Abstract
A dynamical system can be regarded as an information processing apparatus that encodes input streams from the external environment to its state and processes them through state transitions. The information processing capacity (IPC) is an excellent tool that comprehensively evaluates these processed inputs, providing details of unknown information processing in black box systems; however, this measure can be applied to only time-invariant systems. This paper extends the applicable range to time-variant systems and further reveals that the IPC is equivalent to coefficients of polynomial chaos (PC) expansion in more general dynamical systems. To achieve this objective, we tackle three issues. First, we establish a connection between the IPC for time-invariant systems and PC expansion, which is a type of polynomial expansion using orthogonal functions of input history as bases. We prove that the IPC corresponds to the squared norm of the coefficient vector of the basis in the PC expansion. Second, we show that an input following an arbitrary distribution can be used for the IPC, removing previous restrictions to specific input distributions. Third, we extend the conventional orthogonal bases to functions of both time and input history and propose the IPC for time-variant systems. To show the significance of our approach, we demonstrate that our measure can reveal information representations in not only machine learning networks but also a real, cultured neural network. Our generalized measure paves the way for unveiling the information processing capabilities of a wide variety of physical dynamics which has been left behind in nature.
Highlights
Dynamical systems driven by external stimuli can be universally found in nature, especially in biology
To illustrate that various orthogonal polynomials can be used as target outputs for the information processing capacity (IPC), we examine the total capacities for eight target Generalized polynomial chaos (gPC) and four target arbitrary polynomial chaos (aPC) using a one-dimensional echo state network (ESN)
Note that the total temporal information processing capacity (TIPC) is composed of Ctot,1 = 1.952 and Ctot,2 = 3.45 × 10−2, which are computed from Eq (43) by replacing the polynomial chaos (PC) z(i) to the time-dependent polynomial chaos (TDPC) ξ(i). These results suggest that the information processing that was lacking with conventional IPC can be measured by adding time-varying bases, and the total TIPC can reach the rank even if the system does not hold the echo state property (ESP)
Summary
Dynamical systems driven by external stimuli can be universally found in nature, especially in biology. Reservoir computing (RC) [2,3,4,5] is a bioinspired information processing paradigm that capitalizes on this dynamical perspective and has been widely utilized in various fields in recent years [6,7,8,9,10,11,12,13]. Let the number of nodes in a reservoir and its external input be N and ut , respectively, and the ith
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