標題: A NUMERICALLY STABLE PIPELINE NET VLSI ARCHITECTURE FOR THE ISOMORPHIC HOPFIELD MODEL
作者: CHANG, PR
YEH, BF
交大名義發表
電信工程研究所
National Chiao Tung University
Institute of Communications Engineering
公開日期: 1-五月-1993
摘要: This correspondence presents a reconfigurable pipeline net VLSI architecture for implementing Hopfield neural models. It is known that the Hopfield models involve computing the hyperbolic trigonometric functions which are hard to be realized by digital VLSI architectures. In order to tackle such difficulty, a useful isomorphic nonlinear mapping is introduced to convert those hyperbolic trigonometric nonlinear functions into the simple second-order polynomial functions. Moreover, the isomorphic formulation provides the higher ability to decompose the problem into several independent tasks which can be assigned to a number of processors. Handling the digital realizations on the Hopfield model, the previous attemps were to use the technique based on the first-order approximation called Euler's method which has poor numerical stability and large truncation error. To find a numerical solution with a prescribed accuracy, one of the promising approaches is a combination of both a single-step Runge-Kutta method and a multistep predictor-corrector method which has a larger stability interval and is particularly suitable for parallel computation. Since the mixed-type procedure requires data broadcasting, common VLSI architectures with fixed connections cannot offer such flexible connectivities. A pipeline net VLSI architecture which is a programmable two-level pipelined and dynamically reconfigurable systolic array would be adopted as the design platform. The pipelining period and block pipelining period of the proposed architecture have the computational orders of O(1) and O(n), respectively, where n is the number of neurons.
URI: http://dx.doi.org/10.1109/78.215328
http://hdl.handle.net/11536/3034
ISSN: 1053-587X
DOI: 10.1109/78.215328
期刊: IEEE TRANSACTIONS ON SIGNAL PROCESSING
Volume: 41
Issue: 5
起始頁: 2013
結束頁: 2017
顯示於類別:期刊論文


文件中的檔案:

  1. A1993LC85400032.pdf

若為 zip 檔案,請下載檔案解壓縮後,用瀏覽器開啟資料夾中的 index.html 瀏覽全文。