For distance between two GPS coordinates as I googled I realized the best method to use is haversine formula.
The haversine formula is an equation important in navigation, giving great-circle distances between two points on a sphere from their longitudes and latitudes. It is a special case of a more general formula in spherical trigonometry, the law of haversines, relating the sides and angles of spherical “triangles”.
Distance of circle from camera
Some days ago, I was talking to my friends and one of them asked me if I can write a program to measure the distance of the object to the camera, so I told myself why not write a post about it on my blog. I got the idea of writing this code from Adrian’s blog. You can find the code of distance of object to the camera at the end of this post
In order to determine the distance from our camera to a known object or marker, I am going to utilize triangle similarity.
The triangle similarity goes something like this: Let’s say I have a marker or object with a known width W. Then I place this marker some distance D from my camera. I take a picture of my object using our camera and then measure the apparent width in pixels P. This allows me to derive the perceived focal length F of my camera:
F = (P x D) / W
For example, I place a 21 x 29cm piece of paper (vertically; W = 21) D = 20 cm in front of my camera and take a photo. When I measure the width of the piece of paper in the image, I notice that the perceived width of the paper is P = 133 pixels.
My focal length F is then:
F = (1338px x 20cm) / 21cm = 126.35
As I continue to move my camera both closer and farther away from the object/marker, I can apply the triangle similarity to determine the distance of the object to the camera:
D’= (W x F) / P