*
* Learning rate should be a float value between 0.0(exclusive) and 1.0(inclusive)
* Maximum number of iterations can be an integer value greater than 0
* @param int $learningRate
* @param int $maxIterations
*/
public function __construct(float $learningRate = 0.001, int $maxIterations = 1000,
bool $normalizeInputs = true)
{
if ($learningRate <= 0.0 || $learningRate > 1.0) {
throw new \Exception("Learning rate should be a float value between 0.0(exclusive) and 1.0(inclusive)");
}
if ($maxIterations <= 0) {
throw new \Exception("Maximum number of iterations should be an integer greater than 0");
}
if ($normalizeInputs) {
$this->normalizer = new Normalizer(Normalizer::NORM_STD);
}
$this->learningRate = $learningRate;
$this->maxIterations = $maxIterations;
}
/**
* @param array $samples
* @param array $targets
* @param array $labels
*/
public function partialTrain(array $samples, array $targets, array $labels = [])
{
return $this->trainByLabel($samples, $targets, $labels);
}
/**
* @param array $samples
* @param array $targets
* @param array $labels
*/
public function trainBinary(array $samples, array $targets, array $labels)
{
if ($this->normalizer) {
$this->normalizer->transform($samples);
}
// Set all target values to either -1 or 1
$this->labels = [1 => $labels[0], -1 => $labels[1]];
foreach ($targets as $key => $target) {
$targets[$key] = strval($target) == strval($this->labels[1]) ? 1 : -1;
}
// Set samples and feature count vars
$this->featureCount = count($samples[0]);
$this->runTraining($samples, $targets);
}
protected function resetBinary()
{
$this->labels = [];
$this->optimizer = null;
$this->featureCount = 0;
$this->weights = null;
$this->costValues = [];
}
/**
* Normally enabling early stopping for the optimization procedure may
* help saving processing time while in some cases it may result in
* premature convergence.
*
* If "false" is given, the optimization procedure will always be executed
* for $maxIterations times
*
* @param bool $enable
*/
public function setEarlyStop(bool $enable = true)
{
$this->enableEarlyStop = $enable;
return $this;
}
/**
* Returns the cost values obtained during the training.
*
* @return array
*/
public function getCostValues()
{
return $this->costValues;
}
/**
* Trains the perceptron model with Stochastic Gradient Descent optimization
* to get the correct set of weights
*
* @param array $samples
* @param array $targets
*/
protected function runTraining(array $samples, array $targets)
{
// The cost function is the sum of squares
$callback = function ($weights, $sample, $target) {
$this->weights = $weights;
$prediction = $this->outputClass($sample);
$gradient = $prediction - $target;
$error = $gradient**2;
return [$error, $gradient];
};
$this->runGradientDescent($samples, $targets, $callback);
}
/**
* Executes a Gradient Descent algorithm for
* the given cost function
*
* @param array $samples
* @param array $targets
*/
protected function runGradientDescent(array $samples, array $targets, \Closure $gradientFunc, bool $isBatch = false)
{
$class = $isBatch ? GD::class : StochasticGD::class;
if (empty($this->optimizer)) {
$this->optimizer = (new $class($this->featureCount))
->setLearningRate($this->learningRate)
->setMaxIterations($this->maxIterations)
->setChangeThreshold(1e-6)
->setEarlyStop($this->enableEarlyStop);
}
$this->weights = $this->optimizer->runOptimization($samples, $targets, $gradientFunc);
$this->costValues = $this->optimizer->getCostValues();
}
/**
* Checks if the sample should be normalized and if so, returns the
* normalized sample
*
* @param array $sample
*
* @return array
*/
protected function checkNormalizedSample(array $sample)
{
if ($this->normalizer) {
$samples = [$sample];
$this->normalizer->transform($samples);
$sample = $samples[0];
}
return $sample;
}
/**
* Calculates net output of the network as a float value for the given input
*
* @param array $sample
* @return int
*/
protected function output(array $sample)
{
$sum = 0;
foreach ($this->weights as $index => $w) {
if ($index == 0) {
$sum += $w;
} else {
$sum += $w * $sample[$index - 1];
}
}
return $sum;
}
/**
* Returns the class value (either -1 or 1) for the given input
*
* @param array $sample
* @return int
*/
protected function outputClass(array $sample)
{
return $this->output($sample) > 0 ? 1 : -1;
}
/**
* Returns the probability of the sample of belonging to the given label.
*
* The probability is simply taken as the distance of the sample
* to the decision plane.
*
* @param array $sample
* @param mixed $label
*/
protected function predictProbability(array $sample, $label)
{
$predicted = $this->predictSampleBinary($sample);
if (strval($predicted) == strval($label)) {
$sample = $this->checkNormalizedSample($sample);
return abs($this->output($sample));
}
return 0.0;
}
/**
* @param array $sample
* @return mixed
*/
protected function predictSampleBinary(array $sample)
{
$sample = $this->checkNormalizedSample($sample);
$predictedClass = $this->outputClass($sample);
return $this->labels[ $predictedClass ];
}
}