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How can I improve the performance of a feed-forward backpropagation neural network?

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Jocelyn
Jocelyn on 2 Mar 2016
Commented: Greg Heath on 26 Apr 2016
Hi, I am working with MATLAB R2013a to build a prediction neural network model. I have tried to use different training algorithms, activation functions and number of hidden neurons but still can't get the R more than 0.8 for training set, validation set and testing set. The R of training set for some networks can be more than 0.8 but provide low R values (around 0.4~0.5) for validation and testing set. Below are the codes. Is there any solutions to improve the performance and R value?
inputs<48x206>, targets<5x206>
inputs = inputs;
targets = targets;
hiddenLayerSize = 15;
net = fitnet(hiddenLayerSize);
net.layers{1}.transferFcn='tansig';
net.layers{2}.transferFcn='purelin';
net.inputs{1}.processFcns = {'removeconstantrows','mapminmax'};
net.outputs{2}.processFcns = {'removeconstantrows','mapminmax'};
net.divideFcn = 'dividerand';
net.divideMode = 'sample';
net.divideParam.trainRatio = 70/100;
net.divideParam.valRatio = 15/100;
net.divideParam.testRatio = 15/100;
net.trainFcn = 'traincgp';
net.performFcn = 'mse';
net.plotFcns = {'plotperform','plottrainstate','ploterrhist', ... 'plotregression', 'plotfit'};
[net,tr] = train(net,inputs,targets);
outputs = net(inputs);
errors = gsubtract(targets,outputs);
performance = perform(net,targets,outputs)
trainTargets = targets .* tr.trainMask{1};
valTargets = targets .* tr.valMask{1};
testTargets = targets .* tr.testMask{1};
trainPerformance = perform(net,trainTargets,outputs)
valPerformance = perform(net,valTargets,outputs)
testPerformance = perform(net,testTargets,outputs)
view(net)
  1 Comment
pepper yuan
pepper yuan on 30 Mar 2016
Hi, Jocelyn, have you solve the problem of improving the performance of neural network? As I'm dealing the problem same with you, can you provide me your email, so I can ask you some questions via the email. Appreciate if you can rely me.

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Accepted Answer

Greg Heath
Greg Heath on 4 Mar 2016
% 1. This is REGRESSION, not PREDICTION.
%2. Placeholders:
input = randn(48,206);
target = randn(5,48)*input.^2+randn(5,48)*input+ randn(5,206);
[ I N ] = size(input) % [ 48 206 ]
[ O N ] = size(target) % [ 5 206 ]
%3. N = 206 doesn't provide enough information to be using I = 48:
Ntrn = N - 2*round(0.15*N) % 144 training points
Ntrneq = Ntrn*O % 720 No. of training equations
% Nw = (I+1)*H+(H+1)*O No. of weights for an I-H-O net
% Nw > Ntrneq <==> H > Hub
Hub = (0.7*N-O)/(I+O+1) % 2.6 to 2.9 for O = 5 to 1
% Therefore, regardless of O, the net is OVERFIT when H >= 3
% 4. Remedies:
a. H <= 2 and/or
b. Validation Stopping and/or
c. TRAINBR Regularization and/or
d. MSEREG Regularization and/or
e. Input variable Reduction
% 5. I recommend trying 4e first. To get a feel for the data, you could
a. Standardize all variables with zscore or mapstd
b. Create 48 graphs with the 5 targets plotted vs each input
c. Remove or modify outliers
d. Obtain the 54 x 54 correlation coefficient matrix
e. Consider multiple single output models
f. Use STEPWISEFIT and/or STEPWISE on a linear model
Good Luck.
P.S. I try not to waste my time by using statements that just assign default parameter values
Hope this helps.
Thank you for formally accepting my answer
Greg
  1 Comment
Greg Heath
Greg Heath on 20 Apr 2016
CORRECTION:
Hub = (Ntrneq-O)/(I+O+1)% 13.2 for O = 5
I have run 10 initial random number trials for each value of H = 0:13. This resulted in a DECREASE in performance as H increased!!!??? I was quite surprised since I had never experienced that before.
This became somewhat more believable when I plotted the data. The best Linear model (i.e., H=0 ) yielded NMSE = 0.44, Rsq = 1-NMSE = 0.56 and R = sqrt(Rsq) = 0.75.
Next I tried a non-neural quadratic model and hit paydirt!
If this were my problem I would use STEPWISEFIT to see which inputs, crossproducts and squares are really necessary.
Hope this helps.
Greg

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More Answers (3)

