Stack Overflow is a community of 4.7 million programmers, just like you, helping each other.

Join them; it only takes a minute:

Sign up
Join the Stack Overflow community to:
  1. Ask programming questions
  2. Answer and help your peers
  3. Get recognized for your expertise

Intro: I'm using MATLAB's Neural Network Toolbox in an attempt to forecast time series one step into the future. Currently I'm just trying to forecast a simple sinusoidal function, but hopefully I will be able to move on to something a bit more complex after I obtain satisfactory results.

Problem: Everything seems to work fine, however the predicted forecast tends to be lagged by one period. Neural network forecasting isn't much use if it just outputs the series delayed by one unit of time, right?

Code:

t = -50:0.2:100;
noise = rand(1,length(t));
y = sin(t)+1/2*sin(t+pi/3);
split = floor(0.9*length(t));
forperiod = length(t)-split;
numinputs = 5;
forecasted = [];
msg = '';
for j = 1:forperiod
    fprintf(repmat('\b',1,numel(msg)));
    msg = sprintf('forecasting iteration %g/%g...\n',j,forperiod);
    fprintf('%s',msg);

    estdata = y(1:split+j-1);
    estdatalen = size(estdata,2);

    signal = estdata;
    last = signal(end);

    [signal,low,high] = preprocess(signal'); % pre-process
    signal = signal';

    inputs = signal(rowshiftmat(length(signal),numinputs));
    targets = signal(numinputs+1:end);

    %% NARNET METHOD
    feedbackDelays = 1:4;
    hiddenLayerSize = 10;
    net = narnet(feedbackDelays,[hiddenLayerSize hiddenLayerSize]);
    net.inputs{1}.processFcns = {'removeconstantrows','mapminmax'};
    signalcells = mat2cell(signal,[1],ones(1,length(signal)));
    [inputs,inputStates,layerStates,targets] = preparets(net,{},{},signalcells);
    net.trainParam.showWindow = false;
    net.trainparam.showCommandLine = false;
    net.trainFcn = 'trainlm';  % Levenberg-Marquardt
    net.performFcn = 'mse';  % Mean squared error
    [net,tr] = train(net,inputs,targets,inputStates,layerStates);
    next = net(inputs(end),inputStates,layerStates);


    next = postprocess(next{1}, low, high); % post-process
    next = (next+1)*last;

    forecasted = [forecasted next];
end

figure(1);
plot(1:forperiod, forecasted, 'b', 1:forperiod, y(end-forperiod+1:end), 'r');
grid on;

Note: The function 'preprocess' simply converts the data into logged % differences and 'postprocess' converts the logged % differences back for plotting. (Check EDIT for preprocess and postprocess code)

Results:

A screenshot of the forecasting results using MATLAB.

BLUE: Forecasted Values

RED: Actual Values

Can anyone tell me what I'm doing wrong here? Or perhaps recommend another method to achieve the desired results (lagless prediction of sinusoidal function, and eventually more chaotic timeseries)? Your help is very much appreciated.

EDIT: It's been a few days now and I hope everyone has enjoyed their weekend. Since no solutions have emerged I've decided to post the code for the helper functions 'postprocess.m', 'preprocess.m', and their helper function 'normalize.m'. Maybe this will help get the ball rollin.

postprocess.m:

function data = postprocess(x, low, high)

% denormalize
logdata = (x+1)/2*(high-low)+low;

% inverse log data
sign = logdata./abs(logdata);
data = sign.*(exp(abs(logdata))-1);

end

preprocess.m:

function [y, low, high] = preprocess(x)

% differencing
diffs = diff(x);
% calc % changes
chngs = diffs./x(1:end-1,:);
% log data
sign = chngs./abs(chngs);
logdata = sign.*log(abs(chngs)+1);
% normalize logrets
high = max(max(logdata));
low = min(min(logdata));
y=[];
for i = 1:size(logdata,2)
    y = [y normalize(logdata(:,i), -1, 1)];
end

end

normalize.m:

function Y = normalize(X,low,high)
%NORMALIZE Linear normalization of X between low and high values.

if length(X) <= 1
    error('Length of X input vector must be greater than 1.');
end

mi = min(X);
ma = max(X);
Y = (X-mi)/(ma-mi)*(high-low)+low;

end
share|improve this question
    
Oh my, this was meant to be asked in machine learning. Sincerest apologies. – user1656007 Jan 31 '13 at 4:19
    
Let it here also, people here know a lot in general! – Ander Biguri Jan 31 '13 at 9:45
up vote 2 down vote accepted

I didn't check you code, but made a similar test to predict sin() with NN. The result seems reasonable, without a lag. I think, your bug is somewhere in synchronization of predicted values with actual values. Here is the code:

%% init & params
t = (-50 : 0.2 : 100)';
y = sin(t) + 0.5 * sin(t + pi / 3);
sigma = 0.2;
n_lags = 12;
hidden_layer_size = 15;
%% create net
net = fitnet(hidden_layer_size);
%% train
noise = sigma * randn(size(t));
y_train = y + noise;
out = circshift(y_train, -1);
out(end) = nan;
in = lagged_input(y_train, n_lags);
net = train(net, in', out');
%% test
noise = sigma * randn(size(t)); % new noise
y_test = y + noise;
in_test = lagged_input(y_test, n_lags);
out_test = net(in_test')';
y_test_predicted = circshift(out_test, 1); % sync with actual value
y_test_predicted(1) = nan;
%% plot
figure, 
plot(t, [y, y_test, y_test_predicted], 'linewidth', 2); 
grid minor; legend('orig', 'noised', 'predicted')

and the lagged_input() function:

function in = lagged_input(in, n_lags)
    for k = 2 : n_lags
        in = cat(2, in, circshift(in(:, end), 1));
        in(1, k) = nan;
    end
end

enter image description here

share|improve this answer
    
You were right, it's a synchronization error. The line responsible is this little bugger: estdata = y(1:split+j-1);. The -1 is unnecessary. Thank you kindly for your help sir. – user1656007 Feb 5 '13 at 2:32

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.