VS265: Syllabus: Difference between revisions
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==== Aug. 28: Introduction ==== | ==== Aug. 28: Introduction ==== | ||
* Theory and modeling in neuroscience | |||
* Goals of AI/machine learning vs. theoretical neuroscience | |||
* Turing vs. neural computation | |||
==== Sept. 2,4: Neuron models ==== | ==== Sept. 2,4: Neuron models ==== | ||
* Membrane equation, compartmental model of a neuron | |||
* Linear systems: vectors, matrices, linear neuron models | |||
* Perceptron model and linear separability | |||
==== Sept. 9,11: Guest lectures ==== | ==== Sept. 9,11: Guest lectures ==== | ||
* TBD | |||
* Paul Rhodes, Evolved Machines: Multi-compartment models; dendritic integration | |||
==== Sept. 16,18: Supervised learning ==== | ==== Sept. 16,18: Supervised learning ==== | ||
* Perceptron learning rule | |||
* Adaptation in linear neurons, Widrow-Hoff rule | |||
* Objective functions and gradient descent | |||
* Multilayer networks and backpropagation | |||
==== Sept. 23,25: Unsupervised learning ==== | ==== Sept. 23,25: Unsupervised learning ==== | ||
* Linear Hebbian learning and PCA, decorrelation | |||
* Winner-take-all networks and clustering | |||
==== Sept. 30: Guest lecture ==== | ==== Sept. 30: Guest lecture ==== | ||
* TBD | |||
==== Oct. 2: Sparse, distributed coding ==== | ==== Oct. 2: Sparse, distributed coding ==== | ||
* Autoencoders | |||
* Natural image statistics | |||
* Projection pursuit | |||
==== Oct. 7: Plasticity and cortical maps ==== | ==== Oct. 7: Plasticity and cortical maps ==== | ||
* Cortical maps | |||
* Self-organizing maps, Kohonen nets | |||
* Models of experience dependent learning and cortical reorganization | |||
==== Oct. 9: Guest lecture ==== | ==== Oct. 9: Guest lecture ==== | ||
* TBD | |||
==== Oct. 14: Manifold learning ==== | ==== Oct. 14: Manifold learning ==== | ||
* Local linear embedding, Isomap | |||
==== Oct. 16: Guest lecture ==== | ==== Oct. 16: Guest lecture ==== | ||
* Tom Dean, Google: Connectomics | |||
==== Oct. 21,23,28,30: Recurrent networks ==== | ==== Oct. 21,23,28,30: Recurrent networks ==== | ||
* Hopfield networks | |||
* Models of associative memory, pattern completion | |||
* Line attractors and `bump circuits’ | |||
* Dynamical models | |||
==== Nov. 4,6,13,18,20,25: Probabilistic models and inference ==== | ==== Nov. 4,6,13,18,20,25: Probabilistic models and inference ==== | ||
* Probability theory and Bayes’ rule | |||
* Learning and inference in generative models | |||
* The mixture of Gaussians model | |||
* Boltzmann machines | |||
* Sparse coding and ‘ICA’ | |||
* Kalman filter model | |||
* Energy-based models | |||
==== Dec. 2,4: Neural implementations ==== | ==== Dec. 2,4: Neural implementations ==== | ||
* Integrate-and-fire model | |||
* Neural encoding and decoding | |||
* Limits of precision in neurons | |||
* Neural synchrony and phase-based coding | |||
==== Dec. 9,11: Guest lectures ==== | ==== Dec. 9,11: Guest lectures ==== | ||
* TBD | |||
* TBD | |||
Revision as of 17:32, 1 September 2014
Syllabus
Aug. 28: Introduction
- Theory and modeling in neuroscience
- Goals of AI/machine learning vs. theoretical neuroscience
- Turing vs. neural computation
Sept. 2,4: Neuron models
- Membrane equation, compartmental model of a neuron
- Linear systems: vectors, matrices, linear neuron models
- Perceptron model and linear separability
Sept. 9,11: Guest lectures
- TBD
- Paul Rhodes, Evolved Machines: Multi-compartment models; dendritic integration
Sept. 16,18: Supervised learning
- Perceptron learning rule
- Adaptation in linear neurons, Widrow-Hoff rule
- Objective functions and gradient descent
- Multilayer networks and backpropagation
Sept. 23,25: Unsupervised learning
- Linear Hebbian learning and PCA, decorrelation
- Winner-take-all networks and clustering
Sept. 30: Guest lecture
- TBD
Oct. 2: Sparse, distributed coding
- Autoencoders
- Natural image statistics
- Projection pursuit
Oct. 7: Plasticity and cortical maps
- Cortical maps
- Self-organizing maps, Kohonen nets
- Models of experience dependent learning and cortical reorganization
Oct. 9: Guest lecture
- TBD
Oct. 14: Manifold learning
- Local linear embedding, Isomap
Oct. 16: Guest lecture
- Tom Dean, Google: Connectomics
Oct. 21,23,28,30: Recurrent networks
- Hopfield networks
- Models of associative memory, pattern completion
- Line attractors and `bump circuits’
- Dynamical models
Nov. 4,6,13,18,20,25: Probabilistic models and inference
- Probability theory and Bayes’ rule
- Learning and inference in generative models
- The mixture of Gaussians model
- Boltzmann machines
- Sparse coding and ‘ICA’
- Kalman filter model
- Energy-based models
Dec. 2,4: Neural implementations
- Integrate-and-fire model
- Neural encoding and decoding
- Limits of precision in neurons
- Neural synchrony and phase-based coding
Dec. 9,11: Guest lectures
- TBD
- TBD
