Priscila C. Holanda, C. Reinbrecht, G. Bontorin, Vitor V. Bandeira, R. Reis
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引用次数: 10
Abstract
Understanding and modeling the brain is one of the key scientific challenges in the twenty-first century, and a grown effort is rising on a global scale. Due to its high parallelism, the hardware implementation of large-scale spiking neural networks (SNNs) promises superior execution speed compared to sequential software approaches. Such systems can significantly benefit from the use of networks-on-chip(NoC), as they scale very well concerning area, performance, power/energy consumption, and overall design effort. We developed a hierarchical network-on-chip for a hardware SNN architecture to improve the communication and scalability of the system. The architecture was implemented in an Altera Stratix IV FPGA, and a logic synthesis was performed to evaluate the system, achieving an area of 0.23mm2 and a power dissipation of 147mW for a 256 neurons implementation.
对大脑的理解和建模是21世纪最重要的科学挑战之一,在全球范围内,这方面的努力正在不断加强。由于其高并行性,与顺序软件方法相比,大规模峰值神经网络(snn)的硬件实现保证了更高的执行速度。这样的系统可以从使用片上网络(NoC)中获得显著的好处,因为它们在面积、性能、功耗/能耗和总体设计方面都可以很好地扩展。我们为硬件SNN架构开发了一种分层片上网络,以改善系统的通信和可扩展性。该架构在Altera Stratix IV FPGA上实现,并进行了逻辑综合来评估系统,实现了256个神经元的面积为0.23mm2,功耗为147mW。
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