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Workshop on: The Free Energy Principle (Presented by the Wellcome Trust Centre for Neuroimaging) July 5 (Thursday) - 6 (

Workshop on: The Free Energy Principle (Presented by the Wellcome Trust Centre for Neuroimaging) July 5 (Thursday) - 6 (Friday) 2012. Free energy and active inference Karl Friston University College London. Abstract

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Workshop on: The Free Energy Principle (Presented by the Wellcome Trust Centre for Neuroimaging) July 5 (Thursday) - 6 (

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  1. Workshop on: The Free Energy Principle (Presented by the Wellcome Trust Centre for Neuroimaging) July 5 (Thursday) - 6 (Friday) 2012 Free energy and active inference Karl FristonUniversity College London Abstract How much about our interactions with – and experience of – our world can be deduced from basic principles? This talk reviews recent attempts to understand the self-organised behaviour of embodied agents, like ourselves, as satisfying basic imperatives for sustained exchanges with the environment. In brief, one simple driving force appears to explain many aspects of action and perception. This driving force is the minimisation of surprise or prediction error that – in the context of perception – corresponds to Bayes-optimal predictive coding (that suppresses exteroceptive prediction errors) and – in the context of action – reduces to classical motor reflexes (that suppress proprioceptive prediction errors). We will look at some of the implications for the anatomy of this active inference – in terms of large-scale anatomical graphs and canonical microcircuits – and then turn to some examples of active inference – such as the perceptual categorisation, action perception and visual searches. . .

  2. Overview The free-energy principleaction and perception predictive coding with reflexes The anatomy of inference graphical models canonical microcircuits Some examples perceptual categorization omission responses action observation visual searches

  3. “Objects are always imagined as being present in the field of vision as would have to be there in order to produce the same impression on the nervous mechanism” - von Helmholtz Hermann von Helmholtz Richard Gregory Geoffrey Hinton From the Helmholtz machine to the Bayesian brain and self-organization Thomas Bayes Richard Feynman Hermann Haken

  4. What is the difference between a snowflake and a bird? Phase-boundary temperature …a bird can act (to avoid surprises)

  5. The principle of least free energy (and minimising surprise) Maximum entropy principle Ergodic theorem Minimum entropy principle Self organisation and the principle of least action

  6. How can we minimize surprise (prediction error)? sensations – predictions Prediction error Change predictions Change sensations Action Perception …action and perception minimise free energy

  7. Action as inference – the “Bayesian thermostat” Posterior distribution Prior distribution Likelihood distribution 20 40 60 80 100 120 temperature Perception: Action:

  8. Overview The free-energy principleaction and perception predictive coding with reflexes The anatomy of inference graphical models canonical microcircuits Some examples perceptual categorization omission responses action observation visual searches

  9. Hidden states in the world Internal states of the agent Sensations Fluctuations Posterior expectations External states Action

  10. Free energy minimisation Generative model Predictive coding with reflexes

  11. Probabilistic graphical models Generative model Langevin form

  12. From models to perception A simple hierarchy Generative model Outward prediction stream Model inversion (inference) Expectations: Inward error stream Predictions: Prediction errors:

  13. Haeusler and Maass: Cereb. Cortex 2006;17:149-162 Canonical microcircuit for predictive coding Forward prediction error Backward predictions Forward prediction error Backward predictions

  14. David Mumford Predictive coding with reflexes oculomotor signals reflex arc proprioceptive input pons retinal input Prediction error (superficial pyramidal cells) occipital cortex geniculate Top-down or backward predictions Conditional predictions (deep pyramidal cells) Bottom-up or forward prediction error visual cortex

  15. Biological agents resist the second law of thermodynamics They must minimize their average surprise (entropy) They minimize surprise by suppressing prediction error (free-energy) Prediction error can be reduced by changing predictions (perception) Prediction error can be reduced by changing sensations (action) Perception entails recurrent message passing in the brain to optimize predictions Action makes predictions come true (and minimizes surprise)

  16. Overview The free-energy principleaction and perception predictive coding with reflexes The anatomy of inference graphical models canonical microcircuits Some examples perceptual categorization omission responses action observation visual searches

