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== Intermediate topics == | == Intermediate topics == | ||
- | * [[analysis:course-w16:week11|Module 11: Interactions between multiple signals: coherence and other connectivity measures (Week 8)]] | + | * [[analysis:course-w16:week11|Module 11: Interactions between multiple signals: coherence, Granger causality, and phase-slope index (Week 8)]] |
* [[analysis:course-w16:week12|Module 12: Time-frequency analysis II: cross-frequency coupling (Week 9)]] | * [[analysis:course-w16:week12|Module 12: Time-frequency analysis II: cross-frequency coupling (Week 9)]] | ||
* [[analysis:course-w16:week13|Module 13: Spike-field relationships: spike-triggered average, phase locking, phase precession (Week 10)]] | * [[analysis:course-w16:week13|Module 13: Spike-field relationships: spike-triggered average, phase locking, phase precession (Week 10)]] | ||
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* [[analysis:course-w16:week15|Module 15: Two-step Bayesian decoding with dynamic spatial priors]] (likely skip) | * [[analysis:course-w16:week15|Module 15: Two-step Bayesian decoding with dynamic spatial priors]] (likely skip) | ||
- | * [[analysis:course-w16:week16|Module 16: Co-activation and detection of neural ensembles]] (likely skip) | + | * [[analysis:course-w16:week16|Module 16: Pairwise co-occurrence]] (likely skip) |
== Other topics == | == Other topics == | ||
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Basic familiarity with MATLAB. Depending on your background and programming experience you might find the following resources helpful: | Basic familiarity with MATLAB. Depending on your background and programming experience you might find the following resources helpful: | ||
- | * Textbook: {{:analysis:wallisch_matlabforneuro.pdf|Wallisch, MATLAB for Neuroscientists}} | + | * Textbook: Wallisch, MATLAB for Neuroscientists |
* [[http://www.mathworks.com/help/matlab/getting-started-with-matlab.html?s_cid=learn_doc|"Getting Started with MATLAB" Primer]]. | * [[http://www.mathworks.com/help/matlab/getting-started-with-matlab.html?s_cid=learn_doc|"Getting Started with MATLAB" Primer]]. | ||
* [[http://www.mathworks.com/matlabcentral/about/cody/ | Cody]], a continually expanding set of problems with solutions to work through, with a points system to track your progress | * [[http://www.mathworks.com/matlabcentral/about/cody/ | Cody]], a continually expanding set of problems with solutions to work through, with a points system to track your progress | ||
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* [[http://stackoverflow.com/questions/tagged/matlab | MATLAB questions on StackOverflow]], a Q&A site where you can browse previous questions and add new ones | * [[http://stackoverflow.com/questions/tagged/matlab | MATLAB questions on StackOverflow]], a Q&A site where you can browse previous questions and add new ones | ||
- | If you have no formal training in computer programming (i.e. you have never taken a "Intro to Computer Science" or "Introductory Programming" type course) you will almost certainly find what follows in this course less frustrating if you do the pen-and-paper exercises in this [[http://sites.tufts.edu/rodrego/files/2011/03/Secrets-of-Computer-Power-Revealed-2008.pdf | short chapter]] by Daniel Dennett ("The Secrets of Computer Power Revealed") | + | If you have no formal training in computer programming (i.e. you have never taken a "Intro to Computer Science" or "Introductory Programming" type course) you will almost certainly find what follows in this course less frustrating if you do the pen-and-paper exercises in this [[http://sites.tufts.edu/rodrego/files/2011/03/Secrets-of-Computer-Power-Revealed-2008.pdf | short chapter]] by Daniel Dennett ("The Secrets of Computer Power Revealed") before you embark on the MATLAB primer linked to above. |
=== Resources === | === Resources === | ||
This course is "standalone", but the following textbooks provide more in-depth treatment of some of the topics. | This course is "standalone", but the following textbooks provide more in-depth treatment of some of the topics. | ||
- | * Textbook: {{:analysis:leis_dspusingmatlab.pdf|Leis, Digital Signal Processing using MATLAB for Students and Researchers}} | + | * Textbook: Leis, Digital Signal Processing using MATLAB for Students and Researchers |
- | * Textbook: {{:analysis:johnstonwu.pdf|Johnston and Wu, Foundations of Cellular Neurophysiology}} | + | * Textbook: Johnston and Wu, Foundations of Cellular Neurophysiology |
- | * Textbook: {{:analysis:dayanabbott_theoneuro.pdf|Dayan & Abbott, Theoretical Neuroscience}} | + | * Textbook: Dayan & Abbott, Theoretical Neuroscience |
=== What this course is === | === What this course is === | ||
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=== Acknowledgments === | === Acknowledgments === | ||
- | The architecture of the code used in this course was inspired by a similar set of code by my post-doctoral mentor, [[http://redishlab.neuroscience.umn.edu/ | A. David Redish]]; several of the data types and functions are re-implementations of Redish lab functions of the same name. Major contributions to the codebase were made by Alyssa Carey (a %%MSc%% student and research assistant in the lab) and Youki Tanaka (current PhD student), | + | The architecture of the code used in this course was inspired by a similar set of code by my post-doctoral mentor, [[http://redishlab.neuroscience.umn.edu/ | A. David Redish]]; several of the data types and functions are re-implementations of Redish lab functions of the same name. Major contributions to the codebase were made by Alyssa Carey (a %%MSc%% student and research assistant in the lab) and Youki Tanaka (current PhD student). |