608 research outputs found
FireFly: A High-Throughput and Reconfigurable Hardware Accelerator for Spiking Neural Networks
Spiking neural networks (SNNs) have been widely used due to their strong
biological interpretability and high energy efficiency. With the introduction
of the backpropagation algorithm and surrogate gradient, the structure of
spiking neural networks has become more complex, and the performance gap with
artificial neural networks has gradually decreased. However, most SNN hardware
implementations for field-programmable gate arrays (FPGAs) cannot meet
arithmetic or memory efficiency requirements, which significantly restricts the
development of SNNs. They do not delve into the arithmetic operations between
the binary spikes and synaptic weights or assume unlimited on-chip RAM
resources by using overly expensive devices on small tasks. To improve
arithmetic efficiency, we analyze the neural dynamics of spiking neurons,
generalize the SNN arithmetic operation to the multiplex-accumulate operation,
and propose a high-performance implementation of such operation by utilizing
the DSP48E2 hard block in Xilinx Ultrascale FPGAs. To improve memory
efficiency, we design a memory system to enable efficient synaptic weights and
membrane voltage memory access with reasonable on-chip RAM consumption.
Combining the above two improvements, we propose an FPGA accelerator that can
process spikes generated by the firing neuron on-the-fly (FireFly). FireFly is
implemented on several FPGA edge devices with limited resources but still
guarantees a peak performance of 5.53TSOP/s at 300MHz. As a lightweight
accelerator, FireFly achieves the highest computational density efficiency
compared with existing research using large FPGA devices
A Memory-Centric Customizable Domain-Specific FPGA Overlay for Accelerating Machine Learning Applications
Low latency inferencing is of paramount importance to a wide range of real time and userfacing Machine Learning (ML) applications. Field Programmable Gate Arrays (FPGAs) offer unique advantages in delivering low latency as well as energy efficient accelertors for low latency inferencing. Unfortunately, creating machine learning accelerators in FPGAs is not easy, requiring the use of vendor specific CAD tools and low level digital and hardware microarchitecture design knowledge that the majority of ML researchers do not possess. The continued refinement of High Level Synthesis (HLS) tools can reduce but not eliminate the need for hardware-specific design knowledge. The designs by these tools can also produce inefficient use of FPGA resources that ultimately limit the performance of the neural network. This research investigated a new FPGA-based software-hardware codesigned overlay architecture that opens the advantages of FPGAs to the broader ML user community. As an overlay, the proposed design allows rapid coding and deployment of different ML network configurations and different data-widths, eliminating the prior barrier of needing to resynthesize each design. This brings important attributes of code portability over different FPGA families. The proposed overlay design is a Single-Instruction-Multiple-Data (SIMD) Processor-In-Memory (PIM) architecture developed as a programmable overlay for FPGAs. In contrast to point designs, it can be programmed to implement different types of machine learning algorithms. The overlay architecture integrates bit-serial Arithmetic Logic Units (ALUs) with distributed Block RAMs (BRAMs). The PIM design increases the size of arithmetic operations and on-chip storage capacity. User-visible inference latencies are reduced by exploiting concurrent accesses to network parameters (weights and biases) and partial results stored throughout the distributed BRAMs. Run-time performance comparisons show that the proposed design achieves a speedup compared to HLS-based or custom-tuned equivalent designs. Notably, the proposed design is programmable, allowing rapid design space exploration without the need to resynthesize when changing ML algorithms on the FPGA
Simulation and implementation of novel deep learning hardware architectures for resource constrained devices
Corey Lammie designed mixed signal memristive-complementary metal–oxide–semiconductor (CMOS) and field programmable gate arrays (FPGA) hardware architectures, which were used to reduce the power and resource requirements of Deep Learning (DL) systems; both during inference and training. Disruptive design methodologies, such as those explored in this thesis, can be used to facilitate the design of next-generation DL systems
A Survey of Graph Pre-processing Methods: From Algorithmic to Hardware Perspectives
Graph-related applications have experienced significant growth in academia
and industry, driven by the powerful representation capabilities of graph.
However, efficiently executing these applications faces various challenges,
such as load imbalance, random memory access, etc. To address these challenges,
researchers have proposed various acceleration systems, including software
frameworks and hardware accelerators, all of which incorporate graph
pre-processing (GPP). GPP serves as a preparatory step before the formal
execution of applications, involving techniques such as sampling, reorder, etc.
However, GPP execution often remains overlooked, as the primary focus is
directed towards enhancing graph applications themselves. This oversight is
concerning, especially considering the explosive growth of real-world graph
data, where GPP becomes essential and even dominates system running overhead.
Furthermore, GPP methods exhibit significant variations across devices and
applications due to high customization. Unfortunately, no comprehensive work
systematically summarizes GPP. To address this gap and foster a better
understanding of GPP, we present a comprehensive survey dedicated to this area.
We propose a double-level taxonomy of GPP, considering both algorithmic and
hardware perspectives. Through listing relavent works, we illustrate our
taxonomy and conduct a thorough analysis and summary of diverse GPP techniques.
Lastly, we discuss challenges in GPP and potential future directions
Hardware Implementation of Deep Network Accelerators Towards Healthcare and Biomedical Applications
With the advent of dedicated Deep Learning (DL) accelerators and neuromorphic
processors, new opportunities are emerging for applying deep and Spiking Neural
Network (SNN) algorithms to healthcare and biomedical applications at the edge.
This can facilitate the advancement of the medical Internet of Things (IoT)
systems and Point of Care (PoC) devices. In this paper, we provide a tutorial
describing how various technologies ranging from emerging memristive devices,
to established Field Programmable Gate Arrays (FPGAs), and mature Complementary
Metal Oxide Semiconductor (CMOS) technology can be used to develop efficient DL
accelerators to solve a wide variety of diagnostic, pattern recognition, and
signal processing problems in healthcare. Furthermore, we explore how spiking
neuromorphic processors can complement their DL counterparts for processing
biomedical signals. After providing the required background, we unify the
sparsely distributed research on neural network and neuromorphic hardware
implementations as applied to the healthcare domain. In addition, we benchmark
various hardware platforms by performing a biomedical electromyography (EMG)
signal processing task and drawing comparisons among them in terms of inference
delay and energy. Finally, we provide our analysis of the field and share a
perspective on the advantages, disadvantages, challenges, and opportunities
that different accelerators and neuromorphic processors introduce to healthcare
and biomedical domains. This paper can serve a large audience, ranging from
nanoelectronics researchers, to biomedical and healthcare practitioners in
grasping the fundamental interplay between hardware, algorithms, and clinical
adoption of these tools, as we shed light on the future of deep networks and
spiking neuromorphic processing systems as proponents for driving biomedical
circuits and systems forward.Comment: Submitted to IEEE Transactions on Biomedical Circuits and Systems (21
pages, 10 figures, 5 tables
FPGA Acceleration of Domain-specific Kernels via High-Level Synthesis
L'abstract è presente nell'allegato / the abstract is in the attachmen
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