[PHP] 遗传算法求函数最大值一般实现

需求：求解函数 f(x) = x + 10*sin(5*x) + 7*cos(4*x) 在区间[0,9]的最大值。

<?php
/*
    需求：求解函数 f(x) = x + 10*sin(5*x) + 7*cos(4*x) 在区间[0,9]的最大值。


    以我们的目标函数 f(x) = x + 10sin(5x) + 7cos(4x), x∈[0,9] 为例。
    假如设定求解的精度为小数点后4位，可以将x的解空间划分为 (9-0)×(1e+4)=90000个等分。
    2^16<90000<2^17，需要17位二进制数来表示这些解。换句话说，一个解的编码就是一个17位的二进制串。
    一开始，这些二进制串是随机生成的。
    一个这样的二进制串代表一条染色体串，这里染色体串的长度为17。
    对于任何一条这样的染色体chromosome，如何将它复原(解码)到[0,9]这个区间中的数值呢？

    对于本问题，我们可以采用以下公式来解码：x = 0 + decimal(chromosome)×(9-0)/(2^17-1)

*/
header("Content-Type:text/html;CharSet=UTF-8");
//初始化参数
$elitism = true;    //是否精英选择
$population_size = 100; //种群大小
$chromosome_size = 17;  //染色体长度
$generation_size = 200; //最大迭代次数
$cross_rate = 0.6;      //交叉概率
$mutate_rate = 0.01;    //变异概率


//初始化对象，执行算法
$ga_object = new GAEngine($population_size, $chromosome_size, $generation_size, $cross_rate, $mutate_rate, $elitism);

$res = $ga_object->run();


//打印结果
echo "迭代{$generation_size}代，最佳个体如下<br>";

echo "染色体：{$res['m']}<br>";
echo "对应的X：{$res['q']}<br>";
echo "结果：{$res['n']}<br>";
echo "最佳个体出现的代：【{$res['p']}】<br>";





//遗传算法主要部分
class GAEngine
{
    //初始化参数
    public $elitism;            //是否精英选择
    public $population_size;    //种群大小
    public $chromosome_size;    //染色体长度
    public $generation_size;    //最大迭代次数
    public $cross_rate;         //交叉概率
    public $mutate_rate;        //变异概率

    //全局参数
    public $G;  //当前迭代次数
    public $fitness_value;  //当前代适应度矩阵
    public $best_fitness;   //历代最佳适应值
    public $fitness_sum;    //前i个个体的适应度之和
    public $fitness_average;    //历代平均适应值矩阵
    public $best_individual;    //历代最佳个体
    public $best_generation;    //最佳个体出现代
    public $upper_bound = 9;    //自变量的区间上限
    public $lower_bound = 0;    //自变量的区间下限

    //对象
    public $population_obj;     //种群对象


    public $populations;    //种群数组


    //初始化
    public function __construct($population_size, $chromosome_size, $generation_size, $cross_rate, $mutate_rate, $elitism)
    {
        $this->elitism = $elitism;
        $this->population_size = $population_size;
        $this->chromosome_size = $chromosome_size;
        $this->generation_size = $generation_size;
        $this->cross_rate = $cross_rate;
        $this->mutate_rate = $mutate_rate;

        //初始化种群
        $this->population_obj = new Populations($population_size, $chromosome_size);

    }

    //【执行,返回结果】
    public function run(){
        //初始化种群
        $this->populations = $this->population_obj->initPop();

        //开始迭代
        for($i = 1; $i < $this->generation_size; $i ++){
            $this->G = $i;
            $this->fitness();  //计算适应度
            $this->rank();     //对个体按适应度大小进行排序
            $this->selection();//选择操作
            $this->crossover();    //交叉操作
            $this->mutation();     //变异操作
        }


        //最后，求出二进制基因对应的实数x，以及求出实数对应的结果
        $x = $this->upper_bound - bindec($this->best_individual)*($this->upper_bound - $this->lower_bound)/(pow(2, $this->chromosome_size) - 1);

        return [
            'm' => $this->best_individual,  //最佳个体
            'n' => $this->best_fitness,     //最佳适应度
            'p' => $this->best_generation,  //最佳个体出现的代
            'q' => $x                       //最佳个体基因对应的实数
        ];

