# `Optimal` variable initialization and learning rate in Tensorflow for matrix factorization

I'm trying a very simple optimization in Tensorflow- the problem of matrix factorization. Given a matrix `V (m X n)`, decompose it into `W (m X r)` and `H (r X n)`. I'm borrowing a gradient descent based tensorflow based implementation for matrix factorization from here.

Details about the matrix V. In its original form, the histogram of entries would be as follows:

To bring the entries on a scale of [0, 1], I perform the following preprocessing.

``````f(x) = f(x)-min(V)/(max(V)-min(V))
``````

After normalization, the histogram of data would look like the following:

My questions are:

1. Given the nature of data: between 0 and 1 and most entries closer to 0 than 1, what would be the optimal initialisation for `W` and `H`?
2. How should the learning rates be defined based on different cost function: `|A-WH|_F` and `|(A-WH)/A|`?

The minimal working example would be as follows:

``````import tensorflow as tf
import numpy as np
import pandas as pd

V_df = pd.DataFrame([[3, 4, 5, 2],
[4, 4, 3, 3],
[5, 5, 4, 4]], dtype=np.float32).T
``````

Thus, V_df looks like:

``````    0   1   2
0   3.0 4.0 5.0
1   4.0 4.0 5.0
2   5.0 3.0 4.0
3   2.0 3.0 4.0
``````

Now, the code defining W, H

``````V = tf.constant(V_df.values)
shape = V_df.shape
rank = 2 #latent factors

initializer = tf.random_normal_initializer(mean=V_df.mean().mean()/5,stddev=0.1 )
#initializer = tf.random_uniform_initializer(maxval=V_df.max().max())

H =  tf.get_variable("H", [rank, shape[1]],
initializer=initializer)
W =  tf.get_variable(name="W", shape=[shape[0], rank],
initializer=initializer)
WH = tf.matmul(W, H)
``````

Defining the cost and optimizer:

``````f_norm = tf.reduce_sum(tf.pow(V - WH, 2))
lr = 0.01
``````

Running the session:

``````max_iter=10000
display_step = 50

with tf.Session() as sess:
sess.run(tf.global_variables_initializer())

for i in xrange(max_iter):

loss, _ = sess.run([f_norm, optimize])
if i%display_step==0:
print loss, i
W_out = sess.run(W)
H_out = sess.run(H)
WH_out = sess.run(WH)
``````

I realized that when I used something like `initializer = tf.random_uniform_initializer(maxval=V_df.max().max())`, I got matrices W and H such that their product was much greater than V. I also realised that keeping learning rate (`lr`) to be .0001 was probably too slow.

I was wondering if there are any rules of thumb for defining good initializations and learning rate for the problem of matrix factorization.

• The question is very well exposed, but I.M.O. this is off-topic. Tuning parameters, like learning rate and initialization matrices, typically depends on the problem being addressed, and you will not get better opinions than those provided in the optimizer documentation. – rll Apr 8 '17 at 13:16
• @rll: I understand your point. I have thus edited the question and provided more details about the exact nature of data involved in this problem. I think such settings can be fairly common (data normalised between 0 and 1) – Nipun Batra Apr 11 '17 at 11:27
• I agree with rll - optimal learning rates and initialization matrices greatly depend on your data/problem statement and often require manual tuning to get the best performance out of your model. By the way, in the code example you linked, they are solving non-negative matrix factorization. Do you also have this constraint on `W` and/or `H` or can `W` and `H` be arbitrary matrices? – kafman Apr 12 '17 at 7:10
• @kaufmanu both W and H also need to be non-negative – Nipun Batra Apr 12 '17 at 9:34