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Lets say you have this:

P1 = (x=2, y=50)
P2 = (x=9, y=40)
P3 = (x=5, y=20)

Assume that P1 is the center point of a circle. It is always the same. I want the angle that is made up by P2 and P3, or in other words the angle that is next to P1. The inner angle to be precise. It will always be an acute angle, so less than -90 degrees.

I thought: Man, that's simple geometry math. But I have looked for a formula for around 6 hours now, and only find people talking about complicated NASA stuff like arccos and vector scalar product stuff. My head feels like it's in a fridge.

Some math gurus here that think this is a simple problem? I don't think the programming language matters here, but for those who think it does: java and objective-c. I need it for both, but haven't tagged it for these.

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Not programming related (you didn't specify language, platform or what you've tried yourself). However check this out – Binary Worrier Jul 31 '09 at 7:59
Is the circle, by chance, a unit circe (radius of 1)? – Nosredna Aug 30 '09 at 16:00
atan2(P2.y - P1.y, P2.x - P1.x) - atan2(P3.y - P1.y, P3.x - P1.x) – Jim Balter Apr 9 '15 at 2:53

13 Answers 13

up vote 55 down vote accepted

If you mean the angle that P1 is the vertex of then this should work:

arccos((P122 + P132 - P232) / (2 * P12 * P13))

where P12 is the length of the segment from P1 to P2, calculated by

sqrt((P1x - P2x)2 + (P1y - P2y)2)

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1 – Matt W Feb 15 '12 at 9:26
@Rafa Firenze cos^-1 is a common notation for acos, but acos is less ambiguous. – geon Oct 21 '14 at 13:27
I'll leave the edit since it doesn't hurt anything, but having Math/CS/EE degrees, cos^-1 is certainly the most common notation. – Lance Roberts Oct 21 '14 at 14:00
Only a handful of languages use a caret for 'power of', so if you don't want to call it arcos, please just type cos⁻¹. (If you're using a commercial operating system that makes it difficult to type exponents, I expect there would be keycaps applications you could buy, or maybe a browser plug-in you could install. Or you can websearch and copy and paste.) – Michael Scheper Mar 3 '15 at 20:55
@MichaelScheper, I was only using the caret in the comments where html is limited. I would certainly just use the sub/superscript notation in any actual answer. – Lance Roberts Mar 3 '15 at 22:43

If you have 3 points, you have a triangle who's edge lengths are all known. So use the cosine rule:

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It gets very simple if you think it as two vectors, one from point P1 to P2 and one from P1 to P3

a = (p1.x - p2.x, p1.y - p2.y)
b = (p1.x - p3.x, p1.y - p3.y)

You can then invert the dot product formula:
dot product
to get the angle:
angle between two vectors

Remember that dot product just means: a1*b1 + a2*b2 (just 2 dimensions here...)

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What is |x| again? – Daniel Little Mar 16 '15 at 0:31
Ah magnitude of the vector – Daniel Little Mar 16 '15 at 1:04

Basically what you have is two vectors, one vector from P1 to P2 and another from P1 to P3. So all you need is an formula to calculate the angle between two vectors.

Have a look here for a good explanation and the formula.

alt text

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If you are thinking of P1 as the center of a circle, you are thinking too complicated. You have a simple triangle, so your problem is solveable with the law of cosines. No need for any polar coordinate tranformation or somesuch. Say the distances are P1-P2 = A, P2-P3 = B and P3-P1 = C:

Angle = arccos ( (B^2-A^2-C^2) / 2AC )

All you need to do is calculate the length of the distances A, B and C. Those are easily available from the x- and y-coordinates of your points and Pythagoras' theorem

Length = sqrt( (X2-X1)^2 + (Y2-Y1)^2 )

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Let me give an example in JavaScript, I've fought a lot with that:

 * Calculates the angle (in radians) between two vectors pointing outward from one center
 * @param p0 first point
 * @param p1 second point
 * @param c center point
function find_angle(p0,p1,c) {
    var p0c = Math.sqrt(Math.pow(c.x-p0.x,2)+
                        Math.pow(c.y-p0.y,2)); // p0->c (b)   
    var p1c = Math.sqrt(Math.pow(c.x-p1.x,2)+
                        Math.pow(c.y-p1.y,2)); // p1->c (a)
    var p0p1 = Math.sqrt(Math.pow(p1.x-p0.x,2)+
                         Math.pow(p1.y-p0.y,2)); // p0->p1 (c)
    return Math.acos((p1c*p1c+p0c*p0c-p0p1*p0p1)/(2*p1c*p0c));

Bonus: Example with HTML5-canvas

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You can make this more efficient by doing less sqrt and squaring. See my answer here (written in Ruby), or in this updated demo (JavaScript). – Phrogz Feb 11 '14 at 4:46

