setMaxValues([1, 1, 1], [1]); $nn->setHiddenLayersCount(2); $nn->setHiddenLayerNeuronsCount(3); $d = [0, 0, 0]; $nn->addSample($d, behaviour($d)); $d = [0, 0, 1]; $nn->addSample($d, behaviour($d)); $d = [0, 1, 0]; $nn->addSample($d, behaviour($d)); $d = [0, 1, 1]; $nn->addSample($d, behaviour($d)); $d = [1, 0, 0]; $nn->addSample($d, behaviour($d)); $d = [1, 0, 1]; $nn->addSample($d, behaviour($d)); $d = [1, 1, 0]; $nn->addSample($d, behaviour($d)); $d = [1, 1, 1]; $nn->addSample($d, behaviour($d)); $nn->store('A/B/C/test', true); } if( false && 'load_neural_network' ){ $nn = NeuralNetwork::load('A/B/C/test'); } if( true && 'test_genomes' ){ /* (1) Basic Creation */ $a = new Genome(2, 3); // 2 layers of 3 neurons each -> randomly filled /* (2) Inheritance */ $b = new Genome($a); // Clone of @a /* (3) Section Title */ // $b->mutation(0.3); // @b has now mutated with a threshold of 30% /* (4) Cross-over (father+mother) */ $c = new Genome($a, $b); // @c is a randomly-done mix of @a and @b } // REWRITE TEST // for( $a = 0, $al = 50 ; $a < $al ; $a++ ) // for( $b = 0, $bl = 20 ; $b < $bl ; $b++ ){ // print "genome $b/$bl on generation $a/$al \r"; // usleep(1000*10); // } ?>