Progress Report on Neural Net

Well, reducing the number of nodes in the hidden layer didn't help much; if anything it made things look slightly more erratic. As a result I decided to increase the number of input features to 102, which gave much more pleasing results. A screen shot of this newer NN, in the bottom pane, is shown below

Comparing this with the earlier version shown in my previous post, for example by looking at the smooth uptrend in the middle, it can be seen that there are far fewer "false" market types indicated - a definite improvement. The moral seems to be that adding more informative features is the way to go.

However, this raises the problem of training time - it took about 30 hours to train this model using my current Octave scripts - which is far too long for me. Due to this I have decided to use the FANN library, fanntool and the octave-fann bindings for my future development of NNs. I've recently been playing around with these and I think that, in the long run, a lot of time will be saved, even though I will have to write a certain amount of "glue code" to achieve what I want. The above 102 input feature NN will be my reserve NN in the event that I can't get the FANN library, fanntool and octave-fann to work to my satisfaction.

Results of Comparative Cross Validation Tests

As expected the NN achieved 100 % accuracy and my prediction of 20 % to 30 % accuracy for my current Naive Bayesian Classifier was more or less right - in various runs of sample sizes up to 50,000 it achieved accuracy rates of 30 % to 33 %. A screen shot of both classifiers applied to the last 200 days worth of S & P futures prices is shown below, with the Naive Bayesian in the upper pane and the NN in the lower pane.

However, despite it vastly superior performance in the tests, I don't really like the look of the NN on real data - it appears to be more erratic or noisier than the Bayesian classifier. I suspect that the NN may be overly complex, with 54 nodes in its one hidden layer. I shall try to improve the NN by reducing the number of hidden layer nodes to 25, and then seeing how that looks on real data.

Successful Completion of Neural Net Cross Validation Tests

In my last post I suggested that I was unsure of my coding of the cross validation test I had written so what I have done is take a new coding approach and completely rewritten the test, which I'm happy to say has been very successful. Using this newly coded implementation the out of sample accuracy of the trained neural nets is 100 %. As before, these tests were run overnight, but this time for a total of 2,400,000 separate test examples due to increased code efficiency.

The next test I'm going to code, more out of curiosity than anything else, is a concurrent cross validation test to test both my new neural net classifier algorithm and my Naive Bayesian Classifier together. I expect the NN to again obtain results similar to the above, but anticipate that the Naive Bayesian Classifier will perform quite poorly, achieving between 20 % to 30 % accuracy. I expect such low performance simply because the Naive Bayesian Classifier was developed using just 5 exemplar market type examples compared to 25 for the NN.

Neural Net Cross Validation Tests Completed

These tests were conducted by looping over a series of replicated "idealised" market types; in each iteration cyclic component amplitudes were randomly chosen to range between 1 and 25 and phase shifts were randomly chosen such that the phase shifts that appear in the training set markets do not also appear in these cross validation sets of markets. For each combination of the above one of 25 possible market type changes was also randomly applied and then the relevant feature vector for each iteration was extracted. These tests were run overnight for a total of 1,200,000 separate, iterated test examples. The results are shown below.

Complete Accuracy percentage: 33.574500

"Acceptable" mis-classifications percentages
Predicted = uwr & actual = unr: 5.083417
Predicted = unr & actual = uwr: 7.230083
Predicted = dwr & actual = dnr: 5.170667
Predicted = dnr & actual = dwr: 7.180167
Predicted = uwr & actual = cyc: 3.287917
Predicted = dwr & actual = cyc: 7.180167
Predicted = cyc & actual = uwr: 3.623167
Predicted = cyc & actual = dwr: 3.554333

Dubious, difficult to trade mis-classification percentages
Predicted = uwr & actual = dwr: 2.432667
Predicted = unr & actual = dwr: 2.432667
Predicted = dwr & actual = uwr: 2.351500
Predicted = dnr & actual = uwr: 2.351500

Completely wrong classifications percentages
Predicted = unr & actual = dnr: 0.210083
Predicted = dnr & actual = unr: 0.207333

The complete accuracy percentage requires no comment. The "acceptable" mis-classifications are situations in which the erroneous prediction would not have one trading in a manner that would be inconsistent with the actual state of the market i.e. a predicted uwr and actual cyc is a situation where the market is predicted to be trending upwards with 50% retracements, but in actual fact is trending sideways in a cyclic manner. In either case one might be tempted to trade the swings of the market, so the mis-classification is acceptable because the erroneous prediction would still have you trading in a manner suitable to the "true" situation.

