# Implementing and ploting a perceptron in MATLAB

I´m reviewing a code from Toronto perceptron MATLAB code

The code is

``````function [w] = perceptron(X,Y,w_init)

w = w_init;
for iteration = 1 : 100  %<- in practice, use some stopping criterion!
for ii = 1 : size(X,2)         %cycle through training set
if sign(w'*X(:,ii)) ~= Y(ii) %wrong decision?
w = w + X(:,ii) * Y(ii);   %then add (or subtract) this point to w
end
end
sum(sign(w'*X)~=Y)/size(X,2)   %show misclassification rate
end
``````

So I was reading how to apply this function to data matrix X, and target Y, but, do not know how to use this function, I understand, it returns a vector of weights, so it can classify.

Could you please give an example, and explain it??

I´ve tried

``````X=[0 0; 0 1; 1 1]
Y=[1 0; 2 1]
w=[1 1 1]
Result = perceptron( X, Y, w )

??? Error using ==> mtimes
Inner matrix dimensions must agree.

Error in ==> perceptron at 15
if sign(w'*X(:,ii)) ~= Y(ii)

Result = perceptron( X, Y, w' )

??? Error using ==> ne
Matrix dimensions must agree.

Error in ==> perceptron at 19
sum(sign(w'*X)~=Y) / size(X,2);
``````

Thanks

Thank you for the anwers, I got one more, If I change the Y = [0, 1], what happens to the algorithm?.

So, Any input data will not work with Y = [0,1] with this code of the perceptron right?,

-----------------------------EDIT------------------------

One more question, if I want to plot the line that divides the 2 classes, I know we can get that the line solving linear equation system that has to do with weights, but how, what could I do?, I'm trying something like

``````% the initial weights
w_init = [ 1 1 1]';
% the weights returned from perceptron
wtag   = perceptron(X,Y,w_init,15);

% concatenate both
Line = [wtag,w_init]

% solve the linear system, am I correct doing this?
rref(Line')

% plot???
``````
-

You should first understand what is the meaning of each of the inputs:

• `X` is the input matrix of examples, of size M x N, where M is the dimension of the feature vector, and N the number of samples. Since the perceptron model for prediction is `Y=w*X+b`, you have to supply one extra dimension in `X` which is constant, usually set to `1`, so the `b` term is "built-in" into `X`. In the example below for `X`, I set the last entry of `X` to be `1` in all samples.
• `Y` is the correct classification for each sample from `X` (the classification you want the perceptron to learn), so it should be a N dimensional row vector - one output for each input example. Since the perceptron is a binary classifier, it should have only 2 distinct possible values. Looking in the code, you see that it checks for the sign of the prediction, which tells you that the allowed values of `Y` should be `-1,+1` (and not `0,1` for example).
• `w` is the weight vector you are trying to learn.

So, try to call the function with:

``````X=[0 0; 0 1; 1 1];
Y=[1 -1];
w=[.5; .5; .5];
``````

EDIT

Use the following code to call the perceptron alg and see the results graphically:

``````% input samples
X1=[rand(1,100);rand(1,100);ones(1,100)];   % class '+1'
X2=[rand(1,100);1+rand(1,100);ones(1,100)]; % class '-1'
X=[X1,X2];

% output class [-1,+1];
Y=[-ones(1,100),ones(1,100)];

% init weigth vector
w=[.5 .5 .5]';

% call perceptron
wtag=perceptron(X,Y,w);
% predict
ytag=wtag'*X;

% plot prediction over origianl data
figure;hold on
plot(X1(1,:),X1(2,:),'b.')
plot(X2(1,:),X2(2,:),'r.')

plot(X(1,ytag<0),X(2,ytag<0),'bo')
plot(X(1,ytag>0),X(2,ytag>0),'ro')
legend('class -1','class +1','pred -1','pred +1')
``````
-
Nice response!! – qdjm Feb 3 '11 at 14:39
Thank you very much, i really understand your example, but have one more question: What would you if the class 1 has more examples than class 0?? in the example you provided there are the same number of examples for both classes, X1 and X2 – cMinor Feb 3 '11 at 20:05
Is this correct, I can not test it right now: X1=[rand(1,100);rand(1,100);ones(1,100)]; % class '+1' X2=[rand(1,300);1+rand(1,300);ones(1,300)]; % class '-1' X=[X1,X2]; % output class [-1,+1]; Y=[-ones(1,100),ones(1,300)]; % init weigth vector w=[.5 .5 .5]'; wtag=perceptron(X,Y,w); – cMinor Feb 3 '11 at 20:31
The number of examples is irrelevant, I just chose equal number for each class because of convenience. Nothing has to Change. The size of `w` should be the dimension of the samples (including the constant term), since any prediction is based on the value of the dot product `w*x` - so `w` and `x` should have the same size. – Itamar Katz Feb 3 '11 at 20:32
Yes, this seems right. In addition, it's only a synthetic example. In a real-world example your data is mixed, and you are not concerned with the size of each class - only ensure you have enough examples from each class to cover the sample space. – Itamar Katz Feb 3 '11 at 20:34