  17. Generating bird songs with attractors HVC Syrinx Sonogram Frequency causal states 0.5 1 1.5 time (sec) hidden states

  18. Predictive coding prediction and error 20 15 10 5 0 -5 10 20 30 40 50 60 Backward predictions causal states 20 15 stimulus 10 5000 5 4500 Forward prediction error 0 4000 -5 3500 -10 10 20 30 40 50 60 3000 hidden states 20 2500 2000 15 0.2 0.4 0.6 0.8 time (seconds) 10 5 0 -5 10 20 30 40 50 60

  19. Perceptual categorization Song a Song b Song c Frequency (Hz) time (seconds)

  20. Sequences of sequences Neuronal hierarchy Syrinx sonogram Frequency (KHz) 0.5 1 1.5 Time (sec)

  21. 4500 4000 3500 Frequency (Hz) 3000 stimulus (sonogram) without last syllable 2500 5000 omission and violation of predictions 4500 4000 3500 Frequency (Hz) 3000 percept percept 2500 0.5 1 1.5 0.5 1 1.5 Time (sec) Time (sec) ERP (error) with omission 100 100 50 50 Stimulus but no percept 0 0 LFP (micro-volts) LFP (micro-volts) Percept but no stimulus -50 -50 -100 -100 500 1000 1500 2000 500 1000 1500 2000 peristimulus time (ms) peristimulus time (ms)

  22. Overview The free-energy principleaction and perception predictive coding with reflexes The anatomy of inference graphical models canonical microcircuits Some examples perceptual categorization omission responses action observation visual searches

  23. Action as inference – the “Bayesian thermostat” Prior distribution 20 40 60 80 100 120 temperature Perception: Action:

  24. Action with point attractors visual input Exteroceptive predictions Descending proprioceptive predictions proprioceptive input

  25. Heteroclinic cycle (central pattern generator) Descending proprioceptive predictions action observation 0.4 0.6 0.8 position (y) 1 1.2 1.4 0 0.2 0.4 0.6 0.8 1 1.2 1.4 0 0.2 0.4 0.6 0.8 1 1.2 1.4 position (x) position (x)

  26. Overview The free-energy principleaction and perception predictive coding with reflexes The anatomy of inference graphical models canonical microcircuits Some examples perceptual categorization omission responses action observation visual searches

  27. Where do I expect to look?

  28. Sampling the world to minimise uncertainty stimulus visual input salience sampling Perception as hypothesis testing – saccades as experiments

  29. Hidden states in the world Internal states of the agent Sensations Fluctuations Posterior expectations Prior expectations External states Action

  30. Parietal (where) Frontal eye fields Visual cortex Pulvinar salience map Fusiform (what) oculomotor reflex arc Superior colliculus

  31. Saccadic eye movements Saccadic fixation and salience maps Hidden (oculomotor) states Visual samples Conditional expectations about hidden (visual) states And corresponding percept

  32. Thank you And thanks to collaborators: Rick Adams Andre Bastos Sven Bestmann Jean Daunizeau Harriet Brown Lee Harrison Stefan Kiebel James Kilner Jérémie Mattout Rosalyn Moran Will Penny Klaas Stephan And colleagues: Andy Clark Peter Dayan Jörn Diedrichsen Paul Fletcher Pascal Fries Geoffrey Hinton James Hopkins Jakob Hohwy Henry Kennedy Paul Verschure Florentin Wörgötter And many others

  33. Time-scale Free-energy minimisation leading to… Perception and Action: The optimisation of neuronal and neuromuscular activity to suppress prediction errors (or free-energy) based on generative models of sensory data. Learning and attention: The optimisation of synaptic gain and efficacy over seconds to hours, to encode the precisions of prediction errors and causal structure in the sensorium. This entails suppression of free-energy over time. Neurodevelopment: Model optimisation through activity-dependent pruning and maintenance of neuronal connections that are specified epigenetically Evolution: Optimisation of the average free-energy (free-fitness) over time and individuals of a given class (e.g., conspecifics) by selective pressure on the epigenetic specification of their generative models.

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