递归与分形（二）--谢尔斯宾三角形，谢尔斯宾地毯，门格海绵

目录

一、核心点

二、实例

三、总结

 

 

一、核心点

1.把握递归终止条件

2.弄清递归形式。

 

二、实例

1.康托尔集

int yoffset = 10;

public void draw(Graphics g,int n,int x1,int y1,int x2,int y2) {
if(n<1) {  //递归终止条件
return;
}
n--;   
//画线
g.drawLine(x1, y1, x2, y2); 

int tempx = (x2 - x1)/3;
int tempy = (y2 - y1)/3;

draw(g,n,x1,y1+yoffset,x1+tempx,y1+yoffset+tempy);  //递归
draw(g,n,x2-tempx,y2+yoffset-tempy,x2,y2+yoffset);  //递归
}

 

2.谢尔斯宾三角形

    public void draw(Graphics g,int n,int x1,int y1,int x2,int y2,int x3,int y3) {
        int xn1 = (x2+x1)/2;    //画图形
        int yn1 = (y2+y1)/2;
        int xn2 = (x3+x2)/2;
        int yn2 = (y3+y2)/2;
        int xn3 = (x1+x3)/2;
        int yn3 = (y1+y3)/2;
        g.drawLine(xn1, yn1, xn2, yn2);
        g.drawLine(xn2, yn2, xn3, yn3);
        g.drawLine(xn3, yn3, xn1, yn1);
        
        n--;     //递归终止条件
        if(n<0) return;
        
        draw(g,n,x1,y1,xn1,yn1,xn3,yn3);   //递归
        draw(g,n,x2,y2,xn1,yn1,xn2,yn2);
        draw(g,n,x3,y3,xn2,yn2,xn3,yn3);
    }

 

3.谢尔斯宾地毯

 

public void draw(Graphics g,int n,int x1,int y1,int x3,int y3) {
int tempx = (x3 - x1)/3;    //画正方体
int tempy = (y3 - y1)/3;

int xn1 = x1 + tempx;
int yn1 = y1 + tempy;

int xn3 = x1 + tempx * 2;
int yn3 = y1 + tempy * 2;

g.fillRect(xn1, yn1, tempx, tempy);

n--;
if(n<=0) { return;}         //递归结束条件

draw(g,n,x1,y1,xn1,yn1);    //开始递归，八个维度
draw(g,n,x1,yn1,xn1,yn3);
draw(g,n,x1,yn3,xn1,y3);
draw(g,n,xn1,yn3,xn3,y3);
draw(g,n,xn3,yn3,x3,y3);
draw(g,n,xn3,yn1,x3,yn3);
draw(g,n,xn3,y1,x3,yn1);
draw(g,n,xn1,y1,xn3,yn1);
}

 

4.门格海绵

//画立方体
public void draw(Graphics g,int x1 ,int y1,int width,int height,int dx,int dy) {
        
        g.setColor(new Color(0,160,160));
        g.fillRect(x1 , y1, width, height);
        
        int[] xx1 = {x1,x1+width,x1+width+dx,x1+dx};
        int[] yy1 = {y1,y1,y1-dy,y1-dy};
        g.setColor(new Color(0,50,50));
        
        g.fillPolygon(xx1, yy1, 4);
        
        int[] xx2 = {x1+width,x1+width+dx,x1+width+dx,x1+width};
        int[] yy2 = {y1,y1-dy,y1-dy+height,y1+height};
        g.setColor(new Color(0,100,100));
        g.fillPolygon(xx2, yy2, 4);
    }
   //递归 
    public void drawMGHM(int n,Graphics g,int x1,int y1,int width,int height,int dx,int dy) {
        
        n--;
        if(n<0) {   //往里递归结束的时候，开始画   画出基本单元就开始递归
            draw(g,x1,y1,width,height,dx,dy);
            return;
        }
        width = width/3;     //长度缩减为1/3
        height = height/3;
        dx = dx/3;
        dy = dy/3;
                
