Predictive coding under the free-energy principle

Abstract: This paper considers prediction and perceptual categorization as an inference problem that is solved by the brain. We assume that the brain models the world as a hierarchy or cascade of dynamical systems that encode causal structure in the sensorium. Perception is equated with the optimization or inversion of these internal models, to explain sensory data. Given a model of how sensory data are generated, we can invoke a generic approach to model inversion, based on a free energy bound on the model's evidence. … Show more

“…It postulates that vision is a hierarchical process in which higher order areas shape and predict the tuning properties of lower level areas via strong feedback connections (Friston, 2005). This is achieved by suppressing the repeated or predicted, and hence redundant, neural responses in lower level areas that are consistent with the higher level expectations, resulting in a suppressed response of these neuronal populations and in an efficient encoding mechanism (Friston and Kiebel, 2009). …”

“…This discrepancy or residual prediction error signal (ε) is then forwarded to higher areas to re-estimate and update the predictions. The more closely a top-down prediction matches the incoming sensory input, the smaller the feed-forward ε is, which maximizes the "efficiency" of the CNS in the sense that the neural activity evoked by predicted stimuli is less than that evoked by novel and hence unexpected stimuli (Friston and Kiebel, 2009). According to PC accounts RS reflects the reduction of ε during subsequent bottom-up/top-down processing iterations within a hierarchical system (Kveraga et al, 2007): repeating a stimulus (or adapting to it) leads to its increased expectation and recalibrates the predictions such that the adapted stimulus evokes reduced ε, which leads to RS in an area.…”

Repetition probability effects for inverted faces

“…It postulates that vision is a hierarchical process in which higher order areas shape and predict the tuning properties of lower level areas via strong feedback connections (Friston, 2005). This is achieved by suppressing the repeated or predicted, and hence redundant, neural responses in lower level areas that are consistent with the higher level expectations, resulting in a suppressed response of these neuronal populations and in an efficient encoding mechanism (Friston and Kiebel, 2009). …”

“…This discrepancy or residual prediction error signal (ε) is then forwarded to higher areas to re-estimate and update the predictions. The more closely a top-down prediction matches the incoming sensory input, the smaller the feed-forward ε is, which maximizes the "efficiency" of the CNS in the sense that the neural activity evoked by predicted stimuli is less than that evoked by novel and hence unexpected stimuli (Friston and Kiebel, 2009). According to PC accounts RS reflects the reduction of ε during subsequent bottom-up/top-down processing iterations within a hierarchical system (Kveraga et al, 2007): repeating a stimulus (or adapting to it) leads to its increased expectation and recalibrates the predictions such that the adapted stimulus evokes reduced ε, which leads to RS in an area.…”

Repetition probability effects for inverted faces

“…To re-estimate and update predictions, ɛ is forwarded from lower to higher areas of the processing system. Consequently, surprising/incorrectly predicted events generate higher neural activity in comparison with correctly predicted events, maximizing the efficiency of neuronal processing (Friston, 2005(Friston, , 2010Friston & Kiebel, 2009). Summerfield et al, 2008 interpreted the enhanced magnitude of RS for expected stimuli as the reduced neuronal activity induced by a smaller ɛ (following Henson, 2003 claim of a link between RS and ɛ).…”

The contribution of surprise to the prediction based modulation of fMRI responses

“…These findings together suggest that the AIC coordinates the global cortical processing of surprising bodily stimuli by linking lower-level sensory regions to more attention and salience-related areas in the prefrontal and cingulate cortex during the processing of unexpected tactile changes. As discussed above, an interesting possible interpretation is that the AIC supports the emergence of a global workspace by directly monitoring and modulating the precision of these top-down and bottom-up inputs (Friston and Kiebel 2009;Bastos et al 2012). Future studies will benefit from directly manipulating tactile precision and deviancy in conjunction with computational modelling to address this question.…”

Evidence for embodied predictive coding: the anterior insula coordinates cortical processing of tactile deviancy