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Project: BatchRenormalization (GitHub Link)

• BatchRenormalization-master
  • cifar10_brn.py
  • wrn_batchnorm.py
  • plots
  • weights
    • README.md
  • wrn_renorm.py
  • LICENSE
  • batch_renorm.py
  • cifar10_bn_mode_0.py
  • README.md
  • visualization.py
  • history
    • batchnorm_history.txt
    • batch_renorm_history.txt
  • .idea
    • markdown-navigator
      • profiles_settings.xml
    • inspectionProfiles
      • Project_Default.xml
    • modules.xml
    • encodings.xml
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    • BatchRenormalization.iml

Batch Renormalization

Batch Renormalization algorithm implementation in Keras 2.0+. Original paper by Sergey Ioffe, Batch Renormalization: Towards Reducing Minibatch Dependence in Batch-Normalized Models.

NOTE:

This implementation of BatchRenormalization is inconsistent with the original paper and therefore results may not be similar !

For discussion on the inconsistency of this implementation, refer here : https://github.com/keras-team/keras-contrib/issues/17

Usage

Add the batch_renorm.py script into your repository, and import the BatchRenormalization layer.

Eg. You can replace Keras BatchNormalization layers with BatchRenormalization layers.

from batch_renorm import BatchRenormalization

Performance

Using BatchRenormalization layers requires slightly more time than the simpler BatchNormalization layer.

Observed speed differences in WRN-16-4 with respect to BatchNormalization on a 980M GPU:

1) Batch Normalization : 137 seconds per epoch.

2) Batch Renormalization (Mode 0) : 152 seconds per epoch.

3) Batch Renormalization (Mode 2) : 142 seconds per epoch.

Results

The following graph is from training a Wide Residual Network (WRN-16-4) on the CIFAR 10 dataset, with no data augmentation and no dropout. Therefore all models clearly overfit.

However, the graphs compare WRN-16-4 model with Keras BatchNormalization (mode 0) with BatchRenormalization (mode 0 and mode 2). All other parameters are kept constant.

Parameters

There are several parameters that are present in addition to the parameters in BatchNormalization layers.

r_max_value: The clipped maximum value that the internal parameter 'r' can take. The value of r will be clipped in the range
             (1 / r_max_value, r_max_value) after a sufficient number of iterations. 
             The paper suggests a default value of 3.

d_max_value: The clipped maximum value that the internal parameter 'd' can take. The value of d will be clipped in the range
             (-d_max_value, d_max_value) after a sufficient number of iterations. 
             The paper suggests a default value of 5.

t_delta:     This parameter determines in how many iterations the internal r_max and d_max values will become equal to 
             r_max_value and d_max_value. 

             Default setting is 1, which means that in 5 iterations the internal parameters 
             will become their maximum value.

             Values larger than 1 can cause gradient explosion, and prevent learning of anything useful.

             Using very small values will lead to slower learning, but eventually will lead to the same result as using 
             t_delta = 1. 

             Sugggested t_delta values = 1 to 1e-3.

Requirements

Keras 1.2.1 (will be updated when Keras 2 launches)

Theano / Tensorflow

h5py

seaborn (optional, for plotting training graph)