利用显式积分法在 GPU 上加速模拟无源模拟电路

IF 1.8 3区 工程技术 Q3 ENGINEERING, ELECTRICAL & ELECTRONIC Circuits, Systems and Signal Processing Pub Date : 2024-07-16 DOI:10.1007/s00034-024-02780-5
Ginés Doménech-Asensi, Tom J. Kazmierski
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引用次数: 0

摘要

模拟电路由大量紧密耦合结构中的节点组成,由于其 CPU 仿真时间过长,给模拟电路带来了巨大挑战。这项工作描述了一种方法,通过将电路方程的空间状态表述与 GPU 等多核处理器上并行的显式积分方法相结合,来加快此类电路的仿真速度。虽然与隐式方法相比,显式技术的稳定性要求更小的积分步长,但所提出的方法采用了对最大允许步长的快速估算,以保证数值稳定性,从而缩短了复杂度不断增加的电路架构的仿真时间。此外,所提出的技术可以在多核架构上直接并行处理。我们用两个分别使用恒定系数和可变系数的示例来演示所提出的方法:一个 RLC 互联器和一个 MOS-C 网络,用于对中等分辨率图像进行高斯滤波。所获得的结果与并行版 SPICE 进行了比较,结果表明,根据电路的大小,瞬态仿真最多可提高两个数量级。
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Accelerated Simulation of Passive Analog Circuits Over GPU Using Explicit Integration Methods

Analog circuits composed by large number of nodes in a tightly coupled structure pose significant challenges due to their prohibitive CPU simulation time. This work describes a method to speed up the simulation of such circuits by means of the combination of space state formulation of circuit equations with explicit integration methods parallelized over a many-core processor such as a GPU. Although stability of explicit techniques require smaller integration steps compared to implicit methods, the proposed method employs a fast estimate of the maximum allowed step size to guarantee numerical stability, which yields a shorter simulation time for increasing complexity circuit architectures. Moreover, the proposed technique can be straightforward parallelized on a many core architecture. The proposed method is demonstrated with two examples using constant and variable coefficients respectively: an RLC interconnect and a MOS-C network to perform Gaussian filtering of medium resolution images. The results obtained have been compared to a parallel version of SPICE and show improvements up to two orders of magnitude for transient simulations depending of the circuit size.

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来源期刊
Circuits, Systems and Signal Processing
Circuits, Systems and Signal Processing 工程技术-工程:电子与电气
CiteScore
4.80
自引率
13.00%
发文量
321
审稿时长
4.6 months
期刊介绍: Rapid developments in the analog and digital processing of signals for communication, control, and computer systems have made the theory of electrical circuits and signal processing a burgeoning area of research and design. The aim of Circuits, Systems, and Signal Processing (CSSP) is to help meet the needs of outlets for significant research papers and state-of-the-art review articles in the area. The scope of the journal is broad, ranging from mathematical foundations to practical engineering design. It encompasses, but is not limited to, such topics as linear and nonlinear networks, distributed circuits and systems, multi-dimensional signals and systems, analog filters and signal processing, digital filters and signal processing, statistical signal processing, multimedia, computer aided design, graph theory, neural systems, communication circuits and systems, and VLSI signal processing. The Editorial Board is international, and papers are welcome from throughout the world. The journal is devoted primarily to research papers, but survey, expository, and tutorial papers are also published. Circuits, Systems, and Signal Processing (CSSP) is published twelve times annually.
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