Difference between revisions of "10-601 Deep Learning 2"

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* [http://www.cs.cmu.edu/~wcohen/10-601/deep-2.pptx Slides in PowerPoint],[http://www.cs.cmu.edu/~wcohen/10-601/deep-2.pdf Slides in PDF].
 
* [http://www.cs.cmu.edu/~wcohen/10-601/deep-2.pptx Slides in PowerPoint],[http://www.cs.cmu.edu/~wcohen/10-601/deep-2.pdf Slides in PDF].
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Wrapup from next lecture:
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* [http://www.cs.cmu.edu/~wcohen/10-601/deep-wrapup.pptx Slides in PowerPoint],[http://www.cs.cmu.edu/~wcohen/10-601/deep-wrapup.pdf Slides in PDF].
  
 
=== Readings ===
 
=== Readings ===
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===  Things to remember  ===
 
===  Things to remember  ===
  
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* How backprop can be generalized to a sequence of assignment operations
 
* Convolutional networks
 
* Convolutional networks
 
** 2-d convolution
 
** 2-d convolution
 
** How to construct a convolution layer
 
** How to construct a convolution layer
 
** Architecture of CNN: convolution/downsampling pairs
 
** Architecture of CNN: convolution/downsampling pairs
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* Recurrent neural networks
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** When they are useful
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** Why they are hard to train (if trained naively)
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** The basic ideas used in an LSTM: forget, insert, and output gates

Latest revision as of 09:17, 13 April 2016

This a lecture used in the Syllabus for Machine Learning 10-601B in Spring 2016

Slides

Wrapup from next lecture:

Readings

This area is moving very fast and the textbooks are not up-to-date. Some recommended readings:

I also used some on-line visualizations in the materials for the lecture, especially the part on ConvNets.

The LSTM figures and examples I used are mostly from

Things to remember

  • How backprop can be generalized to a sequence of assignment operations
  • Convolutional networks
    • 2-d convolution
    • How to construct a convolution layer
    • Architecture of CNN: convolution/downsampling pairs
  • Recurrent neural networks
    • When they are useful
    • Why they are hard to train (if trained naively)
    • The basic ideas used in an LSTM: forget, insert, and output gates