# Radius of projected sphere in screen space

I'm trying to find the visible size of a sphere in pixels, after projection to screen space. The sphere is centered at the origin with the camera looking right at it. Thus the projected sphere should be a perfect circle in two dimensions. I am aware of this 1 existing question. However, the formula given there doesn't seem to produce the result I want. It is too small by a few percent. I assume this is because it is not correctly taking perspective into account. After projecting to screen space you do not see half the sphere but significantly less, due to perspective foreshortening (you see just a cap of the sphere instead of the full hemisphere 2).

How can I derive an exact 2D bounding circle?

Indeed, with a perspective projection you need to compute the height of the sphere "horizon" from the eye / center of the camera (this "horizon" is determined by rays from the eye tangent to the sphere).

Notations:

`d`: distance between the eye and the center of the sphere
`r`: radius of the sphere
`l`: distance between the eye and a point on the sphere "horizon", `l = sqrt(d^2 - r^2)`
`h`: height / radius of the sphere "horizon"
`theta`: (half-)angle of the "horizon" cone from the eye
`phi`: complementary angle of theta

``````h / l = cos(phi)
``````

but:

``````r / d = cos(phi)
``````

so, in the end:

``````h = l * r / d = sqrt(d^2 - r^2) * r / d
``````

Then once you have `h`, simply apply the standard formula (the one from the question you linked) to get the projected radius `pr` in the normalized viewport:

``````pr = cot(fovy / 2) * h / z
``````

with `z` the distance from the eye to the plane of the sphere "horizon":

``````z = l * cos(theta) = sqrt(d^2 - r^2) * h / r
``````

so:

``````pr = cot(fovy / 2) * r / sqrt(d^2 - r^2)
``````

And finally, multiply `pr` by `height / 2` to get the actual screen radius in pixels.

What follows is a small demo done with three.js. The sphere distance, radius and the vertical field of view of the camera can be changed by using respectively the `n` / `f`, `m` / `p` and `s` / `w` pairs of keys. A yellow line segment rendered in screen-space shows the result of the computation of the radius of the sphere in screen-space. This computation is done in the function `computeProjectedRadius()`.

`projected-sphere.js`:

``````"use strict";

var fov;

fov = fovy / 2 * Math.PI / 180.0;

//return 1.0 / Math.tan(fov) * r / d; // Wrong
return 1.0 / Math.tan(fov) * r / Math.sqrt(d * d - r * r); // Right
}

function Demo() {
this.width = 0;
this.height = 0;

this.scene = null;
this.mesh = null;
this.camera = null;

this.screenLine = null;
this.screenScene = null;
this.screenCamera = null;

this.renderer = null;

this.fovy = 60.0;
this.d = 10.0;
this.r = 1.0;
}

Demo.prototype.init = function() {
var aspect;
var light;
var container;

this.width = window.innerWidth;
this.height = window.innerHeight;

// World scene
aspect = this.width / this.height;
this.camera = new THREE.PerspectiveCamera(this.fovy, aspect, 0.1, 100.0);

this.scene = new THREE.Scene();

light = new THREE.DirectionalLight(0xFFFFFF);
light.position.set(1.0, 1.0, 1.0).normalize();

// Screen scene
this.screenCamera = new THREE.OrthographicCamera(-aspect, aspect,
-1.0, 1.0,
0.1, 100.0);
this.screenScene = new THREE.Scene();

this.renderer = new THREE.WebGLRenderer({
antialias: true
});
this.renderer.setSize(this.width, this.height);
this.renderer.domElement.style.position = "relative";
this.renderer.autoClear = false;

container = document.createElement('div');
container.appendChild(this.renderer.domElement);
document.body.appendChild(container);
}

Demo.prototype.render = function() {
this.renderer.clear();
this.renderer.setViewport(0, 0, this.width, this.height);
this.renderer.render(this.scene, this.camera);
this.renderer.render(this.screenScene, this.screenCamera);
}

var geometry;

this.camera.fov = this.fovy;
this.camera.updateProjectionMatrix();

if (this.mesh) {
this.scene.remove(this.mesh);
}

this.mesh = new THREE.Mesh(
new THREE.SphereGeometry(this.r, 16, 16),
new THREE.MeshLambertMaterial({
color: 0xFF0000
})
);
this.mesh.position.z = -this.d;

if (this.screenLine) {
this.screenScene.remove(this.screenLine);
}

geometry = new THREE.Geometry();
geometry.vertices.push(new THREE.Vector3(0.0, 0.0, -1.0));
geometry.vertices.push(new THREE.Vector3(0.0, -this.pr, -1.0));

this.screenLine = new THREE.Line(
geometry,
new THREE.LineBasicMaterial({
color: 0xFFFF00
})
);

this.screenScene = new THREE.Scene();
}

Demo.prototype.onKeyDown = function(event) {
console.log(event.keyCode)
switch (event.keyCode) {
case 78: // 'n'
this.d /= 1.1;
break;
case 70: // 'f'
this.d *= 1.1;
break;
case 77: // 'm'
this.r /= 1.1;
break;
case 80: // 'p'
this.r *= 1.1;
break;
case 83: // 's'
this.fovy /= 1.1;
break;
case 87: // 'w'
this.fovy *= 1.1;
break;
}
}

Demo.prototype.onResize = function(event) {
var aspect;

this.width = window.innerWidth;
this.height = window.innerHeight;

this.renderer.setSize(this.width, this.height);

aspect = this.width / this.height;
this.camera.aspect = aspect;
this.camera.updateProjectionMatrix();

this.screenCamera.left = -aspect;
this.screenCamera.right = aspect;
this.screenCamera.updateProjectionMatrix();
}

var demo;

demo = new Demo();
demo.init();

function animationLoop() {
demo.render();
window.requestAnimationFrame(animationLoop);
}

function onResizeHandler(event) {
demo.onResize(event);
}

function onKeyDownHandler(event) {
demo.onKeyDown(event);
}

window.requestAnimationFrame(animationLoop);
}
``````

