# Simplified question

How do you convert a spherical coordinate (θ, φ) into a position (x, y) on an equirectangular projection (also called 'geographic projection')?

In which:

• x is longitude, the horizontal position, from -180 to 180 degrees.
• y is latitude, the vertical position, from -90 to 90 degrees.
• θ is theta, the horizontal angle in degrees, a vector from (0,0,0) to a point on the surface of a sphere.
• φ is phi, the vertical angle in degrees, a vector from (0,0,0) to a point on the surface of a sphere.

Below you find the original question, back when I did not understand the problem well, but I think that it is still good for showing what is a practical application of this solution.

# Context

Edit: The original question title was: How to transform a photo at a given angle to become a part of a panorama photo?

Can anybody help me with which steps I should take if I want to transform a photo taken at any given angle in such a way that I can place the resulting (distorted/transformed) image at the corresponding specific location on an equirectangular projection, cube map, or any panorama photo projection?

Whichever projection is easiest to do is good enough, because there are plenty of resources on how to convert between different projections. I just don't know how to do the step from an actual photo to such a projection.

It is safe to assume that the camera will stay at a fixed location, and can rotate in any direction from there. The data that I think is required to do this, is probably something like this:

• Horizontal angle of physical camera `[-180, +180]` (e.g. +140deg).
• Vertical angle of physical camera `[-90, +90]` (e.g. -30deg).
• Resolution of photo `w x h` (e.g. 1280x720 pixels).
• Horizontal angle of photo (e.g. 70deg).
• Vertical angle of photo (e.g. 40deg).
• Lens correction a, b, c parameters (see below).

I have this data, and I guess the first step is to do lens correction so that all lines that should be straight are in fact straight. And this can be done using `imagemagick`'s Barrel Distortion, in which you only need to fill in three parameters: a, b, and c. The transformation that is applied to the image to correct this is straightforward.

I am stuck on the next step. Either I do not fully understand it, or search engines are not helping me, because most results are about converting between already given projections or use advanced applications to stitch photos intelligently together. These results did not help me with answering my question.

EDIT: I figured that maybe a figure will help explaining it better :)

The problem is that a given photo Red cannot be placed into the equirectangular projection without a transformation. The figure below illustrates the problem. So, I have Red, and I need to transform it into Green. Blue shows the difference in transformation, but this depends on the horizontal/vertical angle.

• The Equirectangular Projection, in the simplest case, doesn't change numbers at all. The projected x coordinate equals the longitude θ, the projected y coordinate equals the latitude φ. Constant factors are chosen to chose the latitude that shows zero distortion. In your application, you will likely have a subsequent scaling / translation to get pixel coordinates. – tiwo May 12 '17 at 10:14
• Image stitching usually involves "advanced" corrections because in practice, exact projection parameters, (θ, φ but also camera parameters), are unknown and hard to obtain. – tiwo May 12 '17 at 10:16
• @tiwo, not really, I have already solved the problem but I haven't found the time to post an answer yet. Will do that somewhere next week. The resulting projection is not pixel precise, but good enough to look at it without zooming in on the edges of the individual photos (I should add blurring near border to further reduce the transition-artifact). – Yeti May 12 '17 at 11:45
• @Yeto glad to hear, sounds like a good pragmatic solution :-) – tiwo May 12 '17 at 13:45

If photos are taken from a fixed point, and the camera can only rotate its yaw and pitch around that point. Then we can consider a sphere of any radius (for the math, it is highly recommended to use a radius of 1). The photo will be a rectangular shape on this sphere (from perspective of the camera).

# Horizon-case

If you are looking at the horizon (equator), then vertical pixels account for latitude, and horizontal pixels account for longitude. For a simple panorama photo of the horizon there is not much of a problem: Here we look at roughly the horizon of our world. That is, the camera has angle `va = ~0`. Then this is pretty straightforward, because if we know that the photo is 70 degrees wide and 40 degrees high, then we also know that the longitude range will be approximately 70 degrees and latitude range 40 degrees.

If we don't care about a slight distortion, then the formula to calculate the `(longitude,latitude)` from any pixel `(x,y)` from the photo would be easy:

``````photo_width_deg = 70
photo_height_deg = 30
photo_width_px = 1280
photo_height_px = 720
ha = 0
va = 0
longitude = photo_width_deg * (x - photo_width_px/2) / photo_width_px + ha
latitude = photo_height_deg * (y - photo_height_px/2) / photo_height_px + va
``````

# Problem

But this approximation does not work at all when we move the camera much more vertically: So how do we transform a pixel from the picture at `(x, y)` to a `(longitude, latitude)` coordinate given a vertical/horizontal angle at which the photo was taken `(va,ha)`?

# Solution

The important idea that solved the problem for me is this: you basically have two spheres:

• The photo-sphere with the camera in the center.
• The geo-sphere (equirectangular projection sphere), with longitude/latitude coordinates.

You know the spherical coordinate of a point on the photo-sphere, and you want to know where this point is on the geo-sphere with the different camera-angle.

# The real problem

We have to realize that it is difficult to do any calculations between the two spheres using just spherical coordinates. The math for the cartesian coordinate system is much simpler. In the cartesian coordinate system we can easily rotate around any axis using rotation matrices that are multiplied with the coordinate vector `[x,y,z]` to get the rotated coordinate back.

Warning: Here it is very important to know that there are different conventions with regard to the meaning of `x`-axis, `y`-axis, and `z`-axis. It is uncertain which axis is the vertical one, and which one points where to. You just have to make a drawing for yourself and decide on this. If the result is wrong, it's probably because these are mixed up. The same goes for the `theta` and `phi` for spherical coordinates.

