The free energy principle for action and perception: A mathematical review

Buckley, Christopher L.; Kim, Chang Sub; McGregor, Simon; Seth, Anil K.

doi:10.1016/j.jmp.2017.09.004

Cited by 305 publications

(487 citation statements)

References 49 publications

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“…In that study, model-based estimates replicated key features of human duration estimates of the exact same videos, including biases related to scene type (busy city scenes estimated as longer that quiet office scenes, for example; see also 12,13 ). The model displayed conceptual similarities with the predictive processing account of perception wherein perception is proposed to operate as a function of both sensory predictions and current sensory stimulation, with perceptual content understood as the brain's "best guess" (Bayesian posterior) of the causes of current sensory input given the prior expectations or predictions [14][15][16][17][18] . However, this previous model 4 had only very simple "memory", in the form of content-less tokens marking the occurrence of salient events in perception.…”

Section: Introductionmentioning

confidence: 92%

A predictive processing model of episodic memory and time perception

Fountas

Sylaidi²,

Nikiforou

et al. 2020

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Human perception and experience of time is strongly affected by environmental context. When paying close attention to time, time experience seems to expand; when distracted from time, experience of time seems to contract. Contrasts in experiences like these are common enough to be exemplified in sayings like "time flies when you're having fun". Similarly, experience of time depends on the content of perceptual experience -more rapidly changing or complex perceptual scenes seem longer in duration than less dynamic ones. The complexity of interactions among stimulation, attention, and memory that characterise time experience is likely the reason that a single overarching theory of time perception has been difficult to achieve. In the present study we propose a framework that reconciles these interactions within a single model, built using the principles of the predictive processing approach to perception. We designed a neural hierarchical Bayesian system, functionally similar to human perceptual processing, making use of hierarchical predictive coding, short-term plasticity, spatio-temporal attention, and episodic memory formation and recall. A large-scale experiment with ∼ 13, 000 human participants investigated the effects of memory, cognitive load, and stimulus content on duration reports of natural scenes up to ∼ 1 minute long. Model-based estimates matched human reports, replicating key qualitative biases including differences by cognitive load, scene type, and judgement (prospective or retrospective). Our approach provides an end-to-end model of duration perception from natural stimulus processing to estimation and from current experience to recalling the past, providing a new understanding of this central aspect of human experience. Predictive processing neural architecture for perceptionAccording to (Bayesian) predictive processing theories, the brain is constantly updating its internal representations of the state of the world with new sensory information x 0 t (at time t) through the process of hierarchical probabilistic inference 14,17,19,20 . The resulting 'top-down' generative model is used to predict new states and simulate the outcome of prospective actions 21 . Comparing predicted against actual sensory signals gives rise to prediction errors ξ n t which, in most instantiations of predictive processing, are assumed to flow in a 'bottom-up' direction from the sensory periphery (n = 0), towards higher hierarchical levels n ∈ {1, 2, ..}. Numerous connections with neurophysiology have been made over the years, including proposals viewing predictive processing as the fundamental function of canonical microcircuits in the cortex 22 , or as the result of the interplay between competing oscillatory bands 23, 24 , as well as providing theoretical explanations for a wide range of cognitive and perceptual effects such as hallucinations 25 , autism 26 and schizophrenia 27 . In addition, this framework is uniquely qualified for studying the relation between perceptual change and human perception of time 4 , as i...

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Section: Introductionmentioning

confidence: 92%

A predictive processing model of episodic memory and time perception

Fountas

Sylaidi²,

Nikiforou

et al. 2020

Preprint

Self Cite

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“…Although there are multiple internal 39 dimensions which animals need to optimize, e.g. temperature (Buckley, Kim, McGregor, & Seth, 2017), 40 internal salt levels (Cone et al, 2016), etc., for simplicity, we will consider a single dimension of food 41 reserves. As there exists an optimal level of food reserves, an animal should only seek food resources, 42 if its reserves are below the optimum value.…”

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confidence: 99%

Dopamine role in learning and action inference

Bogacz

2019

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7This paper describes a framework for modelling dopamine function in the mammalian brain. In this 8 framework, dopaminergic neurons projecting to different parts of the striatum encode errors in 9predictions made by the corresponding systems within the basal ganglia. These prediction errors are 10 equal to differences between rewards and expectations in the goal-directed system, and to 11 differences between the chosen and habitual actions in the habit system. The prediction errors enable 12 learning about rewards resulting from actions and habit formation. During action planning, the 13 expectation of reward in the goal-directed system arises from formulating a plan to obtain that 14 reward. Thus dopaminergic neurons in this system provide feedback on whether the current motor 15plan is sufficient to obtain the available reward, and they facilitate action planning until a suitable plan 16 is found. Presented models account for dopaminergic responses during movements, effects of 17 dopamine depletion on behaviour, and make several experimental predictions. 18 the training progresses, the habit system learns to mimic the choices made by the goal-directed

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“…In this work we will not provide a complete derivation of the active inference scheme, referring to previous treatments [26,16,8] for more details. Here we will begin from the Laplace encoded variational free energy for a univariate case:…”

Section: Pid Controlmentioning

confidence: 99%

“…The constants within the free energy will not be discussed here since they play no role in the minimisation scheme we present. As previously shown [16,8], to minimise equation (3) we need to specify the agent's generative density P (ρ, µ x ) = P (ρ|µ x )P (µ x ) introducing a likelihood P (ρ|µ x ) and a prior P (µ x ) in terms of an agent's beliefs µ x . These probabilities can be specified by a generative model in the form of a state space model.…”

Section: Pid Controlmentioning

confidence: 99%

“…Probabilistic approaches to the study of living systems and cognition are becoming increasingly popular in the natural sciences. In particular for the brain sciences, theories inspired the Bayesian brain hypothesis such as predictive coding, the free energy principle and active inference have been used to explain mechanism of the brain and cognition including perception, action and higher order functions [14,32,30,21,11,27,7,8].…”

Section: Introductionmentioning

confidence: 99%

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A probabilistic interpretation of PID controllers using active inference

Baltieri

Buckley

2018

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Abstract. In the past few decades, probabilistic interpretations of brain functions have become widespread in cognitive science and neuroscience. The Bayesian brain hypothesis, predictive coding, the free energy principle and active inference are increasingly popular theories of cognitive functions that claim to unify understandings of life and cognition within general mathematical frameworks derived from information theory, statistical physics and machine learning. Furthermore, it has been argued that one such proposal, active inference, combines both information and control theory and has its roots in cybernetics studies of the brain. The connections between information and control theory have been discussed since the 1950's by scientists like Shannon and Kalman and have recently risen to prominence in modern stochastic optimal control theory. However, the implications of the confluence of these two theoretical frameworks for the biological sciences have been slow to emerge. Here we argue that if the active inference proposal is to be taken as a general process theory for biological systems, we need to consider how existing control theoretical approaches to biological systems relate to it. In this work we will focus on PID (Proportional-Integral-Derivative) controllers, one of the most common types of regulators employed in engineering and more recently used to explain behaviour in biological systems, e.g. chemotaxis in bacteria and amoebae or robust adaptation in biochemical networks. Using active inference, we derive a probabilistic interpretation of PID controllers, showing how they can fit a more general theory of life and cognition under the principle of (variational) free energy minimisation once we use only simple linear generative models.

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The free energy principle for action and perception: A mathematical review

Cited by 305 publications

References 49 publications

A predictive processing model of episodic memory and time perception

A predictive processing model of episodic memory and time perception

Dopamine role in learning and action inference

A probabilistic interpretation of PID controllers using active inference

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