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Introduction to probabilistic models of cognition

Introduction to probabilistic models of cognition. Josh Tenenbaum MIT. Why probabilistic models of cognition?. The fundamental problem of cognition. How does the mind get so much out of so little?

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Introduction to probabilistic models of cognition

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  1. Introduction to probabilistic models of cognition Josh Tenenbaum MIT

  2. Why probabilistic models of cognition?

  3. The fundamental problem of cognition How does the mind get so much out of so little? How do we make inferences, generalizations, models, theories and decisions about the world from impoverished (sparse, incomplete, noisy) data? “The problem of induction”

  4. Visual perception (Marr)

  5. Ambiguity in visual perception • Goal of visual perception is to recover world structure from visual images. • Why the problem is hard: many world structures can produce the same visual input. • Illusions reveal the visual system’s implicit knowledge of the physical world and the processes of image formation. (Shepard)

  6. Learning concepts from examples “horse” “horse” “horse”

  7. “tufa” “tufa” “tufa” Learning concepts from examples

  8. Causal inference cold 1 week cold 1 week Don’t press this button! drug 5 1 no drug 2 6 Does this drug help you get over a cold faster?

  9. Causal inference cold 1 week cold 1 week Don’t press this button! drug 5 1 no drug 2 6 Does this drug help you get over a cold faster?

  10. Language • Parsing: • Two cars were reported stolen by the Groveton police yesterday. • The judge sentenced the killer to die in the electric chair for the second time. • No one was injured in the blast, which was attributed to a buildup of gas by one town official. • One witness told the commissioners that she had seen sexual intercourse taking place between two parked cars in front of her house. (Pinker)

  11. Language • Parsing • Acquisition: • Learning the English past tense (rule vs. exceptions) • Learning the Spanish or Arabic past tense (multiple rules plus exceptions) • Learning verb argument structure (“give” vs. “donate”) • Learning to be bilingual.

  12. Intuitive theories • Physics • Parsing: Inferring support relations, or the causal history and properties of an object. • Acquisition: Learning about gravity and support. • Gravity -- what’s that? • Contact is sufficient • Mass distribution and location is important • Psychology • Parsing: Inferring beliefs, desires, plans. • Acquisition: Learning about agents. • Recognizing intentionality, but without mental state reasoning • Reasoning about beliefs and desires • Reasoning about plans, rationality and “other minds”.

  13. The big questions 1. How does knowledge guide inductive learning, inference, and decision-making from sparse, noisy or ambiguous data? 2. What are the forms and contents of our knowledge of the world? 3. How is that knowledge itself learned from experience? 4. When faced with surprising data, when do we assimilate the data to our current model versus accommodate our model to the new data? 5. How can accurate inductive inferences be made efficiently, even in the presence of complex hypothesis spaces?

  14. A toolkit for answering these questions • Bayesian inference in probabilistic generative models • Probabilities defined over structured representations: graphs, grammars, predicate logic, schemas • Hierarchical probabilistic models, with inference at all levels of abstraction • Adaptive nonparametric or “infinite” models, which can grow in complexity or change form in response to the observed data. • Approximate methods of learning and inference, such as belief propagation, expectation-maximization (EM), Markov chain Monte Carlo (MCMC), and sequential Monte Carlo (particle filtering).

  15. Grammar G P(S | G) Phrase structure S P(U | S) Utterance U P(S | U, G) ~P(U | S) xP(S | G) Bottom-up Top-down

  16. P(grammar | UG) P(phrase structure | grammar) P(utterance | phrase structure) P(speech | utterance) “Universal Grammar” Hierarchical phrase structure grammars (e.g., CFG, HPSG, TAG) Grammar Phrase structure Utterance Speech signal

  17. Vision as probabilistic parsing (Han and Zhu, 2006)

  18. Learning word meanings Whole-object principle Shape bias Taxonomic principle Contrast principle Basic-level bias Principles Structure Data

  19. Causal learning and reasoning Principles Structure Data

  20. Goal-directed action (production and comprehension) (Wolpert et al., 2003)

  21. Why probabilistic models of cognition? • A framework for understanding how the mind can solve fundamental problems of induction. • Strong, principled quantitative models of human cognition. • Tools for studying people’s implicit knowledge of the world. • Beyond classic limiting dichotomies: “structure vs. statistics”, “nature vs. nurture”, “domain-general vs. domain-specific” . • A unifying mathematical language for all of the cognitive sciences: AI, machine learning and statistics, psychology, neuroscience, philosophy, linguistics…. A bridge between engineering and “reverse-engineering”. Why now? Much recent progress, in computational resources, theoretical tools, and interdisciplinary connections.

  22. Summer school plan • Weekly plan • Week 1: Basic probabilistic models. Applications to visual perception, categorization, causal learning. • Week 2: More advanced probabilistic models (grammars, logic, MDPs). Applications to reasoning, language, scene understanding, decision-making, neuroscience. • Week 3: Further applications to memory, motor control, sensory integration, unsupervised learning and cognitive development. Symposia on open challenges and student research.

  23. Summer school plan • Daily plan • 5 (or 6) lectures per day. • Starting Wednesday, break-out sessions after lunch, for discussion with speakers. • Evening tutorials: Matlab, Probability basics, Bayes net toolbox (for matlab), SamIam, BUGS, Markov logic networks and Alchemy. • Psych computer lab (available afternoons). • Self-organizing activities: Sign up for calendar on 30boxes.com: Email address: ipam.summerschool07@gmail.com Password: “ipam07”

  24. Background poll • Bayes’ rule • Conjugate prior • Bayesian network • Plate notation for graphical models • Mixture model • Hidden Markov model • Expectation-maximization (EM) algorithm • Dynamic programming • Gaussian processes • Dirichlet processes • First-order logic • (Stochastic) context-free grammar • Probabilistic relational models • MCMC • Particle filtering • Partially observable Markov decision process • Serotonin

  25. Poll for tonight • Matlab tutorial? • Probability basics?

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