Abstract
In this paper we present a very exciting overlap between emergent nanotechnology and neuroscience, which has been discovered by neuromorphic engineers. Specifically, we are linking one type of memristor nanotechnology devices to the biological synaptic update rule known as spike-time-dependent-plasticity (STDP) found in real biological synapses. Understanding this link allows neuromorphic engineers to develop circuit architectures that use this type of memristors to artificially emulate parts of the visual cortex. We focus on the type of memristors referred to as voltage or flux driven memristors and focus our discussions on a behavioral macro-model for such devices. The implementations result in fully asynchronous architectures with neurons sending their action potentials not only forward but also backward. One critical aspect is to use neurons that generate spikes of specific shapes. We will see how by changing the shapes of the neuron action potential spikes we can tune and manipulate the STDP learning rules for both excitatory and inhibitory synapses. We will see how neurons and memristors can be interconnected to achieve large scale spiking learning systems, that follow a type of multiplicative STDP learning rule. We will briefly extend the architectures to use three-terminal transistors with similar memristive behavior. We will illustrate how a V1 visual cortex layer can assembled and how it is capable of learning to extract orientations from visual data coming from a real artificial CMOS spiking retina observing real life scenes. Finally, we will discuss limitations of currently available memristors. The results presented are based on behavioral simulations and do not take into account non-idealities of devices and interconnects. The aim of this paper is to present, in a tutorial manner, an initial framework for the possible development of fully asynchronous STDP learning neuromorphic architectures exploiting two or three-terminal memristive type devices. All files used for the simulations are made available through the journal web site1.
Highlights
Neuromorphic engineering2 is a new interdisciplinary discipline that takes inspiration from biology, physics, mathematics, computer science, and engineering to design artificial neural systems, such as vision systems, head-eye systems, auditory processors, and autonomous robots, the physical architecture, and design principles of which are based on those of biological nervous systems
From the retina visual field of 128 × 128 pixels we cropped 324 non-overlapping patches of 7 × 7 pixels each, and concatenated all these events sequentially making a recording of 324 × 521 = 168804 s (47 h) with 19.6 million events. This concatenation was used for one training epoch, and we required a total of five epochs to observe convergence in the learned weights
10 Conclusion In this paper we have shown that STDP learning can be induced by the voltage/flux driven formulation of a memristor device
Summary
Neuromorphic engineering is a new interdisciplinary discipline that takes inspiration from biology, physics, mathematics, computer science, and engineering to design artificial neural systems, such as vision systems, head-eye systems, auditory processors, and autonomous robots, the physical architecture, and design principles of which are based on those of biological nervous systems. One example of this is the recent impact of fabricated memristor devices (Strukov et al, 2008; Borghetti et al, 2009; Jo et al, 2009, 2010), postulated since 1971 (Chua, 1971; Chua and Kang, 1976; Chua et al, 1987), thanks to research in nanotechnology electronics Another is the mechanism known as spike-timedependent-plasticity (STDP; Gerstner et al, 1993, 1996; Delorme et al, 2001; Rao and Sejnowski, 2001; Guyonneau et al, 2004; Porr and Wörgötter, 2004; Masquelier and Thorpe, 2007, 2010; Young, 2007; Finelli et al, 2008; Masquelier et al, 2008, 2009a,b; Weidenbacher and Neumann, 2008; Sjöström and Gerstner, 2010) which describes a neuronal synaptic learning mechanism that refines the traditional Hebbian synaptic plasticity proposed in 1949 (Hebb, 1949).
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