If you are interested, here is a little perceptron demo written in quite a tutorial manner:

``````function perceptronDemo
%PERCEPTRONDEMO
%
%   A simple demonstration of the perceptron algorithm for training
%   a linear classifier, made as readable as possible for tutorial
%   purposes. It is derived from the treatment of linear learning
%   machines presented in Chapter 2 of "An Introduction to Support
%   Vector Machines" by Nello Cristianini and John Shawe-Taylor.
%
%

Data  = createTrainingData;
Model = trainPerceptron( Data );

end
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
function Model = trainPerceptron( Data )
%TRAINPERCEPTRON

DOWN   = 1;
ACROSS = 2;

assert( isequal( unique( Data.labels ), [-1; +1] ), ...
'Labels must be -1 or +1' );

% ---------------------------------------------------------------------
% Normalise the data by calculating z-scores
%
%   This makes plotting easier, but is not needed by the algorithm.
%

sampleMean   = mean( Data.samples );
sampleStdDev = std(  Data.samples );
Data.samples = bsxfun( @minus,   Data.samples, sampleMean   );
Data.samples = bsxfun( @rdivide, Data.samples, sampleStdDev );

% ---------------------------------------------------------------------
% Calculate the squared radius of the smallest ball that encloses the
% data and is centred on the origin. This is used to provide an
% appropriate range and step size when updating the threshold (bias)
% parameter.
%

sampleSize = size( Data.samples, DOWN );
maxNorm    = realmin;
for iObservation = 1:sampleSize
observationNorm = norm( Data.samples(iObservation,:) );
if observationNorm > maxNorm
maxNorm = observationNorm;
end
end

% ---------------------------------------------------------------------
% Define the starting weight vector and bias. These should be zeros,
% as the algorithm omits a learning rate, and it is suggested in
% Cristianini & Shawe-Taylor that learning rate may only be omitted
% safely when the starting weight vector and bias are zero.
%

Model.weights = [0.0 0.0];
Model.bias    = 0.0;

% ---------------------------------------------------------------------
% Run the perceptron training algorithm
%
%   To prevent program running forever when nonseparable data are
%   provided, limit the number of steps in the outer loop.
%

maxNumSteps = 1000;

for iStep = 1:maxNumSteps

isAnyObsMisclassified = false;

for iObservation = 1:sampleSize;

inputObservation = Data.samples( iObservation, : );
desiredLabel     = Data.labels(  iObservation    ); % +1 or -1

perceptronOutput = sum( Model.weights .* inputObservation, ACROSS ) + Model.bias;
margin           = desiredLabel * perceptronOutput;

isCorrectLabel   = margin > 0;

% -------------------------------------------------------------
% If the model misclassifies the observation, update the
% weights and the bias.
%

if ~isCorrectLabel

isAnyObsMisclassified = true;

weightCorrection = desiredLabel  * inputObservation;
Model.weights    = Model.weights + weightCorrection;

biasCorrection   = desiredLabel .* enclosingBallRadiusSquared;
Model.bias       = Model.bias   + biasCorrection;

displayPerceptronState( Data, Model );

end % if this observation misclassified.

end % loop over observations

if ~isAnyObsMisclassified
disp( 'Done!' );
break;
end

end % outer loop

end % TRAINPERCEPTRON
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
function Data = createTrainingData
%CREATETRAININGDATA
%
%   Return a structure containing training data suitable for linear
%   classification.
%

sampleAsize   = 1024;
sampleBsize   = 1024;

sampleAmean   = [ 5.5 5.0 ];