    }

    //【计算适应度】
    public function fitness(){
        //所有个体适应度初始化为0
        //遍历每个个体的基因，求出对应的实数，然后再计算出结果，即适应度
        for($i = 0; $i < $this->population_size; $i ++){
//            $gens = strrev($this->populations[$i]['gens']);//染色体字符串与实际的自变量x二进制串顺序是相反的
            $x = $this->upper_bound - bindec($this->populations[$i]['gens'])*($this->upper_bound - $this->lower_bound)/(pow(2, $this->chromosome_size) - 1);

            $fx = $x + 10*sin(5*$x) + 7*cos(4*$x);//函数值

            $this->fitness_value[$i] = $fx;

        }
    }

    //【排序】
    //对个体按适应度的大小进行排序,并且保存最佳个体
    public function rank(){
        //$this->fitness_value[] 保存适应度的数组，根据此数组进行排序，还要修改对应个体的位置
        //冒泡，从小到大排序
        for($i = 0; $i < $this->population_size -1; $i ++){
            for($j = $i + 1; $j < $this->population_size; $j ++){
                if($this->fitness_value[$i] > $this->fitness_value[$j]){
                    //交换适应度
                    $tmp = $this->fitness_value[$i];
                    $this->fitness_value[$i] = $this->fitness_value[$j];
                    $this->fitness_value[$j] = $tmp;

                    //交换种群个体位置
                    $tmp = $this->populations[$i];
                    $this->populations[$i] = $this->populations[$j];
                    $this->populations[$j] = $tmp;
                }
            }
        }

        //计算前i个给个体的适应度之和
        $fitness_sum[0] = $this->fitness_value[0];
        for($i = 1; $i < $this->population_size; $i ++){
            $fitness_sum[$i] = $fitness_sum[$i - 1] +$this->fitness_value[$i];
        }
        $this->fitness_sum = $fitness_sum;

        //第G代迭代， 个体的平均适应度
        $this->fitness_average[$this->G] = ($fitness_sum[$this->population_size - 1] / $this->population_size);

        //更新最大适应度和对应的迭代次数，保存最佳个体（最佳个体适应度最大）
        if($this->fitness_value[$this->population_size - 1] > $this->best_fitness){
            $this->best_fitness = $this->fitness_value[$this->population_size - 1];
            $this->best_generation = $this->G;
            $this->best_individual = $this->populations[$this->population_size -1]['gens'];
        }

    }

    //【选择】
    public function selection(){
        $population_new = [];//保存被选中的个体

        //二分查找实现轮盘赌功能
        for($i = 0; $i < $this->population_size; $i ++){
            $r = (rand(0,10)/10 ) * $this->fitness_sum[$this->population_size - 1];//生成一个随机数，在[0,总适应度] 之间
            $first = 1;
            $last = $this->population_size;
            $mid = round( ($last + $first) / 2 );
            $idx = -1;


            //排中法选择个体
            while(($first <= $last) && ($idx == -1)){
                if($r > $this->fitness_sum[$mid]){
                    $first = $mid;
                }elseif ( $r < $this->fitness_sum[$mid]){
                    $last = $mid;
                }else{
                    $idx = $mid;
                    break;
                }
                $mid = round( ($last + $first) / 2 );
                if(($last - $first) == 1){
                    $idx = $last;
                    break;
                }

            }

            //产生新的个体
            //echo $idx.'=';
            $population_new[$i]['gens'] = $this->populations[$idx]['gens'];
        }

        //是否精英选择
        if($this->elitism){
            $p = $this->population_size - 1;
        }else{
            $p = $this->population_size;
        }

        for($i = 0; $i < $p; $i ++){
            if(isset($population_new[$i]))
                $this->populations[$i] = $population_new[$i];
        }

