# OpenGL - How to calculate normals in a terrain height grid?

My approach is to calculate two tangent vectors parallel to axis X and Y respectively. Then calculate the cross product to find the normal vector.

The tangent vector is given by the line that crosses the middle point on the two nearest segments as is shown in the following picture. I was wondering whether there is a more direct calculation, or less expensive in terms of CPU cycles.

• Can I ask what you used to draw this image? It's really nice. Dec 21, 2012 at 1:46

You can actually calculate it without a cross product, by using the "finite difference method" (or at least I think it is called in this way).

Actually it is fast enough that I use it to calculate the normals on the fly in a vertex shader.

``````  // # P.xy store the position for which we want to calculate the normals
// # height() here is a function that return the height at a point in the terrain

// read neightbor heights using an arbitrary small offset
vec3 off = vec3(1.0, 1.0, 0.0);
float hL = height(P.xy - off.xz);
float hR = height(P.xy + off.xz);
float hD = height(P.xy - off.zy);
float hU = height(P.xy + off.zy);

// deduce terrain normal
N.x = hL - hR;
N.y = hD - hU;
N.z = 2.0;
N = normalize(N);
``````
• Too bad I can't give you more than +1: I doubled my FPS by using your simple algorithm!
– Zac
Jul 5, 2013 at 13:56
• Is there somewhere a mathematical explaination for this? Feb 2, 2018 at 18:53
• A more expensive, but slightly more accurate version here stackoverflow.com/a/21660173/175592 Jul 9, 2019 at 14:44
• ok that makes sense, N.z has to be 2 times your offset, so in my case I use .03 as offset giving N.z = .06 Jul 10, 2019 at 9:09
• Consider your surface: z = h(x, y), where h is the height map. So, z - h(x,y) = 0 This is an equation is a contour at g=0 for the following function: g(x,y,z) = z - f(x,y) The gradient of g points in the direction of max increase. It is also orthogonal to the contour plane. So it is the normal. To find the discrete gradient, center at (x,y), and take the difference of its neighbors. grad_x = f(x+1,y) - f(x-1,y) / 2 grad_y = f(x,y+1) - f(x,y-1) / 2 grad_z = (z+1) - (z-1) / 2 = 2/2 = 1 The whole thing can be scaled without changing direction so multiply by 2. Then normalize. Tada! Jan 20, 2021 at 8:43