# Neural network in MATLAB

I have trained xor neural network in MATLAB and got these weights:

``````iw: [-2.162 2.1706; 2.1565 -2.1688]

lw: [-3.9174 -3.9183]

b{1} [2.001; 2.0033]

b{2} [3.8093]
``````

Just from curiosity I have tried to write MATLAB code which computes the output of this network (two neurons in the hidden layer, and one in the output, TANSIG activation function).

Code that I got:

``````l1w = [-2.162 2.1706; 2.1565 -2.1688];
l2w = [-3.9174 -3.9183];
b1w = [2.001 2.0033];
b2w = [3.8093];

input = [1, 0];

out1 = tansig (input(1)*l1w(1,1) + input(2)*l1w(1,2) + b1w(1));
out2 = tansig (input(1)*l1w(2,1) + input(2)*l1w(2,2) + b1w(2));
out3 = tansig (out1*l2w(1) + out2*l2w(2) + b2w(1))
``````

The problem is when input is lets say [1,1], it outputs -0.9989, when [0,1] 0.4902. While simulating network generated with MATLAB outputs adequately are 0.00055875 and 0.99943.

What am I doing wrong?

• why dont you post the actual code you used to build and train the network?
– Amro
Mar 10, 2010 at 20:25

I wrote a simple example of an XOR network. I used `newpr`, which defaults to `tansig` transfer function for both hidden and output layers.

``````input = [0 0 1 1; 0 1 0 1];               %# each column is an input vector
ouputActual = [0 1 1 0];

net = newpr(input, ouputActual, 2);       %# 1 hidden layer with 2 neurons
net.divideFcn = '';                       %# use the entire input for training

net = init(net);                          %# initialize net
net = train(net, input, ouputActual);     %# train
outputPredicted = sim(net, input);        %# predict
``````

then we check the result by computing the output ourselves. The important thing to remember is that by default, inputs/outputs are scaled to the [-1,1] range:

``````scaledIn = (2*input - 1);           %# from [0,1] to [-1,1]
for i=1:size(input,2)
in = scaledIn(:,i);             %# i-th input vector
hidden(1) = tansig( net.IW{1}(1,1)*in(1) + net.IW{1}(1,2)*in(2) + net.b{1}(1) );
hidden(2) = tansig( net.IW{1}(2,1)*in(1) + net.IW{1}(2,2)*in(2) + net.b{1}(2) );
out(i) = tansig( hidden(1)*net.LW{2,1}(1) + hidden(2)*net.LW{2,1}(2) + net.b{2} );
end
scaledOut = (out+1)/2;              %# from [-1,1] to [0,1]
``````

or more efficiently expressed as matrix product in one line:

``````scaledIn = (2*input - 1);           %# from [0,1] to [-1,1]
out = tansig( net.LW{2,1} * tansig( net.IW{1}*scaledIn + repmat(net.b{1},1,size(input,2)) ) + repmat(net.b{2},1,size(input,2)) );
scaledOut = (1 + out)/2;            %# from [-1,1] to [0,1]
``````
• Excellent. Helped me a lot. Dec 8, 2020 at 6:42

You usually don't use a sigmoid on your output layer--are you sure you should have the tansig on out3? And are you sure you are looking at the weights of the appropriately trained network? It looks like you've got a network trained to do XOR on [1,1] [1,-1] [-1,1] and [-1,-1], with +1 meaning "xor" and -1 meaning "same".

• Then how do you normalize your output if you don't use Sigmoid in the output layer? Furthermore how do you measure error if your output is not normalized? Mar 11, 2010 at 0:21
• For a classifier, you pick the output with the highest value (or toggle at the 50% point) to make your decision. You don't need the nonlinearity. In this case it's okay to do it, but it doesn't really add much. Mar 11, 2010 at 1:16
• the problem of using a linear function in the output layer becomes apparent when you want to get posterior probabilities of each class in addition to the classifications..
– Amro
Mar 11, 2010 at 3:34
• @Amro: Fair enough. If you want them to be forced into the range (0,1), then yes, you should use `1/(1+exp(-y))`; you get approximate probabilities either way but you might exceed 1 (or fall below 0) if you just treat it as a function approximation. Whether that is a problem depends on the application. Mar 11, 2010 at 5:34