    }

    //【交叉】
    public function crossover(){
        //步长为2, 遍历种群
        for($i = 0; $i < $this->population_size; $i+=2){
            //rand < 交叉概率，对2个个体的染色体进行交叉操作
            $r = $this->randFloat();//产生0~1的随机数
            if($r < $this->cross_rate){
//                $r =$this->randFloat();
//                $cross_pos = round($r * $this->chromosome_size);
                $cross_pos = rand(0, $this->chromosome_size);
                if($cross_pos ==0 || $cross_pos == $this->chromosome_size)
                    continue;
                //对 cross_pos及之后的二进制串进行交换
                $x = $this->populations[$i]['gens'];
                $y =  $this->populations[$i+1]['gens'];
                $tmp1 = substr($x,0, $cross_pos).substr($y,$cross_pos);
                $tmp2 = substr($y,0,$cross_pos).substr($x, $cross_pos);

                $this->populations[$i]['gens'] = $tmp1;
                $this->populations[$i+1]['gens'] = $tmp2;
            }
        }
    }

    //【变异】
    public function mutation(){
        for($i =0; $i < $this->population_size; $i ++){
           if($this->randFloat() < $this->mutate_rate){
               $mutate_pos = rand(0,$this->chromosome_size -1);
               $this->populations[$i]['gens'][$mutate_pos] = 1 - $this->populations[$i]['gens'][$mutate_pos];
           }

        }
    }



    public function show($data){
        echo '<pre>';
        var_dump($data);
        echo '<hr>';
    }

    //随机产生0-1的小数
    function randFloat($min=0, $max=1){
        return $min + mt_rand()/mt_getrandmax() * ($max-$min);
    }

}

//种群
class Populations
{
    public $population_size;//种群大小
    public $chromosome_size;//染色体长度

    //初始化参数
    public function __construct($population_size, $chromosome_size)
    {
        $this->population_size = $population_size;
        $this->chromosome_size = $chromosome_size;
    }

    //初始化种群
    public function initPop(){
        $pop = [];
        for($i = 0; $i < $this->population_size; $i ++){
            for($j = 0; $j < $this->chromosome_size; $j ++){
                $pop[$i]['gens'] .=  rand(0, 10) % 2;//产生1-0随机数
            }
        }

        return $pop;
    }

}

参考：

　　知乎：https://www.zhihu.com/question/23293449

　　MATLAB的实现GitHub地址：https://github.com/yanshengjia/artificial-intelligence/tree/master/genetic-algorithm-for-functional-maximum-problem

附录：把个体单独抽出来放到一个类中

<?php
/*
    需求：求解函数 f(x) = x + 10*sin(5*x) + 7*cos(4*x) 在区间[0,9]的最大值。


    以我们的目标函数 f(x) = x + 10sin(5x) + 7cos(4x), x∈[0,9] 为例。
    假如设定求解的精度为小数点后4位，可以将x的解空间划分为 (9-0)×(1e+4)=90000个等分。
    2^16<90000<2^17，需要17位二进制数来表示这些解。换句话说，一个解的编码就是一个17位的二进制串。
    一开始，这些二进制串是随机生成的。
    一个这样的二进制串代表一条染色体串，这里染色体串的长度为17。
    对于任何一条这样的染色体chromosome，如何将它复原(解码)到[0,9]这个区间中的数值呢？

    对于本问题，我们可以采用以下公式来解码：x = 0 + decimal(chromosome)×(9-0)/(2^17-1)

*/
header("Content-Type:text/html;CharSet=UTF-8");
//初始化参数
$elitism = true;    //是否精英选择
$population_size = 100; //种群大小
$chromosome_size = 17;  //染色体长度
$generation_size = 200; //最大迭代次数
$cross_rate = 0.6;      //交叉概率
$mutate_rate = 0.01;    //变异概率


//初始化对象，执行算法
$ga_object = new GAEngine($population_size, $chromosome_size, $generation_size, $cross_rate, $mutate_rate, $elitism);

$res = $ga_object->run();


//打印结果
echo "迭代{$generation_size}代，最佳个体如下<br>";

echo "染色体：{$res['m']}<br>";
echo "对应的X：{$res['q']}<br>";
echo "结果：{$res['n']}<br>";
echo "最佳个体出现的代：【{$res['p']}】<br>";