The "Dubious, difficult to trade" mis-classifications are where the above does not apply, i.e. attempting to swing trade in a bullish manner when in fact the market is trending down. One might get lucky and extract some profit, but in all probability the net expectation would be to make a loss. The completely wrong classifications again require no comment. The above totals of percentages do not add up to 100 because some combinations of mis-classifications are not included in this summary.

I'm not overwhelmed by these results, and so I shall continue to extend the features vector with more informative features to hopefully improve future cross validation test results. Also, I'm not 100% sure that my test implementation code is doing what I think it is doing, so that needs checking too.

On a related note, I've just enrolled in another online course, this time devoted entirely to neural nets.

Neural Net Training Completed

I am pleased to say that I have now completed the training of my NN market type classifier.

In an earlier post I mentioned that I had constructed a training set of 324,000 training examples to train the NN on. However, my first attempt at using this in its entirety wasn't successful, with an accuracy on the training set of between 52 % to 58 %. What's more, one training "session" lasted approximately 24 hours, with only 50 calls to the fmincg.m function ( a Java implementation is available from here ), and this would need to be repeated many times. This wasn't a practical proposition and I began to think about ways in which I could speed up the training process. One possible solution was to use other software and in my search of the internet I discovered the FANN library and the Fanntool GUI. After a close reading of the manuals I decided that for my purposes this wasn't the route I wanted to take, but in the future I may come back to this, particularly since the library has bindings to Octave.

After some consideration I decided to split the training set into smaller sets, with the intention of training numerous NNs, each trained to classify a market with a given period, and then to index into the relevant NN in a manner similar to that used in my brute force similarity classifier. The code for this training session is shown below.

% first, training data "training_data.mat" should be loaded in command line

clear -exclusive X y accurate_period % clear everything except y and X, previously loaded from the command line

% ************************************************************************
% Comment out the non relevant preprocessing step for the test in question
% ************************************************************************
% use X as it is for X_train
X_train = X ;
% ************************************************************************
% change zeros in X into -1 for X_train
%X_train = X ;
%change = X_train(:,4:end) ;
%change( change == 0 ) = -1 ;
%X_train(:,4:end) = change ;
%*************************************************************************
% train on just one period's features in X
% index into training set based on period measurement

% create final matrices for storing all unrolled Theta1 and Theta2 and cost record
all_ur_Theta1 = zeros(2862,288) ;
all_ur_Theta2 = zeros(270,288) ;
cost_record = zeros(288,4) ;
col_count = 1 ;

for period = 15:50 
[i_X j_X] = find( accurate_period(:,1) == period ) ;
% extract the relevant part of X using above i_X index
X_train = X( [i_X] , 2:54 ) ;
% and same for market labels vector y
y_train = y( [i_X] , 1 ) ;
% ************************************************************************

%% Setup the parameter sizes 
input_layer_size = size(X_train,2) ;   % the number of features ( columns ) in X_train
hidden_layer_size = size(X_train,2) ;  % original was 25 hidden units
num_labels = 5 ;                 % 5 labels, from 1 to 5  
                                 % 1=uwr 2=unr 3=dwr 4=dnr 5=cyc

for lambda = [ 0.01 0.03 0.1 0.3 1 3 10 30 ]

% Initializing Neural Network Parameters
initial_Theta1 = randInitializeWeights( input_layer_size , hidden_layer_size ) ;
initial_Theta2 = randInitializeWeights( hidden_layer_size , num_labels ) ;

% Unroll parameters
initial_nn_params = [ initial_Theta1(:) ; initial_Theta2(:) ] ;

