Postgraduate Course: Neural Information Processing (INFR11035)
|School||School of Informatics
||College||College of Science and Engineering
|Credit level (Normal year taken)||SCQF Level 11 (Postgraduate)
||Availability||Available to all students
|Summary||This course builds one recent insights that in many cases the computation done by the nervous system can be described in machine learning terms and using information theory. This course focusses on the more mathematical models of the brain and sensory processing. The solutions found by the nervous system might transfer to engineering applications such as compression, parallel processing, and dealing with complex data.
*Neural coding: reverse correlation, higher order kernels, stimulus reconstruction. Application to the fly visual system.
*Information theory as applied to neural coding: mutual information measures, whitening. Application to retinal and LGN coding.
*Networks based on information-theoretic cost functions: Helmholtz machine, Linsker's info-max principle. Application to V1 coding.
*Independent Component Analysis. Basics, variants of ICA, ICA as model for visual cortex.
*Predictive Coding: Kalman filters. Application to cortical coding
*Bayesian approaches: Stimulus estimation, probabilistic interpretation of populations codes.
Relevant QAA Computing Curriculum Sections: Simulation and Modelling, Artificial intelligence
Entry Requirements (not applicable to Visiting Students)
||Other requirements|| This course is open to all Informatics students including those on joint degrees. For external students where this course is not listed in your DPT, please seek special permission from the course organiser.
A good undergraduate-level grounding in mathematics is assumed, particularly probability and statistics, vectors and matrices. Neural Computation is recommended as preparation. Also, a reasonable level of familiarity with computational concepts and MATLAB is assumed.
Information for Visiting Students
|High Demand Course?
Course Delivery Information
|Not being delivered|
On completion of this course, the student will be able to:
- Understand response analysis techniques and their limitations when applied to neural responses.
- Analyse neural responses in Information theoretic terms
- Describe perceptual processing from a probabilistic point of view.
- Implement some of the methods discussed in class in Matlab.
|Abbott and Dayan (2001) Theoretical Neuroscience. MIT press (recommended)|
|Course organiser||Dr Matthias Hennig
Tel: (131 6)50 3080
|Course secretary||Mrs Sam Stewart
Tel: (0131 6)51 3266