迈向细胞骨架计算机。一个提议

From Parallel to Emergent Computing Pub Date : 2018-10-11 DOI:10.1201/9781315167084-26

A. Adamatzky, J. Tuszynski, Joerg Pieper, D. Nicolau, Rossalia Rinalndi, G. Sirakoulis, V. Erokhin, J. Schnauss, David M. Smith

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引用次数: 5

摘要

我们提出了一个路线图，以实验实现基于细胞骨架的计算设备。下面描述了一个总体概念。基于碰撞的细胞骨架计算机通过行进定位(AF/MT链上的电压孤子和AF/MT聚合波前)之间的相互作用实现逻辑门。细胞骨架网络通过可编程聚合生长。数据通过电子和光学手段输入AF/MT计算网络。数据信号在网络终端上传播定位(孤子、构象缺陷)。计算通过AF/MT网络结构门(分支点)的定位之间的碰撞来实现。计算结果以电和/或光的方式记录在蛋白质网络的输出端。作为额外的选择，光学I/O元件设想通过直接激发蛋白质网络和耦合荧光分子。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Towards Cytoskeleton Computers. A proposal

We propose a road-map to experimental implementation of cytoskeleton-based computing devices. An overall concept is described in the following. Collision-based cytoskeleton computers implement logical gates via interactions between travelling localisation (voltage solitons on AF/MT chains and AF/MT polymerisation wave fronts). Cytoskeleton networks are grown via programmable polymerisation. Data are fed into the AF/MT computing networks via electrical and optical means. Data signals are travelling localisations (solitons, conformational defects) at the network terminals. The computation is implemented via collisions between the localisations at structural gates (branching sites) of the AF/MT network. The results of the computation are recorded electrically and/or optically at the output terminals of the protein networks. As additional options, optical I/O elements are envisaged via direct excitation of the protein network and by coupling to fluorescent molecules.

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From Parallel to Emergent Computing

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