                //frist
//                draw(g,x1,y1,width,height,dx,dy);               //1
//                draw(g,x1-dx,y1+dy,width,height,dx,dy);         //4
//                draw(g,x1-2*dx,y1+2*dy,width,height,dx,dy);     //7
//                draw(g,x1+width,y1,width,height,dx,dy);         //2
//                draw(g,x1+2*width,y1,width,height,dx,dy);       //3
//                draw(g,x1+2*width-dx,y1+dy,width,height,dx,dy); //6
//                draw(g,x1+width-2*dx,y1+2*dy,width,height,dx,dy);    //8
//                draw(g,x1+2*width-2*dx,y1+2*dy,width,height,dx,dy);  //9
//                //second
//                draw(g,x1,y1-height,width,height,dx,dy);   //1
//                draw(g,x1+2*width,y1-height,width,height,dx,dy);       //3
//                draw(g,x1-2*dx,y1+2*dy-height,width,height,dx,dy);     //7
//                draw(g,x1+2*width-2*dx,y1+2*dy-height,width,height,dx,dy);  //9
//                //third
//                draw(g,x1,y1-2*height,width,height,dx,dy);      //1
//                draw(g,x1-dx,y1+dy-2*height,width,height,dx,dy);         //4
//                draw(g,x1-2*dx,y1+2*dy-2*height,width,height,dx,dy);     //7
//                draw(g,x1+width,y1-2*height,width,height,dx,dy);         //2
//                draw(g,x1+2*width,y1-2*height,width,height,dx,dy);       //3
//                draw(g,x1+2*width-dx,y1+dy-2*height,width,height,dx,dy); //6
//                draw(g,x1+width-2*dx,y1+2*dy-2*height,width,height,dx,dy);    //8
//                draw(g,x1+2*width-2*dx,y1+2*dy-2*height,width,height,dx,dy);  //9
                

　　　　　　　　　　//20个维度的递归
                //frist
                drawMGHM(n,g,x1,y1,width,height,dx,dy);               //1
                drawMGHM(n,g,x1-dx,y1+dy,width,height,dx,dy);         //4
                drawMGHM(n,g,x1-2*dx,y1+2*dy,width,height,dx,dy);     //7
                drawMGHM(n,g,x1+width,y1,width,height,dx,dy);         //2
                drawMGHM(n,g,x1+2*width,y1,width,height,dx,dy);       //3
                drawMGHM(n,g,x1+2*width-dx,y1+dy,width,height,dx,dy); //6
                drawMGHM(n,g,x1+width-2*dx,y1+2*dy,width,height,dx,dy);    //8
                drawMGHM(n,g,x1+2*width-2*dx,y1+2*dy,width,height,dx,dy);  //9
                //second
                drawMGHM(n,g,x1,y1-height,width,height,dx,dy);   //1
                drawMGHM(n,g,x1+2*width,y1-height,width,height,dx,dy);       //3
                drawMGHM(n,g,x1-2*dx,y1+2*dy-height,width,height,dx,dy);     //7
                drawMGHM(n,g,x1+2*width-2*dx,y1+2*dy-height,width,height,dx,dy);  //9
                //third
                drawMGHM(n,g,x1,y1-2*height,width,height,dx,dy);      //1
                drawMGHM(n,g,x1-dx,y1+dy-2*height,width,height,dx,dy);         //4
                drawMGHM(n,g,x1-2*dx,y1+2*dy-2*height,width,height,dx,dy);     //7
                drawMGHM(n,g,x1+width,y1-2*height,width,height,dx,dy);         //2
                drawMGHM(n,g,x1+2*width,y1-2*height,width,height,dx,dy);       //3
                drawMGHM(n,g,x1+2*width-dx,y1+dy-2*height,width,height,dx,dy); //6
                drawMGHM(n,g,x1+width-2*dx,y1+2*dy-2*height,width,height,dx,dy);    //8
                drawMGHM(n,g,x1+2*width-2*dx,y1+2*dy-2*height,width,height,dx,dy);  //9
    }

门格海绵，特殊点在于图形是立体的，通过不同面不同颜色来体现立体感。不能递归的时候画，必须根据图形覆盖原理，由里往外画，由上往下画，所以必须在往里递归的结束时候才能开始画。

 

 

三、总结

分形可以帮助理解递归，让初学递归的人更清楚更清晰的感觉到递归过程。画分形的过程也需要使用到递归这一方法。两者相互结合。

用递归画分形图形，可以先画出基本单元，画出基本单元后，再将画的基本单元替换为递归函数即可。画立体图形需从由里往外画，由上往下画，以免被覆盖。

最后一句，分形很美。