Abstract
Studies suggest that, within the hierarchical architecture, the topological higher level possibly represents the scenarios of the current sensory events with slower changing activities. They attempt to predict the neural activities on the lower level by relaying the predicted information after the scenario of the sensorimotor event has been determined. On the other hand, the incoming sensory information corrects such prediction of the events on the higher level by the fast‐changing novel or surprising signal. From this point, we propose a predictive hierarchical artificial neural network model that examines this hypothesis on neurorobotic platforms. It integrates the perception and action in the predictive coding framework. Moreover, in this neural network model, there are different temporal scales of predictions existing on different levels of the hierarchical predictive coding architecture, which defines the temporal memories in recording the events occurring. Also, both the fast‐ and the slow‐changing neural activities are modulated by the motor action. Therefore, the slow‐changing neurons can be regarded as the representation of the recent scenario which the sensorimotor system has encountered. The neurorobotic experiments based on the architecture were also conducted.
Highlights
In order to react and move adaptively, the system needs to be compensated by two means: firstly the system extrapolates the upcoming percept within the delayed time taken for the signal to travel between the various components of system; secondly, it plans ahead the upcoming events based on the contextual background, including its own perception and action, until it reaches the end of the sensorimotor loop
We propose a computational-feasible model using deep neural network, based on the predictive coding (PC) model to learn the datasets in the real world
Two experiments are conducted to investigate how the perception and action of the robots can be integrated in the predictive coding (PC) framework and how the hierarchical representation differ in different scenarios
Summary
Delays always exist in both biological and engineering systems. They are typically caused by the processing time in biological organs, electrical circuits, or computer programs. Noises, nonlinearities, delays, uncertainties, and redundancies are other factors that caused delays in the system. In order to react and move adaptively, the system needs to be compensated by two means: firstly the system extrapolates the upcoming percept within the delayed time taken for the signal to travel between the various components of system; secondly, it plans ahead the upcoming events based on the contextual background, including its own perception and action, until it reaches the end of the sensorimotor loop
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