sampleAstdDev = [ 0.5 1.0 ];

sampleBmean   = [ 2.5 3.0 ];
sampleBstdDev = [ 0.3 0.7 ];

Data.samples  = [ normallyDistributedSample( sampleAsize, sampleAmean, sampleAstdDev ); ...
normallyDistributedSample( sampleBsize, sampleBmean, sampleBstdDev ) ];

Data.labels   = [  ones(sampleAsize,1); ...
-ones(sampleBsize,1) ];

% ---------------------------------------------------------------------
% Randomly permute samples & class labels.
%
%   This is not really necessary, but done to illustrate that the order
%   in which observations are evaluated does not matter.
%

randomOrder   = randperm( sampleAsize + sampleBsize );
Data.samples  = Data.samples( randomOrder, : );
Data.labels   = Data.labels(  randomOrder, : );

end % CREATETRAININGDATA
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
function samples = normallyDistributedSample( sampleSize, sampleMean, sampleStdDev )
%NORMALDISTRIBUTIONSAMPLE
%
%   Draw a sample from a normal distribution with specified mean and
%   standard deviation.
%

assert(    isequal( size( sampleMean ), size( sampleStdDev ) ) ...
&& 1 == size( sampleMean, 1 ),                         ...
'Sample mean and standard deviation must be row vectors of equal length.' );

numFeatures = numel( sampleMean );
samples     = randn( sampleSize, numFeatures );
samples     = bsxfun( @times, samples, sampleStdDev );
samples     = bsxfun( @plus,  samples, sampleMean   );

end % NORMALDISTRIBUTIONSAMPLE
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
function displayPerceptronState( Data, Model )
%DISPLAYPERCEPTRONSTATE

hFig = figure( 1 );
clf;
set( hFig,                        ...
'NumberTitle', 'off',         ...
'Name',         mfilename,    ...
'Color',        [1.0 1.0 1.0] );

displayXmin = -4;
displayXmax =  4;
displayYmin = -4;
displayYmax =  4;

hAx = subplot( 1, 1, 1 );
axis('equal');
set( hAx,                                  ...
'Box',      'on',                      ...
'xgrid',    'on',                      ...
'ygrid',    'on',                      ...
'xlim',     [displayXmin displayXmax], ... % Bounds suitable for Z-scored data
'ylim',     [displayYmin displayYmax]  );
xlabel( 'x_1' );
ylabel( 'x_2' );

% ---------------------------------------------------------------------
% Plot data points from the two classes
%

isPositiveClass = Data.labels >  0;
isNegativeClass = Data.labels <= 0;

plot( hAx, Data.samples(isPositiveClass,1), Data.samples(isPositiveClass,2), 'b+' );
plot( hAx, Data.samples(isNegativeClass,1), Data.samples(isNegativeClass,2), 'rx' );

% ---------------------------------------------------------------------
% Display parameters for separating hyperplane in title
%

xWeight   = Model.weights(1);
yWeight   = Model.weights(2);
bias      = Model.bias;

szTitle   = sprintf( 'Linear classifier parameters: %0.2f x_1 + %0.2f x_2 + %0.2f = 0', xWeight, yWeight, bias );
title( szTitle );

% ---------------------------------------------------------------------
% Plot separating hyperplane
%

y1 = ( (xWeight*displayXmin) + bias ) ./ -yWeight;
y2 = ( (xWeight*displayXmax) + bias ) ./ -yWeight;

plot( hAx, [displayXmin; displayXmax], [y1, y2], 'k-', 'linewidth', 2 );

pause(0.1);

end % DISPLAYPERCEPTRONSTATE
``````
-

try this:

``````perceptron([1 2 1 2], [1 0 1 0], 0.5);
``````
-
Your example won't work, since the algorithm assumes output values of [-1,+1], not [0,1]. The `w` vector won't be updated at all. – Itamar Katz Feb 3 '11 at 14:21
Also, the input should be at least of dimension 2, otherwise you explicitly assuming that `b=0` in `y=a*x+b` – Itamar Katz Feb 3 '11 at 14:37