# I need an equation for equal movement along an ellipse

i am programing something like planets moving around the Sun, and to move planets i am using a function

``````CGPointMake(object.center.x + 1, sqrt(75*75*150*150 - 75*75*(object.center.x - 300)*(object.center.x - 300))/150 + 150)
``````

using eliptic equation where a = 150, b = 75, p = 300, q = 150, but when object closes to x = around 450 its speed rises, i guess that is because of pitagora because the path its passes is c = sqrt((x-x0)^2*(y-y0)^2)

i notice my c is always around 0.5, but when it gets on the end of x domain it rises up to 0.8 so i need either a programatic or mathematical solution to make object move at same speed around an eliptic curve

Thank you!

• This is probably more a math or physics question. But as far as I know, planets to not move with constant speed on their elliptic orbit. – Martin R Nov 5 '14 at 21:42
• i know that, but i either need a equation for real planet movement, or solution to the problem above, becouse like this it looks very unreal – Josip Bogdan Nov 5 '14 at 21:56
• i can solve this by lowering x incerement when object is in x: 150 - 170 range, couse that is where c increases, but that is very bad programing i guess – Josip Bogdan Nov 5 '14 at 22:01
• @JosipBogdan edited my answer. btw it looks like it works even if the `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

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

• Is your statement about the constant speed really true? The speed is `sqrt(rx^2 * sin^2(a(t)) + ry^2 * cos^2(a(t))) * a'(t)`, and that is not constant even if `a'(t)` is constant (only for the special case of a circle). – Martin R Nov 6 '14 at 17:09
• @MartinR ow youre right it is the area that is constant not the arclength – Spektre Nov 6 '14 at 18:58
• @MartinR your equation works added [edit1] to my answer ... the precision of perimeter computation affects this greatly so for high eccentricity is this not very precise. – Spektre Nov 6 '14 at 21:15
• this looks great, sry for not checking it sooner, thank u so much, ive been working on this for a week myself but this solutin is what I needed, real deal, id very much like to buy u a beer – Josip Bogdan Nov 15 '14 at 15:26

Hmm...

You could fake something like this very easily with SpriteKit. N.B. your entire app doesn't have to use SpriteKit. You can fairly easily put an SKView into a non-SpriteKit app.

Anyway...

``````SKSpritNode *planet = [SKSpritNode spriteNodeWithImageNamed:@"mars"];
``````

``````UIBezierPath *ellipse = [UIBezierPath bezierPathWithOvalInRect:/*your rect*/]; //or create it any other way.
``````

Create an action...

``````SKAction *singleOrbit = [SKAction followPath:ellipse.CGPath speed:10];
SKAction *orbit = [SKAction repeatActionForever:singleOrbit];
``````

Run the action...

``````[planet runAction:orbit];
``````