# Draw fitted line (OpenCV)

I'm using OpenCV to fit a line from a set of points using `cvFitLine()`

`cvFitLine()` returns a normalized vector that is co-linear to the line and a point on the line. See details here

Using this information how can I get the equation of a line so that I can draw the line?

-

If `cvFitLine()` returns normalized vector `(vx,vy)` and point `(x0,y0)`, then the equation of the line is

(x,y) = (x0,y0) + t*(vx,vy)

where `t` runs from −∞ to +∞.

This is what you asked for, but probably isn't immediately helpful in drawing the line. You would want to clip it either to the screen boundaries, or perhaps the bounding box of the the original set of points. To clip a line to a rectangle, just solve for values of `t` where the line crosses the boundary of the rectangle.

-

Just draw a big line instead of solving for the boundaries. eg:

``````cv.Line(img, (x0-m*vx[0], y0-m*vy[0]), (x0+m*vx[0], y0+m*vy[0]), (0,0,0))
``````

will do it for example.. for m large enough :)

-

I used a strategy similar to Karpathy up there but used an extra function. As you can see, I'm using cvClipLine to trim the line to the size of the image, which is unnecessary but does add a little niceness.

Also the multiplier here is defined as theMult = max(img->height,img->width) so we dont get numbers that might one day overflow or something.

``````void drawLine(IplImage * img, float line[4], int thickness,CvScalar color)
{
double theMult = max(img->height,img->width);
// calculate start point
CvPoint startPoint;
startPoint.x = line[2]- theMult*line[0];// x0
startPoint.y = line[3] - theMult*line[1];// y0
// calculate end point
CvPoint endPoint;
endPoint.x = line[2]+ theMult*line[0];//x[1]
endPoint.y = line[3] + theMult*line[1];//y[1]

// draw overlay of bottom lines on image
cvClipLine(cvGetSize(img), &startPoint, &endPoint);
cvLine(img, startPoint, endPoint, color, thickness, 8, 0);
}
``````
-

we use a " Vec4f fitedLine;" for fitted Line in fitLine we have 4 parameters if we consider Line relation az bellow: Y - Y0 = M (X - X0)

we have Y0 = FitedLine[3]; X0 = FitedLine[2]; m = FitedLine[1]/FitedLine[0];

so we have a Line equation we can find other points on it.

-