GSGP-硬件:利用 FPGA 实现几何语义遗传编程的瞬时符号回归

IF 1.7 3区 计算机科学 Q3 COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCE Genetic Programming and Evolvable Machines Pub Date : 2024-06-25 DOI:10.1007/s10710-024-09491-5
Yazmin Maldonado, Ruben Salas, Joel A. Quevedo, Rogelio Valdez, Leonardo Trujillo
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引用次数: 0

摘要

几何语义遗传编程(GSGP)为基于 GP 的学习提出了一个重要的改进方案,它结合了搜索运算符,可直接对父代的语义进行操作,并对子代的语义产生有界影响。这种方法将任何符号回归适合度景观都视为单模态函数,从而实现了更有方向性的搜索。此外,这种搜索方式显然可以更高效地实现,而不需要执行、评估或操作长度可变的句法模型。因此,该算法的高效实现方法已被开发出来,同时使用 CPU 和 GPU 处理。然而,当前的实现仍不适合实时学习或在资源有限的设备上学习,而随着物联网的不断发展以及对边缘高效分布式学习需求的增加,这种情况正变得越来越普遍。本文介绍了 GSGP 硬件,它是完全使用 VHDL 开发的 GSGP 全流水线并行设计,可在 FPGA 设备上实现。使用 Vivado AMD-Xilinx 进行综合和仿真,GSGP-Hardware 与最先进的 GPU 实现相比,在运行时间和 Gpops/s 方面的效率分别提高了近似三个和四个数量级。这是其他基于 FPGA 的遗传编程实现所无法达到的性能提升。这得益于 GSGP 演化模型的方式,通过对原始 GSGP 算法进行简单而强大的改进,实现了具有竞争力的精度。GSGP 硬件允许瞬时符号回归,为这一强大的遗传编程变体开辟了新的应用领域。
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GSGP-hardware: instantaneous symbolic regression with an FPGA implementation of geometric semantic genetic programming

Geometric Semantic Genetic Programming (GSGP) proposed an important enhancement to GP-based learning, incorporating search operators that operate directly on the semantics of the parents with bounded effects on the semantics of the offspring. This approach posed any symbolic regression fitness landscape as a unimodal function, allowing for more directed search. Moreover, it became evident that the search could be implemented in a much more efficient manner, that does not require the execution, evaluation or manipulation of variable length syntactic models. Hence, efficient implementations of this algorithm have been developed using both CPU and GPU processing. However, current implementations are still ill-suited for real-time learning, or learning on devices with limited resources, scenarios that are becoming more prevalent with the continued development of the Internet-of-Things and the increased need for efficient and distributed learning on the Edge. This paper presents GSGP-Hardware, a fully pipelined and parallel design of GSGP developed fully using VHDL, for implementation on FPGA devices. Using Vivado AMD-Xilinx for synthesis and simulation, GSGP-Hardware achieves an approximate improvement in efficiency, in terms of run time and Gpops/s, of three and four orders of magnitude, respectively, compared with the state-of-the-art GPU implementation. This is a performance increase that has not been achieved by other FPGA-based implementations of genetic programming. This is possible due to the manner in which GSGP evolves a model, and competitive accuracy is achieved by incorporating simple but powerful enhancements to the original GSGP algorithm. GSGP-Hardware allows for instantaneous symbolic regression, opening up new application domains for this powerful variant of genetic programming.

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来源期刊
Genetic Programming and Evolvable Machines
Genetic Programming and Evolvable Machines 工程技术-计算机:理论方法
CiteScore
5.90
自引率
3.80%
发文量
19
审稿时长
6 months
期刊介绍: A unique source reporting on methods for artificial evolution of programs and machines... Reports innovative and significant progress in automatic evolution of software and hardware. Features both theoretical and application papers. Covers hardware implementations, artificial life, molecular computing and emergent computation techniques. Examines such related topics as evolutionary algorithms with variable-size genomes, alternate methods of program induction, approaches to engineering systems development based on embryology, morphogenesis or other techniques inspired by adaptive natural systems.
期刊最新文献
Evolving code with a large language model Hga-lstm: LSTM architecture and hyperparameter search by hybrid GA for air pollution prediction A survey on dynamic populations in bio-inspired algorithms GSGP-hardware: instantaneous symbolic regression with an FPGA implementation of geometric semantic genetic programming Geometric semantic GP with linear scaling: Darwinian versus Lamarckian evolution
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