//遗传算法主要部分
class GAEngine
{
    //初始化参数
    public $elitism;            //是否精英选择
    public $population_size;    //种群大小
    public $chromosome_size;    //染色体长度
    public $generation_size;    //最大迭代次数
    public $cross_rate;         //交叉概率
    public $mutate_rate;        //变异概率

    //全局参数
    public $G;  //当前迭代次数
    public $fitness_value;  //当前代适应度矩阵
    public $best_fitness;   //历代最佳适应值
    public $fitness_sum;    //前i个个体的适应度之和
    public $fitness_average;    //历代平均适应值矩阵
    public $best_individual;    //历代最佳个体
    public $best_generation;    //最佳个体出现代
    public $upper_bound = 9;    //自变量的区间上限
    public $lower_bound = 0;    //自变量的区间下限

    //对象
    public $population_obj;     //种群对象


    public $populations;    //种群数组


    //初始化
    public function __construct($population_size, $chromosome_size, $generation_size, $cross_rate, $mutate_rate, $elitism)
    {
        $this->elitism = $elitism;
        $this->population_size = $population_size;
        $this->chromosome_size = $chromosome_size;
        $this->generation_size = $generation_size;
        $this->cross_rate = $cross_rate;
        $this->mutate_rate = $mutate_rate;

        //初始化种群
        $this->population_obj = new Populations($population_size, $chromosome_size);

    }

    //【执行,返回结果】
    public function run(){
        //初始化种群
        $this->populations = $this->population_obj->initPop();

        //开始迭代
        for($i = 1; $i <= $this->generation_size; $i ++){
            $this->G = $i;
            $this->fitness();  //计算适应度
            $this->rank();     //对个体按适应度大小进行排序
            $this->selection();//选择操作
            $this->crossover();    //交叉操作
            $this->mutation();     //变异操作
        }


        //最后，求出二进制基因对应的实数x，以及求出实数对应的结果
        $x = $this->upper_bound - bindec($this->best_individual)*($this->upper_bound - $this->lower_bound)/(pow(2, $this->chromosome_size) - 1);

        return [
            'm' => $this->best_individual,  //最佳个体
            'n' => $this->best_fitness,     //最佳适应度
            'p' => $this->best_generation,  //最佳个体出现的代
            'q' => $x                       //最佳个体基因对应的实数
        ];

    }

    //【计算适应度】
    public function fitness(){
        //所有个体适应度初始化为0
        //遍历每个个体的基因，求出对应的实数，然后再计算出结果，即适应度
        for($i = 0; $i < $this->population_size; $i ++){
//            $gens = strrev($this->populations[$i]['gens']);//染色体字符串与实际的自变量x二进制串顺序是相反的
            $x = $this->upper_bound - bindec($this->populations[$i]->chromosomes)*($this->upper_bound - $this->lower_bound)/(pow(2, $this->chromosome_size) - 1);

            $fx = $x + 10*sin(5*$x) + 7*cos(4*$x);//函数值

//            $this->fitness_value[$i] = $fx;
            $this->populations[$i]->fitness = $fx;

        }
    }

    //【排序】
    //对个体按适应度的大小进行排序,并且保存最佳个体
    public function rank(){
        //冒泡，从小到大排序
        for($i = 0; $i < $this->population_size -1; $i ++){
            for($j = $i + 1; $j < $this->population_size; $j ++){
                if($this->populations[$i]->fitness > $this->populations[$j]->fitness){
                    //交换个体
                    $tmp = $this->populations[$i];
                    $this->populations[$i] = $this->populations[$j];
                    $this->populations[$j] = $tmp;
                }
            }
        }

        //计算前i个给个体的适应度之和
        $fitness_sum[0] = $this->populations[0]->fitness;
        for($i = 1; $i < $this->population_size; $i ++){
            $fitness_sum[$i] = $fitness_sum[$i - 1] + $this->populations[$i]->fitness;
        }
        $this->fitness_sum = $fitness_sum;

        //第G代迭代， 个体的平均适应度
        $this->fitness_average[$this->G] = ($fitness_sum[$this->population_size - 1] / $this->population_size);