# The real solution

So the trick is to transform from photo-sphere to cartesian, then apply the rotations, and then go back to spherical coordinates:

1. Take any pixel on the photo, and calculate the relative degrees it is away from the center of the photo both horizontally and vertically.
2. Transform the photo-sphere spherical coordinates into cartesian coordinates (`[x,y,z]` vectors).
3. Apply rotation matrices to the coordinate just like the camera was rotated `(ha,va)`.
4. Transform the cartesian coordinates back to spherical coordinates, and these will be your longitude and latitude.

# Example code

``````// Photo resolution
double img_w_px = 1280;
double img_h_px = 720;
// Camera field-of-view angles
double img_ha_deg = 70;
double img_va_deg = 40;
// Camera rotation angles
double hcam_deg = 230;
double vcam_deg = 60;
// Camera rotation angles in radians
// Rotation around y-axis for vertical rotation of camera
Matrix rot_y = {
0, 1, 0,
};
// Rotation around z-axis for horizontal rotation of camera
Matrix rot_z = {
0, 0, 1
};

for(int i=0;i<img_h_px;++i)
{
for(int j=0;j<img_w_px;++j)
{
Pixel p = img.getPixelAt(i, j);

// Calculate relative position to center in degrees
double p_theta = (j - img_w_px / 2.0) / img_w_px * img_w_deg / 180.0 * PI;
double p_phi = -(i - img_h_px / 2.0) / img_h_px * img_h_deg / 180.0 * PI;

// Transform into cartesian coordinates
double p_x = cos(p_phi) * cos(p_theta);
double p_y = cos(p_phi) * sin(p_theta);
double p_z = sin(p_phi);
Vector p0 = {p_x, p_y, p_z};

// Apply rotation matrices (note, z-axis is the vertical one)
// First vertically
Vector p1 = rot_y * p0;
Vector p2 = rot_z * p1;

// Transform back into spherical coordinates
double theta = atan2(p2, p2);
double phi = asin(p2);

// Retrieve longitude,latitude
double longitude = theta / PI * 180.0;
double latitude = phi / PI * 180.0;

// Now we can use longitude,latitude coordinates in many different projections, such as:
// Polar projection
{
int polar_x_px = (0.5*PI + phi)*0.5 * cos(theta) /PI*180.0 * polar_w;
int polar_y_px = (0.5*PI + phi)*0.5 * sin(theta) /PI*180.0 * polar_h;
polar.setPixel(polar_x_px, polar_y_px, p.getRGB());
}
// Geographical (=equirectangular) projection
{
int geo_x_px = (longitude + 180) * geo_w;
int geo_y_px = (latitude + 90) * geo_h;
geo.setPixel(geo_x_px, geo_y_px, p.getRGB());
}
// ...
}
}
``````

Note, this is just some kind of pseudo-code. It is advised to use a matrix-library that handles your multiplications and rotations of matrices and vectors.

• what is polar_w, polar_h and geo_w, geo_h?? – PvDev Aug 15 '18 at 10:11
• @PvDev Those are just the width and height of the final projection, turning degrees into pixels. For instance, take this equqirectangular projection of the Earth map. If we have a longitude and latitude in degrees, and we want to draw that dot on that image, `geo_w_px` is 2058, and `geo_h_px` is 1036. However, first we need to normalize the degrees, so we do `(longitude+180)/360.0*geo_w_px`. But in the pseudo-code I precomputed `geo_w` as `geo_w_px/360` (same idea for `geo_h`, `polar_w`, `polar_h` etc). – Yeti Aug 16 '18 at 11:42
• thank you for reply. Actually i'm converting your code into node js. For sphere to equirectangular. – PvDev Aug 16 '18 at 12:56
• My image will look like single fisheye image. Is it possible to convert into equirectangular??\ – PvDev Aug 16 '18 at 13:20
• @PvDev Yes, but for that you won't really need to use rotation, you could just map it one on one. You only need a function that turns `(x,y)` from your fisheye image into `(latitude, longitude)`, and then a function that turns this latitude, longitude into a pixel on your equirectangular output image (which is how `geo_w_px` was calculated). But, please, ask a new question, because your situation seems really different from this one. – Yeti Aug 17 '18 at 15:35

hmm, i think maybe you should go one step back. Consider your camera angle (70mm ? or so). but your background image is a 360 degree in horizontal (but also vertical). Consider the perspective distortions on both type of pictures. For the background pict, in a vertical sense only the horizon is not vertically distorted. Sadly its only a thin line. As the distortion increases the more you get to the top or bottom.

Its not constant as in barrel distortion, but it depends on vertical distance of horizon.

I think the best way to realize the difference is to take a side view of both type of camera's and the target they supposed to project upon, from there its trigonometry, math.

Note that for the 70mm picture you need to know the angle it was shot. (or estimate it)

• I've already thought of manually stretching the picture depending on vertical offset in the picture and the angle at which it was taken with respect to the horizon. This was also my first intuition. But unfortunately, this did not bring me any closer to a solution. Think that I really need the right math to do this correctly. I am thinking now of this: I need to reverse the steps from a flat projection to a screenshot of any 360 degrees viewer. But then again, I'm not sure how to reverse this process, I'm bad in geometry math. (btw, camera angle is ~70x40 degrees) – Yeti May 5 '17 at 15:45
• its not simple stretching you need here, the stretching factor should per pixel (not as whole image) be applied with a factor depending distance from horizon. which would be different for each vertical pixel. – user3800527 May 8 '17 at 6:33