I'm porting my Caffe network over to TensorFlow but it doesn't seem to have xavier initialization. I'm using
truncated_normal but this seems to be making it a lot harder to train.
Just to add another example on how to define a
tf.Variable initialized using Xavier and Yoshua's method:
graph = tf.Graph() with graph.as_default(): ... initializer = tf.contrib.layers.xavier_initializer() w1 = tf.Variable(initializer(w1_shape)) b1 = tf.Variable(initializer(b1_shape)) ...
This prevented me from having
nan values on my loss function due to numerical instabilities when using multiple layers with RELUs.
@Aleph7, Xavier/Glorot initialization depends the number of incoming connections (fan_in), number outgoing connections (fan_out), and kind of activation function (sigmoid or tanh) of the neuron. See this: http://jmlr.org/proceedings/papers/v9/glorot10a/glorot10a.pdf
So now, to your question. This is how I would do it in TensorFlow:
(fan_in, fan_out) = ... low = -4*np.sqrt(6.0/(fan_in + fan_out)) # use 4 for sigmoid, 1 for tanh activation high = 4*np.sqrt(6.0/(fan_in + fan_out)) return tf.Variable(tf.random_uniform(shape, minval=low, maxval=high, dtype=tf.float32))
Note that we should be sampling from a uniform distribution, and not the normal distribution as suggested in the other answer.
Incidentally, I wrote a post yesterday for something different using TensorFlow that happens to also use Xavier initialization. If you're interested, there's also a python notebook with an end-to-end example: https://github.com/delip/blog-stuff/blob/master/tensorflow_ufp.ipynb
def xavier_init(n_inputs, n_outputs, uniform=True): """Set the parameter initialization using the method described. This method is designed to keep the scale of the gradients roughly the same in all layers. Xavier Glorot and Yoshua Bengio (2010): Understanding the difficulty of training deep feedforward neural networks. International conference on artificial intelligence and statistics. Args: n_inputs: The number of input nodes into each output. n_outputs: The number of output nodes for each input. uniform: If true use a uniform distribution, otherwise use a normal. Returns: An initializer. """ if uniform: # 6 was used in the paper. init_range = math.sqrt(6.0 / (n_inputs + n_outputs)) return tf.random_uniform_initializer(-init_range, init_range) else: # 3 gives us approximately the same limits as above since this repicks # values greater than 2 standard deviations from the mean. stddev = math.sqrt(3.0 / (n_inputs + n_outputs)) return tf.truncated_normal_initializer(stddev=stddev)
xavier_initializer. Here is an example how to use it:
import tensorflow as tf a = tf.get_variable("a", shape=[4, 4], initializer=tf.contrib.layers.xavier_initializer()) with tf.Session() as sess: sess.run(tf.global_variables_initializer()) print sess.run(a)
In addition to this, tensorflow has other initializers:
I looked and I couldn't find anything built in. However, according to this:
Xavier initialization is just sampling a (usually Gaussian) distribution where the variance is a function of the number of neurons.
tf.random_normal can do that for you, you just need to compute the stddev (i.e. the number of neurons being represented by the weight matrix you're trying to initialize).
kernel_initializer parameter to
tf.layers.conv2d, tf.layers.conv2d_transpose, tf.layers.Dense etc
layer = tf.layers.conv2d( input, 128, 5, strides=2,padding='SAME', kernel_initializer=tf.contrib.layers.xavier_initializer())