org/1998/Math/MathML" xmlns:xlink="http://www.w3.org/1999/xlink">FPGA chip architecture</i> enhancements for DL. First, we give a brief introduction on the basics of FPGA architecture and how its components lead to strengths and weaknesses for DL applications. Next, we discuss different <italic xmlns:mml="http://www.w3.org/1998/Math/MathML" xmlns:xlink="http://www.w3.org/1999/xlink">design styles</i> of DL inference accelerators implemented on FPGAs that achieve state-of-the-art performance and productive development flows, ranging from model-specific dataflow styles to software-programmable overlay styles. We survey DL-specific enhancements to traditional FPGA building blocks including the logic blocks (LBs), arithmetic circuitry, and on-chip memories, as well as new DL-specialized blocks that integrate into the FPGA fabric to accelerate tensor computations. Finally, we discuss hybrid devices that combine processors and coarse-grained accelerator blocks with FPGA-like interconnect and networks-on-chip (NoCs), and highlight promising future research directions.

Topics & Concepts

Field-programmable gate arrayComputer scienceInterfacingComputer architectureEmbedded systemDataflowVariety (cybernetics)ArchitectureComputer hardwareDataflow architectureReconfigurable computingData processingGraphicsEmulationOverlayRendering (computer graphics)Efficient energy usePipeline (software)Design space explorationEdge deviceVHDLSystem on a chipScalabilityElectronic design automationEnhanced Data Rates for GSM EvolutionSignal processingLogic synthesisRangingProgramming paradigmPaceProgrammable logic deviceLatency (audio)BottleneckParallel processingLow latency (capital markets)Gate arrayPacket processingHigh-level synthesisChipAdvanced Neural Network ApplicationsAdvanced Memory and Neural ComputingEmbedded Systems Design Techniques
Field-Programmable Gate Array Architecture for Deep Learning: Survey and Future Directions | Litcius