# How can I calculate the curvature of an extracted contour by opencv?

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:

$|K|&space;=&space;\sqrt{&space;\frac{&space;\left(\frac{d^2y(t)}{dt^2}\frac{dx(t))}{dt}-\frac{d^2x(t)}{dt^2}\frac{dy(t)}{dt}&space;\right&space;)^2&space;}{&space;\left(&space;\frac{d^2x(t)}{dt^2}+\frac{d^2y(t)}{dt^2}&space;\right&space;)^{3}&space;}&space;}$

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) > 10e-4 && std::abs(f2ndDerivative.y) > 10e-4 )
{
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 non-closed 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:

$f'(t)=\lim\limits_{n&space;\rightarrow&space;0}{\frac{f(t+n)-f(t))}{t+n-x}}&space;=&space;\lim\limits_{n&space;\rightarrow&space;0}{\frac{f(t+n)-f(t))}{n}}$

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.

$f_x'(t)=\lim\limits_{n&space;\rightarrow&space;0}{\frac{f_x(t+n)-f_x(t))}{t+n-x}}&space;=&space;\lim\limits_{n&space;\rightarrow&space;0}{\frac{f_x(t+n)-f_x(t))}{n}}&space;\approx&space;\frac{f_x(t+1)-f_x(t))}{1}$

The second derivative is the derivative of the first derivative:

$f_x''(t)=\lim\limits_{n&space;\rightarrow&space;0}{\frac{f_x'(t+n)-f_x'(t))}{t+n-x}}&space;=&space;\lim\limits_{n&space;\rightarrow&space;0}{\frac{f_x'(t+n)-f_x'(t))}{n}}&space;\approx&space;\frac{f_x'(t+1)-f_x'(t))}{1}$

Using the approximation of the first derivative, it yields to:

$f_x''(t)=(f_x(t+2)-f_x(t+1))&space;-&space;(f_x(t+1)-f_x(t))&space;=&space;f_x(t+2)&space;-&space;2f_x(t+1)&space;+&space;f_x(t)$

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
• There are several options for this. I add an explanation to the answer. – Gombat Sep 18 '15 at 7:50
• 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+n-x should be t+n-t). 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()-1-i);
if (maxStep == 0)
{
vecCurvature[i] = std::numeric_limits<double>::infinity();
continue;
}
}

int iminus = i-maxStep;
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) / (iplus-iminus);
f1stDerivative.y =   (pplus.y -        pminus.y) / (iplus-iminus);
f2ndDerivative.x = (pplus.x - 2*pos.x + pminus.x) / ((iplus-iminus)/2*(iplus-iminus)/2);
f2ndDerivative.y = (pplus.y - 2*pos.y + pminus.y) / ((iplus-iminus)/2*(iplus-iminus)/2);

double curvature2D;
double divisor = f1stDerivative.x*f1stDerivative.x + f1stDerivative.y*f1stDerivative.y;
if ( std::abs(divisor) > 10e-8 )
{
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;
}