Let's assume I have a convolutional neural network which should predict two different (semantically) things out of images which can be classified in a N-dimensional output each. So my network looks like this:
# architecture input (RGB images) | conv_layer 1 | ..... | conv_layer n | _______________ | | fc1_x fc1_y <-- fully-connected layer 1 | | fc2_x fc2_y <-- fully-connected layer 2 / output (output_x) (output_y)
output_x is a vector of dimension
(1, 1000), therefore predicting over 1000 classes.
output_y is a vector of dimension
(1, 500), therefore predicting over 500 classes.
The classes in x and y are semantically related, so they are not one-hot encoded. Instead, a normal distribution around the real class is fitted in the training vectors.
With every training step I am minimizing the cross entropy error like this:
train_step_x = tf.train.AdamOptimizer(0.001).minimize(cross_entropy_x) train_step_y = tf.train.AdamOptimizer(0.001).minimize(cross_entropy_y)
So I'm calculating different cross entropy errors for
Up to now I am satisfied with the (training) results of the network. However, the network architecture is not final. It will get bigger and eventually deeper and the training data set will be several orders of magnitude bigger as it is by now.
My question is: Is this a reasonable network architecture? Or is it considered rather a bad design?
Is Tensorflow really training the two streams separately? Or are my two AdamOptimizers per learning step bad design and am I just getting "magically" good looking results although my architecture wouldn't be considered "good" for this problem?
I thought two different fully-connected "streams" for x and y data/classes would be reasonable for an architecture which should predict between two different "sets" of classes.