# Can I use `tf.nn.dropout` to implement DropConnect?

I (think) that I grasp the basics of DropOut and the use of the TensorFlow API in implementing it. But the normalization that's linked to the dropout probability in `tf.nn.dropout` seems not to be a part of DropConnect. Is that correct? If so, does normalizing do any "harm" or can I simply apply `tf.nn.dropout` to my weights to implement DropConnect?

Yes, you can use tf.nn.dropout to do DropConnect, just use tf.nn.dropout to wrap your weight matrix instead of your post matrix multiplication. You can then undo the weight change by multiplying by the dropout like so

``````dropConnect = tf.nn.dropout( m1, keep_prob ) * keep_prob
``````

# Code Example

Here is a code example that calculates the XOR function using drop connect. I've also commented out the code that does dropout that you can sub in and compare the output.

``````### imports
import tensorflow as tf

### constant data
x  = [[0.,0.],[1.,1.],[1.,0.],[0.,1.]]
y_ = [[1.,0.],[1.,0.],[0.,1.],[0.,1.]]

### induction

# Layer 0 = the x2 inputs
x0 = tf.constant( x  , dtype=tf.float32 )
y0 = tf.constant( y_ , dtype=tf.float32 )

keep_prob = tf.placeholder( dtype=tf.float32 )

# Layer 1 = the 2x12 hidden sigmoid
m1 = tf.Variable( tf.random_uniform( [2,12] , minval=0.1 , maxval=0.9 , dtype=tf.float32  ))
b1 = tf.Variable( tf.random_uniform( [12]   , minval=0.1 , maxval=0.9 , dtype=tf.float32  ))

########## DROP CONNECT
# - use this to preform "DropConnect" flavor of dropout
dropConnect = tf.nn.dropout( m1, keep_prob ) * keep_prob
h1 = tf.sigmoid( tf.matmul( x0, dropConnect ) + b1 )

########## DROP OUT
# - uncomment this to use "regular" dropout
#h1 = tf.nn.dropout( tf.sigmoid( tf.matmul( x0,m1 ) + b1 ) , keep_prob )

# Layer 2 = the 12x2 softmax output
m2 = tf.Variable( tf.random_uniform( [12,2] , minval=0.1 , maxval=0.9 , dtype=tf.float32  ))
b2 = tf.Variable( tf.random_uniform( [2]   , minval=0.1 , maxval=0.9 , dtype=tf.float32  ))
y_out = tf.nn.softmax( tf.matmul( h1,m2 ) + b2 )

# loss : sum of the squares of y0 - y_out
loss = tf.reduce_sum( tf.square( y0 - y_out ) )

# training step : discovered learning rate of 1e-2 through experimentation

### training
# run 5000 times using all the X and Y
# print out the loss and any other interesting info
with tf.Session() as sess:
sess.run( tf.initialize_all_variables() )
print "\nloss"
for step in range(5000) :
sess.run(train,feed_dict={keep_prob:0.5})
if (step + 1) % 100 == 0 :
print sess.run(loss,feed_dict={keep_prob:1.})

results = sess.run([m1,b1,m2,b2,y_out,loss],feed_dict={keep_prob:1.})
labels  = "m1,b1,m2,b2,y_out,loss".split(",")
for label,result in zip(*(labels,results)) :
print ""
print label
print result

print ""
``````

# Output

Both flavors are able to correctly separate the input into the correct output

``````y_out
[[  7.05891490e-01   2.94108540e-01]
[  9.99605477e-01   3.94574134e-04]
[  4.99370173e-02   9.50062990e-01]
[  4.39682379e-02   9.56031740e-01]]
``````

Here you can see the output from dropConnect was able to correctly classify Y as true,true,false,false.

• And for convolutional layers: I assume DropConnect applies, in the same way, to the kernel weights, in place of Dropout's application before/after ([I'm never clear which(stackoverflow.com/q/37573674/656912)) pooling. Correct? Commented Jun 7, 2017 at 16:56
• Yes, you can use it to dropconnect any weight. The trick is to wrap the weight and not the post processing. For convolution, you'll have a weight matrix just like the above code and you'd wrap it in just the same way. Cheers. Commented Jun 7, 2017 at 17:00
• I'd love some better answers (or opinions) for my [related question](stackoverflow.com/q/37573674/656912) on that point. Commented Jun 7, 2017 at 17:06
• The Regularization of Neural Networks using DropConnect paper says "Additionally, the biases are also masked out during training" - does this mean that the code above should have applied `tf.nn.dropout(b1, keep_prob)*keep_prob` to `b1` ? Commented Nov 16, 2017 at 16:38
• oh, that's an interesting question. It is worth a test, or at least a thought experiment. As a thought experiment I'd say that the bias acts to "white balance" the embedding space where as dropConnect acts to make layer-to-layer connections act redundantly, so my gut would say that using dropConnect on a bias is misguided. But, it is worth a test. I don't see anything in that paper which empirically tests with and without. It's more like they are saying what they did - just so you know. Commented Nov 16, 2017 at 18:32