E. Rietman, L. Schuum, Ayush Salik, M. Askenazi, H. Siegelmann
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引用次数: 0
摘要
Stephen Wolfram(2002)提出了计算等效的概念,这意味着几乎任何动力系统都可以被认为是一种计算,包括可编程物质和非线性材料,如所谓的量子物质。忆阻器常用于硬件神经网络的构建和评估。Ukil(2011)证明了压电材料和忆阻器之间的理论关系。在我们探索用于神经网络计算的压电材料之前,我们回顾了这项工作作为必要的背景。我们的方法包括使用立方块的未极化锆钛酸铅(PZT)陶瓷,我们在其上附加了用于编程PZT的电线作为可编程基板。然后,我们通过脉冲序列,构建了对准极化区域和未对准或无序区域的动态内部模式。这些动态模式是通过建设性和破坏性干扰产生的,可以作为一种油藏网络进行开发。使用MNIST数据,我们演示了一个学习机。
Machine Learning with Quantum Matter: An Example Using Lead Zirconate Titanate
Stephen Wolfram (2002) proposed the concept of computational equivalence, which implies that almost any dynamical system can be considered as a computation, including programmable matter and nonlinear materials such as, so called, quantum matter. Memristors are often used in building and evaluating hardware neural networks. Ukil (2011) demonstrated a theoretical relationship between piezoelectrical materials and memristors. We review that work as a necessary background prior to our work on exploring a piezoelectric material for neural network computation. Our method consisted of using a cubic block of unpoled lead zirconate titanate (PZT) ceramic, to which we have attached wires for programming the PZT as a programmable substrate. We then, by means of pulse trains, constructed on-the-fly internal patterns of regions of aligned polarization and unaligned, or disordered regions. These dynamic patterns come about through constructive and destructive interference and may be exploited as a type of reservoir network. Using MNIST data we demonstrate a learning machine.
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