I ran into a similar problem recently, only I needed to differentiate between a positive and negative angles. In case this is of use to anyone, I recommend the code snippet I grabbed from this mailing list about detecting rotation over a touch event for Android:

 public boolean onTouchEvent(MotionEvent e) {
    float x = e.getX();
    float y = e.getY();
    switch (e.getAction()) {
    case MotionEvent.ACTION_MOVE:
       //find an approximate angle between them.

       float dx = x-cx;
       float dy = y-cy;
       double a=Math.atan2(dy,dx);

       float dpx= mPreviousX-cx;
       float dpy= mPreviousY-cy;
       double b=Math.atan2(dpy, dpx);

       double diff  = a-b;
       this.bearing -= Math.toDegrees(diff);
    mPreviousX = x;
    mPreviousY = y;
    return true;
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In Objective-C you could do this by

float xpoint = (((atan2((newPoint.x - oldPoint.x) , (newPoint.y - oldPoint.y)))*180)/M_PI);

Or read more here

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Uh, no. There are three points, the center is not at (0,0), and this gives an angle of a right triangle, not the angle of the apex. And what sort of name is "xpoint" for an angle? – Jim Balter Apr 9 '15 at 5:08

You mentioned a signed angle (-90). In many applications angles may have signs (positive and negative, see If the points are (say) P2(1,0), P1(0,0), P3(0,1) then the angle P3-P1-P2 is conventionally positive (PI/2) whereas the angle P2-P1-P3 is negative. Using the lengths of the sides will not distinguish between + and - so if this matters you will need to use vectors or a function such as Math.atan2(a, b).

Angles can also extend beyond 2*PI and while this is not relevant to the current question it was sufficiently important that I wrote my own Angle class (also to make sure that degrees and radians did not get mixed up). The questions as to whether angle1 is less than angle2 depends critically on how angles are defined. It may also be important to decide whether a line (-1,0)(0,0)(1,0) is represented as Math.PI or -Math.PI

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The best way to deal with angle computation is to use atan2(y, x) that given a point x, y returns the angle from that point and the X+ axis in respect to the origin.

Given that the computation is

double result = atan2(P3.y - P1.y, P3.x - P1.x) -
                atan2(P2.y - P1.y, P2.x - P1.x);

i.e. you basically translate the two points by -P1 (in other words you translate everything so that P1 ends up in the origin) and then you consider the difference of the absolute angles of P3 and of P2.

The advantages of atan2 is that the full circle is represented (you can get any number between -π and π) where instead with acos you need to handle several cases depending on the signs to compute the correct result.

The only singular point for atan2 is (0, 0)... meaning that both P2 and P3 must be different from P1 as in that case doesn't make sense to talk about an angle.

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my angle demo program

Recently, I too have the same problem... In Delphi It's very similar to Objective-C.

procedure TForm1.FormPaint(Sender: TObject);
var ARect: TRect;
    AWidth, AHeight: Integer;
    ABasePoint: TPoint;
    AAngle: Extended;
  FCenter := Point(Width div 2, Height div 2);
  AWidth := Width div 4;
  AHeight := Height div 4;
  ABasePoint := Point(FCenter.X+AWidth, FCenter.Y);
  ARect := Rect(Point(FCenter.X - AWidth, FCenter.Y - AHeight),
    Point(FCenter.X + AWidth, FCenter.Y + AHeight));
  AAngle := ArcTan2(ClickPoint.Y-Center.Y, ClickPoint.X-Center.X) * 180 / pi;
  AngleLabel.Caption := Format('Angle is %5.2f', [AAngle]);
  Canvas.MoveTo(FCenter.X, FCenter.Y);
  Canvas.LineTo(FClickPoint.X, FClickPoint.Y);
  Canvas.MoveTo(FCenter.X, FCenter.Y);
  Canvas.LineTo(ABasePoint.X, ABasePoint.Y);
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Few days ago, a fell into the same problem & had to sit with the math book. I solved the problem by combining and simplifying some basic formulas.

enter image description here

Here is a C# method that calculates the angle (ϴ)-

    private double calculateAngle(double P1X, double P1Y, double P2X, double P2Y, double P3X, double P3Y){
        double numerator = P2Y*(P1X-P3X) + P1Y*(P3X-P2X) + P3Y*(P2X-P1X);
        double denominator = 1 + (P2Y-P1Y)*(P1Y-P3Y);
        double ratio = numerator/denominator;

        double angleRad = Math.Atan(ratio);
        double angleDeg = (angleRad*180)/Math.PI;

            angleDeg = 180+angleDeg;

        return angleDeg;
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Swift 2.2 version:

func angleBetween (a: CGPoint, _ b: CGPoint, _ c: CGPoint) -> CGFloat {
    let x1 = a.x - b.x, x2 = c.x - b.x
    let y1 = a.y - b.y, y2 = c.y - b.y
    let d1 = sqrt (x1 * x1 + y1 * y1)
    let d2 = sqrt (x2 * x2 + y2 * y2)
    return acos ((x1 * x2 + y1 * y2) / (d1 * d2))
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