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I am trying to find the 2D vector in a set that is closest to the provided angle from another vector.

So if I have v(10, 10) and I would like to find the closest other vector along an angle of 90 degrees it should find v(20, 10), for example. I have written a method that I think returns the correct bearing between two vectors.

float getBearing(
    const sf::Vector2f& a, const sf::Vector2f& b)
{
    float degs = atan2f(b.y - a.y, b.x - a.x) * (180 / M_PI);
    return (degs > 0.0f ? degs : (360.0f + degs)) + 90.0f;
}

This seems to work okay although if I place one above another it returns 180, which is fine, and 360, which is just odd. Shouldn't it return 0 if it is directly above it? The best way to do that would be to check for 360 and return 0 I guess.

My problem is that I can't work out the difference between the passed angle, 90 degrees for example, and the one returned from getBearing. I'm not even sure if the returned bearing is correct in all situations.

Can anyone help correct any glaringly obvious mistakes in my bearing method and suggest a way to get the difference between two bearings? I have been hunting through the internet but there are so many ways to do it, most of which are shown in other languages.

Thanks.

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What is the range of the return value? -180 deg to 180 deg or 0 deg to 360 deg? Why are you adding 90 degrees? –  swtdrgn Dec 26 '12 at 15:59
    
I think I have worked out the diff now, I will post that in a second, but it returns 0-360. I have no idea why I have to add 90, but without it everything is shifted round 90 degrees. Almost as if it is always starting from the west, rather than the north like a bearing. –  Olical Dec 26 '12 at 16:03

3 Answers 3

up vote 2 down vote accepted

I would suggest to take the two vectors that are being compared and do an unit dot product. The closest bearing should be greatest, 1 being the maximum (meaning the vectors are pointing to the same direction) and -1 being the minimum (meaning the vectors are pointing to opposite directions).

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+1 although, if only the angle is important (and not its orientation), the relevant quantity is the absolute value of such dot product. –  Matteo Italia Dec 26 '12 at 16:06
    
I agree that this is a better solution for finding the bearing between the vectors. I have added my own answer which shows how I worked out the difference between the bearing and an arbitrary angle. Could I use a similar solution on something from the dot product method? –  Olical Dec 26 '12 at 16:10
1  
Since a·b = |a||b|cos(theta) where theta is the angle between the two vectors, you can find such angle by calculating the arccosine of the dot product of the two normalized vectors (theta=arccos((a·b)/(|a||b|))). –  Matteo Italia Dec 26 '12 at 16:12

If what you need is just to find the vectors nearest to a certain angle, you can follow @swtdrgn method; if, instead, you actually need to compute the angle difference between two vectors, you can exploit a simple property of the dot product:

dot product geometric definition

where theta is the angle between the two vectors; thus, inverting the formula, you get:

inverse of the formula above

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This seems very promising, I am having trouble understanding the actual formula though. I understand the use of acos and the dot product but I have no idea what the arrows or double pipes (|a|) symbolize. Could you possibly write the expression in some kind of pseudo code? I will investigate some of these symbols now anyway, I have just never learnt them. Thank you for your help! –  Olical Dec 26 '12 at 16:22
2  
The arrows mean that a and b are vectors; the "pipes" mean euclidean norm (i.e. the square root of the dot product with itself, i.e. the magnitude of the vector, i.e. that before the dot product a and b have to be normalized). But again, if all you have to do is to find the vector that is nearest to an angle @swtdrgn's solution is the simplest (more straightforward, less calculations) and all in all the best. –  Matteo Italia Dec 26 '12 at 16:26
    
Okay, thank you very much for explaining that. I should really learn this so all those Wikipedia pages will actually be useful to me. I will give the simpler solution a go first and report back here in a minute with an accepted answer. Regardless, thank you for your help. –  Olical Dec 26 '12 at 16:47
2  
@Olical: if you have to work often with vectors you should really read an introductory book on linear algebra, much of this stuff will become obvious. Also, a quick revision of trigonometry won't hurt. :) –  Matteo Italia Dec 26 '12 at 16:49

I have found a solution for now. I have spent a good few hours trying to solve this and I finally do it minutes after asking SO, typical. There may be a much better way of doing this, so I am still open to suggestions from other answers.

I am still using my bearing method from the question at the moment, which will always return a value between 0 and 360. I then get the difference between the returned value and a specified angle like so.

fabs(fmodf(getBearing(vectorA, vectorB) + 180 - angle, 360) - 180);

This will return a positive float that measures the distance in degrees between the bearing between two vectors. @swtdrgn's answer suggests using the dot product of the two vectors, this may be much simpler than my bearing method because I don't actually need the angle, I just need the difference.

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atan2f(b.y - a.y, b.x - a.x) is not the actual angle between the two vectors... if that's what getBearing suppose to do. –  swtdrgn Dec 26 '12 at 16:12
    
getBearing was supposed to return the degrees from 0 (north) to face the other vector. I thought it was returning the correct values when I was logging it. Is this not the case then? Because it seems to be working at the moment. –  Olical Dec 26 '12 at 16:24
1  
In trigonometry angles are normally measured anticlockwise from east... –  Matteo Italia Dec 26 '12 at 16:27
    
That, will be where I'm going wrong. Or one of the places anyway. I will commit what I have already which is a bit nasty and try implementing a suggestion from here. I will accept the one I get working that seems the best. Thank you for your help. –  Olical Dec 26 '12 at 16:40

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