Jocelyn
Jocelyn on 28 Mar 2016
Thanks Greg for your suggested solutions. I have tried all the above remedies and neural network with MSEREG regularization provides the highest value of R for training and testing which are 0.73 and 0.71. However, I have to get the R value more than 0.8. Is there any other solution to improve it? It is really urgent and I really appreciate your help.
  1 Comment
Greg Heath
Greg Heath on 28 Mar 2016
1. You are still wasting time, space and attention by keeping statements that merely assign default values
2. How many inputs and outputs are you using after the variable reduction?
3. What happens when you use
net.divideFcn = 'dividetrain'
and try to minimize H using a double for loop as in my posts?
Hope this helps.
Greg

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Jocelyn
Jocelyn on 12 Apr 2016
Sorry for the late reply. I didn't reduce the variables and have to use back the same number of variables as those variables are the tested significant variables from the structural equation modeling. So, the input and output sizes remain same. I have make some changes as below and would like to ask for your help to improve the performance.Thanks.
close all,clear all,clc,tic
load inputs&targets
x=KMinputs;
t=KMtargets;
[I N]=size(x) %[48 206]
[O N]=size(t) %[5 206]
rng('default')
h=4
net = fitnet(h);
net.layers{1}.transferFcn='tansig';
net.layers{2}.transferFcn='tansig';
net.inputs{1}.processFcns = {'removeconstantrows','mapminmax'};
net.outputs{2}.processFcns = {'removeconstantrows','mapminmax'};
Ntrneq=N*O
ynaive=mean(t,2)
Nw00=numel(ynaive)
Ndof00=Ntrneq-Nw00
y00=repmat(ynaive,1,N);
SSE00=sse(t-y00)
MSE00=SSE00/Ntrneq %0.6768
MSE00a=SSE00/Ndof00 %0.6801
Nw=(I+1)*h+(h+1)*O %221
Ndof=Ntrneq-Nw %809
net.divideFcn = 'dividerand';
net.divideParam.trainRatio = 0.9;
net.divideParam.valRatio = 0;
net.divideParam.testRatio = 0.1;
net.trainFcn = 'trainlm';
MSEgoal=0.01*Ndof*MSE00a/Ntrneq %0.0053
MinGrad=MSEgoal/100 %5.3415e-05
net.trainParam.goal=MSEgoal;
net.trainParam.min_grad=MinGrad;
net.performFcn = 'msereg';
net.performParam.regularization = 0.5;
net.plotFcns = {'plotperform','plottrainstate','ploterrhist', ... 'plotregression', 'plotfit'};
[net tr y e] = train(net,x,t);
y = net(x);
errors = gsubtract(t,y);
performance = perform(net,t,y) %0.1574
trainTargets = t .* tr.trainMask{1};
testTargets = t .* tr.testMask{1};
trainPerformance = perform(net,trainTargets,y) %0.1531
testPerformance = perform(net,testTargets,y) %0.1953
[r,m,b] = regression(t,y)
NMSE= mse(e)/MSE00; %0.4181
R2= 1-NMSE; %0.5819
view(net)
%Rtrn=0.78149
%Rtst=0.78322
%Rtotal=0.78071
  7 Comments
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Greg Heath
Greg Heath on 16 Apr 2016
If you post the data in *.m or *.txt, I may be able to take a look at it.
Again: My first impression is that you don't have enough data to accurately deal with 48 inputs.
Greg
Jocelyn
Jocelyn on 16 Apr 2016
Hi Greg. I have attached my data in *.txt here. Actually, the inputs can be classified into 3 categories(category 1=IN1->IN9, category 2=IN10->IN32, category 3=IN33->IN48). Does it applicable to build 3 NN for each category with the targets? Thanks.

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Jocelyn
Jocelyn on 19 Apr 2016
Is it feasible to set the rng to rng('default') or a fixed seed and generator for the neural network? How to predict the outputs of a new set of inputs based on the previous network training?
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Jocelyn
Jocelyn on 21 Apr 2016
If I want to collect the Rsq of training, validation and testing sets for each Ntrials loop, what are the matlab codes?
Thanks Greg for the explanation. I can get the whole picture of it now. However, my data has been gone through the convergent and discriminant validity tests and redundant variables have been eliminated using structural equation modeling. So, I think there must be lack of data points to obtain better result. I decided to collect more data to run the neural network. Is there any formula or equation to calculate the minimum number of data set with 48 inputs and 5 outputs for neural network? Or just use the below equations?
Ntrn = N - 2*round(0.15*N)
Ntrneq = Ntrn*O
Nw = (I+1)*H+(H+1)*O
Hub = (0.7*N-O)/(I+O+1)
Greg Heath
Greg Heath on 26 Apr 2016
For no overfitting
Ntrneq >= Nw
Which leads to
Hub = (Ntrneq - O)/(I + O + 1)
= (Ntrn*O - O)/(I + O +1)
~ (0.7*N*O - O )/ (I + O + 1)
Hope this helps.
Greg

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