I have a list of 2D points (x1,y1),(x2,y2)......(Xn,Yn) representing a curved segment, is there any formula to determine whether the direction of drawing that segment is clockwise or anti clockwise ?

any help is appreciated

  • 2
    How can a segment have a clockwise/counter-clokwise direction? What is the exact definition?
    – kraskevich
    Aug 11 '14 at 21:29
  • the segment is a curved part of a handwritten arabic character Aug 11 '14 at 21:31
  • 3
    @LuisMendo - Ok I get it. One thing you could possibly do is given the curve, find its centre of mass. Once you do this, find the angle that each point along the curve makes with this centre of mass. After this, use diff and see the neighbouring differences between the points. If the diff elements for each element in this output vector are positive, this could be considered as clockwise, where if it were negative, this could be considered as anti-clockwise. Perhaps make a histogram of positive and negative occurrences and whichever bin has the higher count, that's the direction chosen
    – rayryeng
    Aug 11 '14 at 21:38
  • 1
    @rayryeng I think the ambiguity you refer to can be removed by unwrapping the phase (provided sampling represented by the points is sufficiently fine). That's what I've done in my answer.
    – Luis Mendo
    Aug 11 '14 at 21:50
  • 1
    @LuisMendo - Correct. Forgot about unwrap. Good spot!
    – rayryeng
    Aug 11 '14 at 21:53

Alternately, you can use a bit of linear algebra. If you have three points a, b, and c, in that order, then do the following:

 1)  create the vectors u = (b-a) = (b.x-a.x,b.y-a.y) and v = (c-b) ...
 2) calculate the cross product uxv = u.x*v.y-u.y*v.x
 3) if uxv is -ve then a-b-c is curving in clockwise direction (and vice-versa).

by following a longer curve along in the same manner, you can even detect when as 's'-shaped curve changes from clockwise to anticlockwise, if that is useful.

  • For me it's the best solution by far. +1
    – nicolas
    Aug 11 '14 at 22:16
  • @seb - Never mind. I misread the algorithm. I'm going to delete my comment as it's nonsense.
    – rayryeng
    Aug 11 '14 at 22:21
  • @Penguino: i have N points, i tried your approach but because i have N points i did summation on the result of the cross product of each two successive diff vectors, is that correct ? Aug 11 '14 at 22:29
  • @ahmed: Yes, do something like x1=diff(x) y1=diff(y), then X-product of all consecutive elements of x1 y1
    – nicolas
    Aug 11 '14 at 22:32
  • 1
    @ahmed Yep - if the curve is locally-clockwise along its entire length then you will get all -ve cross products, so summing is fine. But if the curve has the same direction of curvature along its entire length, you can save time by just doing the test on the first three points.
    – Penguino
    Aug 12 '14 at 1:57

One possible approach. It should work reasonably well if the sampling of the line represented by your list of points is uniform and smooth enough, and if the line is sufficiently simple.

  1. Subtract the mean to "center" the line.
  2. Convert to polar coordinates to get the angle.
  3. Unwrap the angle, to make sure its increments are meaningful.
  4. Check if total increment is possitive or negative.

I'm assuming you have the data in x and y vectors.

theta = cart2pol(x-mean(x), y-mean(y)); %// steps 1 and 2
theta = unwrap(theta); %// step 3
clockwise = theta(end)<theta(1); %// step 4. Gives 1 if CW, 0 if ACW

This only considers the integrated effect of all points. It doesn't tell you if there are "kinks" or sections with different directions of turn along the way.

A possible improvement would be to replace the average of x and y by some kind of integral. The reason is: if sampling is denser in a region the average will be biased towards that, whereas the integral wouldn't.

  • Yup... this is pretty much the suggested approach that I wrote! Very nice. I decided to bin all of the differences and see which sign had the higher count, and that's the one I would choose. This is still a good approach.
    – rayryeng
    Aug 11 '14 at 21:55
  • luis i tried your approach and it works :) thaaank you for your help @rayryeng your help is much appreciated thank you too Aug 11 '14 at 22:02
  • 1
    @LuisMendo - I'm favouriting this post, mainly because of the collaboration between different SO users (Yvon, you and myself) to ultimately come up with an answer that worked for the OP. Thanks!
    – rayryeng
    Aug 11 '14 at 22:03
  • @ahmedabobakr - You are very welcome. Glad we could help you solve this problem!
    – rayryeng
    Aug 11 '14 at 22:04
  • 2
    @LuisMendo - That's no problem at all. To be honest, I wasn't sure if my approach would work. Seeing that you posted an answer, and the OP accepting it is confirmation that what I had in my mind worked. Reputation points are only secondary. I'm mostly here to help people, and this post and collaboration is a testament to that.
    – rayryeng
    Aug 11 '14 at 22:16

Now this is my approach, as mentioned in a comment to the question -

Another approach: draw a line from starting point to ending point. This line is indeed a vector. A CW curve has most of its part on RHS of this line. For CCW, left.

I wrote a sample code to elaborate this idea. Most of the explanation can be found in comments in the code.

clear;clc;close all

%% draw a spiral curve
N = 30;
theta = linspace(0,pi/2,N); % a CCW curve
rho = linspace(1,.5,N);
[x,y] = pol2cart(theta,rho);
clearvars theta rho N

hold on

%% find "the vector"
vec(:,:,1) = [x(1), y(1); x(end), y(end)]; % "the vector"

scatter(x(1),y(1), 200,'s','r','fill') % square is the starting point
scatter(x(end),y(end), 200,'^','r','fill') % triangle is the ending point
line(vec(:,1,1), vec(:,2,1), 'LineStyle', '-', 'Color', 'r')

%% find center of mass
com = [mean(x), mean(y)]; % center of mass

vec(:,:,2) = [x(1), y(1); com]; % secondary vector (start -> com)

scatter(com(1), com(2), 200,'d','k','fill') % diamond is the com
line(vec(:,1,2), vec(:,2,2), 'LineStyle', '-', 'Color', 'k')

%% find rotation angle
dif = diff(vec,1,1);
[ang, ~] = cart2pol(reshape(dif(1,1,:),1,[]), reshape(dif(1,2,:),1,[]));
clearvars dif

% now you can tell the answer by the rotation angle
if ( diff(ang)>0 )

One can always tell on which side of the directed line (the vector) a point is, by comparing two vectors, namely, rotating vector [starting point -> center of mass] to the vector [starting point -> ending point], and then comparing the rotation angle to 0. A few seconds of mind-animating can help understand.

  • Not useless! +1 from me... in about 22 minutes. I've reached my maximum amount of votes for today.
    – rayryeng
    Aug 11 '14 at 23:37

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