`index.html`:

``````<!DOCTYPE html>
<html>
<title>Projected sphere</title>
<style>
body {
background-color: #000000;
}
</style>
<script src="http://cdnjs.cloudflare.com/ajax/libs/three.js/r61/three.min.js"></script>
<script src="projected-sphere.js"></script>
<div id="container"></div>
</body>
</html>
``````
• Wow, thank you very much for a very detailed answer! – BuschnicK Feb 12 '14 at 8:23
• if you use a tool like GeoGebra for creating the 2D drawing then could you tell me the name of it, please? – knivil Feb 12 '14 at 19:10
• @knivil I simply used Inkscape. – user3146587 Feb 12 '14 at 22:53

Let the sphere have radius `r` and be seen at a distance `d` from the observer. The projection plane is at distance `f` from the observer.

The sphere is seen under the half angle `asin(r/d)`, so the apparent radius is `f.tan(asin(r/d))`, which can be written as `f . r / sqrt(d^2 - r^2)`. [The wrong formula being `f . r / d`.]

The illustrated accepted answer above is excellent, but I needed a solution without knowing the field of view, just a matrix to transform between world and screen space, so I had to adapt the solution.

1. Reusing some variable names from the other answer, calculate the start point of the spherical cap (the point where line `h` meets line `d`):

``````capOffset = cos(asin(l / d)) * r
capCenter = sphereCenter + ( sphereNormal * capOffset )
``````

where `capCenter` and `sphereCenter` are points in world space, and `sphereNormal` is a normalized vector pointing along `d`, from the sphere center towards the camera.

2. Transform the point to screen space:

``````capCenter2 = matrix.transform(capCenter)
``````
3. Add `1` (or any amount) to the `x` pixel coordinate:

``````capCenter2.x += 1
``````
4. Transform it back to world space:

``````capCenter2 = matrix.inverse().transform(capCenter2)
``````
5. Measure the distance between the original and new points in world space, and divide into the amount you added to get a scale factor:

``````scaleFactor = 1 / capCenter.distance(capCenter2)
``````
6. Multiply that scale factor by the cap radius `h` to get the visible screen radius in pixels:

``````screenRadius = h * scaleFactor
``````

Old question, but a dirt simple hack:

Render a frame with two identical spheres: one at the middle of the screen, and one at a corner. Make sure the center of both spheres are equidistant from the camera.