        //更新最大适应度和对应的迭代次数，保存最佳个体（最佳个体适应度最大）
        if($this->populations[$this->population_size - 1]->fitness > $this->best_fitness){
            $this->best_fitness = $this->populations[$this->population_size - 1]->fitness;
            $this->best_generation = $this->G;
            $this->best_individual = $this->populations[$this->population_size -1]->chromosomes;
        }

    }

    //【选择】
    public function selection(){
        $population_new = [];//保存被选中的个体

        //二分查找实现轮盘赌功能
        for($i = 0; $i < $this->population_size; $i ++){
            $r = (rand(0,10)/10 ) * $this->fitness_sum[$this->population_size - 1];//生成一个随机数，在[0,总适应度] 之间
            $first = 1;
            $last = $this->population_size;
            $mid = round( ($last + $first) / 2 );
            $idx = -1;


            //排中法选择个体
            while(($first <= $last) && ($idx == -1)){
                if($r > $this->fitness_sum[$mid]){
                    $first = $mid;
                }elseif ( $r < $this->fitness_sum[$mid]){
                    $last = $mid;
                }else{
                    $idx = $mid;
                    break;
                }
                $mid = round( ($last + $first) / 2 );
                if(($last - $first) == 1){
                    $idx = $last;
                    break;
                }

            }

            //产生新的个体
            //echo $idx.'=';
            $population_new[$i] = $this->populations[$idx];
        }

        //是否精英选择
        if($this->elitism){
            $p = $this->population_size - 1;
        }else{
            $p = $this->population_size;
        }

        for($i = 0; $i < $p; $i ++){
            if(isset($population_new[$i]))
                $this->populations[$i] = $population_new[$i];
        }

    }

    //【交叉】
    public function crossover(){
        //步长为2, 遍历种群
        for($i = 0; $i < $this->population_size; $i+=2){
            //rand < 交叉概率，对2个个体的染色体进行交叉操作
            $r = $this->randFloat();//产生0~1的随机数
            if($r < $this->cross_rate){
//                $r =$this->randFloat();
//                $cross_pos = round($r * $this->chromosome_size);
                $cross_pos = rand(0, $this->chromosome_size);
                if($cross_pos ==0 || $cross_pos == $this->chromosome_size)
                    continue;
                //对 cross_pos及之后的二进制串进行交换
                $x = $this->populations[$i]->chromosomes;
                $y =  $this->populations[$i+1]->chromosomes;
                $tmp1 = substr($x,0, $cross_pos).substr($y,$cross_pos);
                $tmp2 = substr($y,0,$cross_pos).substr($x, $cross_pos);

                $this->populations[$i]->chromosomes = $tmp1;
                $this->populations[$i+1]->chromosomes = $tmp2;
            }
        }
    }

    //【变异】
    public function mutation(){
        for($i =0; $i < $this->population_size; $i ++){
           if($this->randFloat() < $this->mutate_rate){
               $mutate_pos = rand(0,$this->chromosome_size -1);
               $this->populations[$i]->chromosomes[$mutate_pos] = 1 - $this->populations[$i]->chromosomes[$mutate_pos];
           }

        }
    }



    public function show($data){
        echo '<pre>';
        var_dump($data);
        echo '<hr>';
    }

    //随机产生0-1的小数
    function randFloat($min=0, $max=1){
        return $min + mt_rand()/mt_getrandmax() * ($max-$min);
    }

}

//种群
class Populations
{
    public $population_size;//种群大小
    public $chromosome_size;//染色体长度

    //初始化参数
    public function __construct($population_size, $chromosome_size)
    {
        $this->population_size = $population_size;
        $this->chromosome_size = $chromosome_size;
    }

    //初始化种群
    public function initPop(){
        $pop = [];
        for($i = 0; $i < $this->population_size; $i ++){
            $pop[] = new Individuals($this->chromosome_size);
        }

        return $pop;
    }
}

//个体
class Individuals
{
    public $chromosomes;    //染色体
    public $fitness;        //适应度
    public $value;          //实数

    public $chromosome_size;

    public function __construct($chromosome_size)
    {
        $this->chromosome_size = $chromosome_size;

        for($j = 0; $j < $this->chromosome_size; $j ++){
            $this->chromosomes .=  rand(0, 10) % 2;//产生1-0随机数
        }
    }


}