I am having a bit of trouble understanding the dimensions of the tensors used in the set up of convolutional neural networks using TensorFlow. For example, in this tutorial, the 28x28 MNIST images are represented like this:
import TensorFlow as tf x = tf.placeholder(tf.float32, shape=[None, 784]) x_image = tf.reshape(x, [-1,28,28,1])
Assuming I have ten training images, the reshaping above makes my input
x_image a collection of ten sub-collections of twenty-eight 28-dimensional column vectors.
It seems more natural to use
x_image_natural = tf.reshape(x, [-1,28,28])
instead, which would return ten 28x28 matrices.
a = np.array(range(8)) opt1 = a.reshape(-1,2,2,1) opt2 = a.reshape(-1,2,2) print opt1 print opt2 # opt1 - column vectors >>[[[ >>] >>[ >>]] >>[[ >>] >>[ >>]]] # opt2 - matrices >>[[[0 1] >>[2 3]] >>[[4 5] >>[6 7]]]
In a similar vein, is there an intuitive way to understand why the convolutional layers have dimensions
(height_of_patch, width_of_patch, num_input_layers, num_output_layers)? The transpose, seems more intuitive, in that it is ultimately a collection of patch-sized matrices.
* EDIT *
I'm actually curious about why the dimensions of the tensors are ordered they way they are.
For the inputs, X, why don't we use
x_image = tf.reshape(x, [-1,i,28,28])
which would create batch_size,
i-sized arrays of 28x28 matrices (where
i is the number of input layers)?
Similarly, why aren't the weight tensors shaped like
(num_output_layers, num_input_layers, input_height, input_width) (which again seems more intuitive in that it is a collection of 'patch matrices.')