- New
-
Topics
- All Categories
- Metaphysics and Epistemology
- Value Theory
- Science, Logic, and Mathematics
- Science, Logic, and Mathematics
- Logic and Philosophy of Logic
- Philosophy of Biology
- Philosophy of Cognitive Science
- Philosophy of Computing and Information
- Philosophy of Mathematics
- Philosophy of Physical Science
- Philosophy of Social Science
- Philosophy of Probability
- General Philosophy of Science
- Philosophy of Science, Misc
- History of Western Philosophy
- Philosophical Traditions
- Philosophy, Misc
- Other Academic Areas
- Journals
- Submit material
- More
Learning How to Generalize
Cognitive Science 43 (8):e12777 (2019)
Abstract
Generalization is a fundamental problem solved by every cognitive system in essentially every domain. Although it is known that how people generalize varies in complex ways depending on the context or domain, it is an open question how people learn the appropriate way to generalize for a new context. To understand this capability, we cast the problem of learning how to generalize as a problem of learning the appropriate hypothesis space for generalization. We propose a normative mathematical framework for learning how to generalize by learning inductive biases for which properties are relevant for generalization in a domain from the statistical structure of features and concepts observed in that domain. More formally, the framework predicts that an ideal learner should learn to generalize by either taking the weighted average of the results of generalizing according to each hypothesis space, with weights given by how well each hypothesis space fits the previously observed concepts, or by using the most likely hypothesis space. We compare the predictions of this framework to human generalization behavior with three experiments in one perceptual (rectangles) and two conceptual (animals and numbers) domains. Across all three studies we find support for the framework's predictions, including individual‐level support for averaging in the third study.Author's Profile
My notes
Similar books and articles
Using Category Structures to Test Iterated Learning as a Method for Identifying Inductive Biases.Thomas L. Griffiths, Brian R. Christian & Michael L. Kalish - 2008 - Cognitive Science 32 (1):68-107.
Novelty and Inductive Generalization in Human Reinforcement Learning.Samuel J. Gershman & Yael Niv - 2015 - Topics in Cognitive Science 7 (3):391-415.
Sampling Assumptions in Inductive Generalization.Daniel J. Navarro, Matthew J. Dry & Michael D. Lee - 2012 - Cognitive Science 36 (2):187-223.
Apragatic Bayesian Platform for Automating Scientific Induction.Kevin B. Korb - 1992 - Dissertation, Indiana University
The Role of Explanation in Discovery and Generalization: Evidence From Category Learning.Joseph J. Williams & Tania Lombrozo - 2010 - Cognitive Science 34 (5):776-806.
Logically reliable inductive inference.Oliver Schulte - 2007 - In Friend Michele, Goethe Norma B. & Harizanov Valentina (eds.), Induction, algorithmic learning theory, and philosophy. Springer. pp. 157-178.
Rational statistical inference: A critical component for word learning.Fei Xu & Joshua B. Tenenbaum - 2001 - Behavioral and Brain Sciences 24 (6):1123-1124.
Evolving to Generalize: Trading Precision for Speed.Cailin O’Connor - 2017 - British Journal for the Philosophy of Science 68 (2).
Modeling Cross-Domain Causal Learning in Preschoolers as Bayesian Inference.Bonawitz Elizabeth Baraff, L. Griffiths Thomas & Schulz Laura - unknown
Non‐Bayesian Noun Generalization in 3‐ to 5‐Year‐Old Children: Probing the Role of Prior Knowledge in the Suspicious Coincidence Effect. [REVIEW]Gavin W. Jenkins, Larissa K. Samuelson, Jodi R. Smith & John P. Spencer - 2015 - Cognitive Science 39 (2):268-306.
Learning the Form of Causal Relationships Using Hierarchical Bayesian Models.Christopher G. Lucas & Thomas L. Griffiths - 2010 - Cognitive Science 34 (1):113-147.
Language Evolution by Iterated Learning With Bayesian Agents.Thomas L. Griffiths & Michael L. Kalish - 2007 - Cognitive Science 31 (3):441-480.
The complexity of learning SUBSEQ(A).Stephen Fenner, William Gasarch & Brian Postow - 2009 - Journal of Symbolic Logic 74 (3):939-975.
Generalization, similarity, and bayesian inference.Joshua B. Tenenbaum & Thomas L. Griffiths - 2001 - Behavioral and Brain Sciences 24 (4):629-640.
What Mechanisms Underlie Implicit Statistical Learning? Transitional Probabilities Versus Chunks in Language Learning.Pierre Perruchet - 2019 - Topics in Cognitive Science 11 (3):520-535.
Analytics
Added to PP
2019-08-18
Downloads
16 (#903,096)
6 months
3 (#965,065)
2019-08-18
Downloads
16 (#903,096)
6 months
3 (#965,065)
Historical graph of downloads
Author's Profile
Citations of this work
Refining the Bayesian Approach to Unifying Generalisation.Nina Poth - 2022 - Review of Philosophy and Psychology (3):1-31.
Refining the Bayesian Approach to Unifying Generalisation.Nina Poth - 2023 - Review of Philosophy and Psychology 14 (3):877-907.
Same but Different: Providing a Probabilistic Foundation for the Feature-Matching Approach to Similarity and Categorization.Nina Poth - forthcoming - Erkenntnis:1-25.
Learning to Learn Functions.Michael Y. Li, Fred Callaway, William D. Thompson, Ryan P. Adams & Thomas L. Griffiths - 2023 - Cognitive Science 47 (4):e13262.
References found in this work
Fact, Fiction, and Forecast.The Philosophy of Nature.Edward H. Madden, Nelson Goodman & Andrew G. Van Melsen - 1955 - Philosophy and Phenomenological Research 16 (2):271.
ALCOVE: An exemplar-based connectionist model of category learning.John K. Kruschke - 1992 - Psychological Review 99 (1):22-44.
Categories and induction in young children.Susan A. Gelman & Ellen M. Markman - 1986 - Cognition 23 (3):183-209.
PhilPapers logo by Andrea Andrews and Meghan Driscoll.
This site uses cookies and Google Analytics (see our terms & conditions for details regarding the privacy implications). Use of this site is subject to terms & conditions.
All rights reserved by The PhilPapers Foundation
Server: philpapers-web-64dd777598-vk9kt uwo