I did use the findcontours()
method to extract contour from the image, but I have no idea how to calculate the curvature from a set of contour points. Can somebody help me? Thank you very much!

It would help enormously if you provide us with the list of things you have already tried and with a more specific question. – YePhIcK Sep 17 '15 at 12:12
For me curvature is:
where t
is the position inside the contour and x(t)
resp. y(t)
return the related x
resp. y
value. See here.
So, according to my definition of curvature, one can implement it this way:
std::vector< float > vecCurvature( vecContourPoints.size() );
cv::Point2f posOld, posOlder;
cv::Point2f f1stDerivative, f2ndDerivative;
for (size_t i = 0; i < vecContourPoints.size(); i++ )
{
const cv::Point2f& pos = vecContourPoints[i];
if ( i == 0 ){ posOld = posOlder = pos; }
f1stDerivative.x = pos.x  posOld.x;
f1stDerivative.y = pos.y  posOld.y;
f2ndDerivative.x =  pos.x + 2.0f * posOld.x  posOlder.x;
f2ndDerivative.y =  pos.y + 2.0f * posOld.y  posOlder.y;
float curvature2D = 0.0f;
if ( std::abs(f2ndDerivative.x) > 10e4 && std::abs(f2ndDerivative.y) > 10e4 )
{
curvature2D = sqrt( std::abs(
pow( f2ndDerivative.y*f1stDerivative.x  f2ndDerivative.x*f1stDerivative.y, 2.0f ) /
pow( f2ndDerivative.x + f2ndDerivative.y, 3.0 ) ) );
}
vecCurvature[i] = curvature2D;
posOlder = posOld;
posOld = pos;
}
It works on nonclosed pointlists as well. For closed contours, you may would like to change the boundary behavior (for the first iterations).
UPDATE:
Explanation for the derivatives:
A derivative for a continuous 1 dimensional function f(t)
is:
But we are in a discrete space and have two discrete functions f_x(t)
and f_y(t)
where the smallest step for t
is one.
The second derivative is the derivative of the first derivative:
Using the approximation of the first derivative, it yields to:
There are other approximations for the derivatives, if you google it, you will find a lot.

Thanks for your comment.But i don't understand why f1stDerivative.x and f2ndDerivative.x can calculate as the formule you show in the code? – kookoo121 Sep 18 '15 at 5:49


I have tried the code you post.But i got many value as 1.#IND000000000000? – kookoo121 Sep 18 '15 at 12:28

That occures when both derivative values in the denominator are zero. I update the code. Now, there's an additional check and otherwise the curvature is zero. – Gombat Sep 18 '15 at 12:29

But maybe the problem was, that the argument of sqrt has been negative. Added a
std::abs
call. – Gombat Sep 18 '15 at 13:17
While the theory behind Gombat's answer is correct, there are some errors in the code as well as in the formulae (the denominator t+nx
should be t+nt
). I have made several changes:
 use symmetric derivatives to get more precise locations of curvature maxima
 allow to use a step size for derivative calculation (can be used to reduce noise from noisy contours)
 works with closed contours
Fixes: * return infinity as curvature if denominator is 0 (not 0) * added square calculation in denominator * correct checking for 0 divisor
std::vector<double> getCurvature(std::vector<cv::Point> const& vecContourPoints, int step)
{
std::vector< double > vecCurvature( vecContourPoints.size() );
if (vecContourPoints.size() < step)
return vecCurvature;
auto frontToBack = vecContourPoints.front()  vecContourPoints.back();
std::cout << CONTENT_OF(frontToBack) << std::endl;
bool isClosed = ((int)std::max(std::abs(frontToBack.x), std::abs(frontToBack.y))) <= 1;
cv::Point2f pplus, pminus;
cv::Point2f f1stDerivative, f2ndDerivative;
for (int i = 0; i < vecContourPoints.size(); i++ )
{
const cv::Point2f& pos = vecContourPoints[i];
int maxStep = step;
if (!isClosed)
{
maxStep = std::min(std::min(step, i), (int)vecContourPoints.size()1i);
if (maxStep == 0)
{
vecCurvature[i] = std::numeric_limits<double>::infinity();
continue;
}
}
int iminus = imaxStep;
int iplus = i+maxStep;
pminus = vecContourPoints[iminus < 0 ? iminus + vecContourPoints.size() : iminus];
pplus = vecContourPoints[iplus > vecContourPoints.size() ? iplus  vecContourPoints.size() : iplus];
f1stDerivative.x = (pplus.x  pminus.x) / (iplusiminus);
f1stDerivative.y = (pplus.y  pminus.y) / (iplusiminus);
f2ndDerivative.x = (pplus.x  2*pos.x + pminus.x) / ((iplusiminus)/2*(iplusiminus)/2);
f2ndDerivative.y = (pplus.y  2*pos.y + pminus.y) / ((iplusiminus)/2*(iplusiminus)/2);
double curvature2D;
double divisor = f1stDerivative.x*f1stDerivative.x + f1stDerivative.y*f1stDerivative.y;
if ( std::abs(divisor) > 10e8 )
{
curvature2D = std::abs(f2ndDerivative.y*f1stDerivative.x  f2ndDerivative.x*f1stDerivative.y) /
pow(divisor, 3.0/2.0 ) ;
}
else
{
curvature2D = std::numeric_limits<double>::infinity();
}
vecCurvature[i] = curvature2D;
}
return vecCurvature;
}