**If you want the real thing**

then the planets closer to the primary focus point (center of mass of stellar system ... **very close** to star) are moving faster so use **Kepler's equation** here: C++ implementation of mine. Do not forget to check out all the sub-links in that answer you can find there everything you need.

**If you want constant speed instead**

Then use parametric ellipse equation

```
x(a)=x0+rx*cos(a)
y(a)=y0+ry*sin(a)
```

where `a`

is angle `<0,2.0*PI>`

`(x0,y0)`

is the ellipse center and `(rx,ry)`

are the ellipse semi axises (radii).

if `a`

is incremented with constant speed then the area increase is constant so the `a`

is the mean circular angle not the visual on ellipse !!! For more info look here:

**[edit1] as MartinR pointed out the speed is not constant**

so here is approximation with his formula for speed. Ellipse is axis aligned defined by `x0,y0,rx,ry`

`(rx>=ry)`

the perimeter aproximation `l`

:

```
h=(rx-ry)/(rx+ry); h*=3.0*h; l=M_PI*(rx+ry)*(1.0+(h/(10.0+sqrt(4.0-h))));
```

if you want to have `n`

chunks of equal sized steps along the perimeter then

```
l/=n;
```

initial computations:

```
double x0,y0,rx,ry,n,l,h;
x0=Form1->ClientWidth>>1; // center is centered on form
y0=Form1->ClientHeight>>1;
rx=200; // semiaxises rx>=ry !!!
ry=75;
n=40.0; // number of chunks per ellipse (1/speed)
//l=2.0*M_PI*sqrt(0.5*((rx*rx)+(ry*ry))); // not accurate enough
h=(rx-ry)/(rx+ry); h*=3.0*h; l=M_PI*(rx+ry)*(1.0+(h/(10.0+sqrt(4.0-h)))); // this is more precise
l/=n; // single step size in units,pixels,or whatever
```

first the slow bruteforce attack (black):

```
int i;
double a,da,x,y,xx,yy,ll;
a=0.0;
x=x0+rx*cos(a);
y=y0+ry*sin(a);
for (i=n;i>0;i--)
{
xx=x; yy=y;
for (da=a;;)
{
a+=0.001;
x=x0+rx*cos(a);
y=y0+ry*sin(a);
ll=sqrt(((xx-x)*(xx-x))+((yy-y)*(yy-y)));
if (ll>=l) break;
} da=a-da;
scr->MoveTo(5.0+50.0*a,5.0);
scr->LineTo(5.0+50.0*a,5.0+300.0*da);
scr->MoveTo(x0,y0);
scr->LineTo(xx,yy);
scr->LineTo(x ,y );
ll=sqrt(((xx-x)*(xx-x))+((yy-y)*(yy-y)));
scr->TextOutA(0.5*(x+xx)+20.0*cos(a),0.5*(y+yy)+20.0*sin(a),floor(ll));
}
```

Now the approximation (Blue):

```
a=0.0; da=0;
x=x0+rx*cos(a);
y=y0+ry*sin(a);
for (i=n;i>0;i--)
{
scr->MoveTo(5.0+50.0*a,5.0+300.0*da);
xx=rx*sin(a);
yy=ry*cos(a);
da=l/sqrt((xx*xx)+(yy*yy)); a+=da;
scr->LineTo(5.0+50.0*a,5.0+300.0*da);
xx=x; yy=y;
x=x0+rx*cos(a);
y=y0+ry*sin(a);
scr->MoveTo(x0,y0);
scr->LineTo(xx,yy);
scr->LineTo(x ,y );
ll=sqrt(((xx-x)*(xx-x))+((yy-y)*(yy-y)));
scr->TextOutA(0.5*(x+xx)+40.0*cos(a),0.5*(y+yy)+40.0*sin(a),floor(ll));
}
```

This is clean ellipse step (no debug draws)

```
a=???; // some initial angle
// point on ellipse
x=x0+rx*cos(a);
y=y0+ry*sin(a);
// next angle by almost constant speed
xx=rx*sin(a);
yy=ry*cos(a);
da=l/sqrt((xx*xx)+(yy*yy)); a+=da;
// next point on ellipse ...
x=x0+rx*cos(a);
y=y0+ry*sin(a);
```

Here the output of comparison bruteforce and approximation:

**[edit2] little precision boost**

```
a,da=???; // some initial angle and step (last)
x=x0+rx*cos(a);
y=y0+ry*sin(a);
// next angle by almost constant speed
xx=rx*sin(a+0.5*da); // use half step angle for aproximation ....
yy=ry*cos(a+0.5*da);
da=l/sqrt((xx*xx)+(yy*yy)); a+=da;
// next point on ellipse ...
x=x0+rx*cos(a);
y=y0+ry*sin(a);
```

the half step angle in approximation lead to much closer result to bruteforce attack

notmove with constant speed on their elliptic orbit. – Martin R Nov 5 '14 at 21:42`rx<=ry`

(but not sure if in all circumstances ... the only thing that could go wrong is perimeter computation) – Spektre Nov 6 '14 at 21:18