Accelerated and Highly Correlated ASIC Synthesis of AI Hardware Subsystems Using CGP

IF 1.1 4区 计算机科学 Q4 COMPUTER SCIENCE, HARDWARE & ARCHITECTURE
H. C. Prashanth, Madhav Rao
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引用次数: 0

Abstract

Unconventional functions, including activation functions and power functions, are extremely hard-to-realize primarily due to the difficulty in arriving at the hierarchical design. The hierarchical design allows the synthesis tool to map the functionality with that of standard cells employed through the regular ASIC synthesis flow. For conventional functions, the hierarchical design is structured and then supplied to the synthesis flow, whereas, for unconventional functions, the same method is not reliable, since the current synthesis method does not offer any design-space exploration scheme to arrive at an easy-to-realize design entity. The unconventional functions either take a long synthesis run-time or additional efforts are spent in restructuring the hierarchical design for the desired function to synthesizable ones. Cartesian genetic programing (CGP) allows to not only incorporate custom logic gates for synthesizing the hierarchical design but also aids in the design-space exploration for the targeted function through the custom gates. The CGP configuration evolves difficult-to-realize complex functions with multiple solutions, and filtering through desired Pareto-optimal requirements offers a unique hierarchical design. Incorporating CGP-derived hierarchical designs into the traditional synthesis flow is instrumental for implementing and evaluating higher-order designs comprising nonlinear functional constructs. Six activation functions and power functions that fall in the category of unconventional functions are realized by the CGP method using custom cells to demonstrate the capability. Further, the hierarchical design of these unconventional functions is flattened and compared with the same function that is directly synthesized using basic gates. The CGP-derived synthesis method reports 3× less synthesis time for realizing the complex functions at the hierarchical level compared to the synthesis using basic gate cells. Hardware characteristics and error metrics are also investigated for the CGP realized complex functions and are made freely available for further usage to the research and designers’ community.

Abstract Image

使用 CGP 加速人工智能硬件子系统的高相关 ASIC 合成
包括激活函数和幂函数在内的非常规函数极难实现,这主要是由于难以实现分层设计。分层设计允许综合工具将功能与常规 ASIC 综合流程中使用的标准单元进行映射。对于常规功能,分层设计是结构化的,然后提供给综合流程,而对于非常规功能,同样的方法并不可靠,因为当前的综合方法并不提供任何设计空间探索方案来获得易于实现的设计实体。非常规功能要么需要很长的合成运行时间,要么需要花费额外的精力将所需功能的分层设计重组为可合成的功能。笛卡尔遗传编程(CGP)不仅可以在合成分层设计时加入定制逻辑门,还能通过定制门帮助探索目标功能的设计空间。CGP 配置可演化出具有多种解决方案的难以实现的复杂功能,并通过所需的帕累托最优要求进行筛选,从而提供独特的分层设计。将 CGP 衍生的分层设计纳入传统的合成流程,有助于实现和评估包含非线性功能结构的高阶设计。CGP 方法使用定制单元实现了属于非常规函数类别的六种激活函数和幂函数,以展示其能力。此外,这些非常规函数的分层设计被扁平化,并与使用基本门直接合成的相同函数进行了比较。与使用基本门单元的合成方法相比,CGP 衍生的合成方法在分层层次上实现复杂功能所需的合成时间减少了 3 倍。此外,还研究了 CGP 实现的复杂函数的硬件特性和误差指标,并免费提供给研究和设计人员社区进一步使用。
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来源期刊
IET Computers and Digital Techniques
IET Computers and Digital Techniques 工程技术-计算机:理论方法
CiteScore
3.50
自引率
0.00%
发文量
12
审稿时长
>12 weeks
期刊介绍: IET Computers & Digital Techniques publishes technical papers describing recent research and development work in all aspects of digital system-on-chip design and test of electronic and embedded systems, including the development of design automation tools (methodologies, algorithms and architectures). Papers based on the problems associated with the scaling down of CMOS technology are particularly welcome. It is aimed at researchers, engineers and educators in the fields of computer and digital systems design and test. The key subject areas of interest are: Design Methods and Tools: CAD/EDA tools, hardware description languages, high-level and architectural synthesis, hardware/software co-design, platform-based design, 3D stacking and circuit design, system on-chip architectures and IP cores, embedded systems, logic synthesis, low-power design and power optimisation. Simulation, Test and Validation: electrical and timing simulation, simulation based verification, hardware/software co-simulation and validation, mixed-domain technology modelling and simulation, post-silicon validation, power analysis and estimation, interconnect modelling and signal integrity analysis, hardware trust and security, design-for-testability, embedded core testing, system-on-chip testing, on-line testing, automatic test generation and delay testing, low-power testing, reliability, fault modelling and fault tolerance. Processor and System Architectures: many-core systems, general-purpose and application specific processors, computational arithmetic for DSP applications, arithmetic and logic units, cache memories, memory management, co-processors and accelerators, systems and networks on chip, embedded cores, platforms, multiprocessors, distributed systems, communication protocols and low-power issues. Configurable Computing: embedded cores, FPGAs, rapid prototyping, adaptive computing, evolvable and statically and dynamically reconfigurable and reprogrammable systems, reconfigurable hardware. Design for variability, power and aging: design methods for variability, power and aging aware design, memories, FPGAs, IP components, 3D stacking, energy harvesting. Case Studies: emerging applications, applications in industrial designs, and design frameworks.
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