%% =================== Training NN ===================
%  To train the neural network, we will now use "fmincg", which
%  is a function which works similarly to "fminunc". Recall that these
%  advanced optimizers are able to train our cost functions efficiently as
%  long as we provide them with the gradient computations.
%
fprintf( '\nTraining Neural Network... \n' )

%  After you have completed the assignment, change the MaxIter to a larger
%  value to see how more training helps.
options = optimset( 'MaxIter' , 200 ) ; % original was 50

% try different values of lambda
%lambda = 0.1 ;

% Create "short hand" for the cost function to be minimized
costFunction = @(p) nnCostFunction( p, ...
                                   input_layer_size, ...
                                   hidden_layer_size, ...
                                   num_labels, X_train, y_train, lambda ) ;

% Now, costFunction is a function that takes in only one argument (the
% neural network parameters)
[ nn_params , cost ] = fmincg( costFunction , initial_nn_params , options ) ;

% Obtain Theta1 and Theta2 back from nn_params
Theta1 = reshape( nn_params( 1:hidden_layer_size * (input_layer_size + 1) ) , ...
                 hidden_layer_size , (input_layer_size + 1) ) ;

Theta2 = reshape( nn_params( (1 + (hidden_layer_size * (input_layer_size + 1))):end ) , ...
                 num_labels , (hidden_layer_size + 1) ) ;

%% ================= Implement Predict =================
%  After training the neural network, we would like to use it to predict
%  the labels. You will now implement the "predict" function to use the
%  neural network to predict the labels of the training set. This lets
%  you compute the training set accuracy.

pred = predict( Theta1 , Theta2 , X_train ) ;
training_set_accuracy = mean( double(pred == y_train) ) * 100.0 ;

fprintf( 'Training Set Accuracy: %f\n' , training_set_accuracy ) ;
fprintf( 'for lambda value of: %f\n' , lambda ) ;
fprintf( 'and period: %f\n' , period ) ;

% write to all_ur_Theta1 & all_ur_Theta2 & cost record
all_ur_Theta1(:,col_count) = Theta1(:) ;
all_ur_Theta2(:,col_count) = Theta2(:) ;
cost_record(col_count,1) = period ;
cost_record(col_count,2) = lambda ;
cost_record(col_count,3) = training_set_accuracy ;
cost_record(col_count,4) = cost(end) ;
col_count = col_count + 1 ;

end % lambda loop

end % period loop

save -binary all_ur_Thetas.mat all_ur_Theta1 all_ur_Theta2 cost_record

With 200 calls to the fmincg.m function this took an overnight run to complete, but in the morning I had extremely good results. For every period there was a trained NN that obtained 100 % accuracy. In fact for most periods there were several values for lambda ( a regularisation term to avoid over-fitting ) that gave 100 % accuracy, in which case I took the NN that had the lowest cost for 100 % accuracy.

So now I have a set of trained NNs, and the next step will be to test them on a cross validation set of my normal "ideal" market types, which will be the subject of my next post.

Jack Schwagger on Youtube

I have just watched a very interesting Youtube video of Jack Schwagger, of Market Wizards fame, giving a presentation. Well worth watching.

Update on Neural Network:- as I write this I have a NN training session running in Octave, which looks very promising. More in a new post in a day or so.

Brute Force Classifier in Action

As an update to my recent post, here is a short video of the brute force similarity search classifier in action.

Non-embedded view here.
The coloured coded candlestick bars are coloured thus: purple = a cyclic market classification; green = up with retracement; blue = up with no retracement; yellow = down with retracement; red = down with no retracement. The upper price series is the classification as per the brute force algorithm and the lower is the classification as per my Naive Bayesian classifier, shown for comparative purposes.  The cyan trend line is my implementation of a Kalman filter, and where this trend line extends out at the hard right hand edge of the chart it changes to become the prediction of the Kalman filter for the next 10 bars, this prediction based on extending the pattern that was selected during the run of the brute force algorithm.

I will leave it up to readers to judge for themselves the efficacy of this new indicator, but I think it shows some promise, and I have some ideas about how it can be improved. This, however, is work for the future. For now I intend to crack on with working on my neural net classification algorithm.