I'm going to assume you're using C++, but the answer should be the same if you're using C or Python.

The function `minAreaRect`

seems to give angles ranging from -90 to 0 degrees, not including zero, so an interval of [-90, 0).

The function gives -90 degrees if the rectangle it outputs isn't rotated, i.e. the rectangle has two sides exactly horizontal and two sides exactly vertical. As the rectangle rotates clockwise, the angle increases (goes towards zero). When zero is reached, the angle given by the function ticks back over to -90 degrees again.

So if you have a long rectangle from `minAreaRect`

, and it's lying down flat, `minAreaRect`

will call the angle -90 degrees. If you rotate the image until the rectangle given by `minAreaRect`

is perfectly upright, then the angle will say -90 degrees again.

I didn't actually know any of this (I procrastinated from my OpenCV project to find out how it works :/). Anyway, here's an OpenCV program that demonstrates `minAreaRect`

if I haven't explained it clear enough already:

```
#include <stdio.h>
#include <opencv\cv.h>
#include <opencv\highgui.h>
using namespace cv;
int main() {
float angle = 0;
Mat image(200, 400, CV_8UC3, Scalar(0));
RotatedRect originalRect;
Point2f vertices[4];
vector<Point2f> vertVect;
RotatedRect calculatedRect;
while (waitKey(5000) != 27) {
// Create a rectangle, rotating it by 10 degrees more each time.
originalRect = RotatedRect(Point2f(100,100), Size2f(100,50), angle);
// Convert the rectangle to a vector of points for minAreaRect to use.
// Also move the points to the right, so that the two rectangles aren't
// in the same place.
originalRect.points(vertices);
for (int i = 0; i < 4; i++) {
vertVect.push_back(vertices[i] + Point2f(200, 0));
}
// Get minAreaRect to find a rectangle that encloses the points. This
// should have the exact same orientation as our original rectangle.
calculatedRect = minAreaRect(vertVect);
// Draw the original rectangle, and the one given by minAreaRect.
for (int i = 0; i < 4; i++) {
line(image, vertices[i], vertices[(i+1)%4], Scalar(0, 255, 0));
line(image, vertVect[i], vertVect[(i+1)%4], Scalar(255, 0, 0));
}
imshow("rectangles", image);
// Print the angle values.
printf("---\n");
printf("Original angle: %7.2f\n", angle);
printf("Angle given by minAreaRect: %7.2f\n", calculatedRect.angle);
printf("---\n");
// Reset everything for the next frame.
image = Mat(200, 400, CV_8UC3, Scalar(0));
vertVect.clear();
angle+=10;
}
return 0;
}
```

This lets you easily see how the angle, and shape, of a manually drawn rectangle compares to the `minAreaRect`

interpretation of the same rectangle.