# Intro

Hey!

Some weeks ago, I did a small demo for a JS challenge. This demo was displaying a landscape based on a procedurally-generated **heightmap**. To display it as a 3D surface, I was evaluating the **interpolated height** of random points (*Monte-Carlo rendering*) then projecting them.

At that time, I was already aware of some glitches in my method, but I was waiting for the challenge to be over to seek some help. I'm counting on you. :)

# Problem

So the main error I get can be seen in the following screenshot:

Screenshot - Interpolation Error? http://code.aldream.net/img/interpolation-error.jpg

As you can see in the center, some points seem like floating above the peninsula, forming like a *less-dense relief*. It is especially obvious with the sea behind, because of the color difference, even though the problem seems global.

# Current method

## Surface interpolation

To evaluate the height of each point of the surface, I'm using triangulation + linear interpolation with barycentric coordinates, ie:

**I find in which square ABCD my point**, with*(x, y)*is*A = (X,Y), B = (X+1, Y), C = (X, Y+1) and D = (X+1, Y+1)*,*X*and*Y*being the truncated value of*x, y*. (each point is mapped to my heightmap)**I estimate in which triangle - ABD or ACD - my point is**, using the condition:*isInABD = dx > dy*with*dx, dy*the decimal part of*x, y*.**I evaluate the height of my point using linear interpolation**:- if in ABD, height = h(B) + [h(A) - h(B)] * (1-dx) + [h(D) - h(B)] * dy
- if in ACD, height = h(C) + [h(A) - h(C)] * (1-dy) + [h(D) - h(C)] * dx, with h(X) height from the map.

## Displaying

To display the point, I just convert *(x, y, height)* into the world coordinates, project the vertex (using simple **perspective projection** with yaw and pitch angles). I use a **zBuffer** I keep updated to check if I draw or not the obtained pixel.

# Attempts

My impression is that for some points, I get a wrong interpolated height. I thus tried to search for some errors or some non-covered boundaries cases, in my implementation of the triangulation + linear interpolation. But if there are, I can't spot them.

I use the projection in other demos, so I don't think the problem comes from here. As for the *zBuffering*, I can't see how it could be related...

I'm running out of luck here... Any hints are most welcome!

Thank for your attention, and have a nice day!

# Annexe

## JsFiddle - Demo

Here is a jsFiddle http://jsfiddle.net/PWqDL/ of the whole slightly simplified demo, for those who want to tweak around...

## JsFiddle - Small test for the interpolation

As I was writing down this question, I got an idea to have a better look at the results of my interpolation. I implemented a simple test in which I use a 2x2 matrix containing some hue values, and I interpolate the intermediate colors before displaying them in the canvas.

Here is the jsFiddle: http://jsfiddle.net/y2K7n/

*Alas*, the results seem to match the expected behavior for the kind of "triangular" interpolation I'm doing, so I'm definitly running out of ideas.

## Code sample

And here is the simplified most-probably-faulty part of my JS code describing my rendering method (but the language doesn't matter much here I think), given a square heightmap "*displayHeightMap*" of size *(dim x dim)* for a landscape of size *(SIZE x SIZE)*:

```
for (k = 0; k < nbMonteCarloPointsByFrame; k++) {
// Random float indices:
var i = Math.random() * (dim-1),
j = Math.random() * (dim-1),
// Integer part (troncated):
iTronc = i|0,
jTronc = j|0,
indTronc = iTronc*dim + jTronc,
// Decimal part:
iDec = i%1,
jDec = j%1,
// Now we want to intrapolate the value of the float point from the surrounding points of our map. So we want to find in which triangle is our point to evaluate the weighted average of the 3 corresponding points.
// We already know that our point is in the square defined by the map points (iTronc, jTronc), (iTronc+1, jTronc), (iTronc, jTronc+1), (iTronc+1, jTronc+1).
// If we split this square into two rectangle using the diagonale [(iTronc, jTronc), (iTronc+1, jTronc+1)], we can deduce in which triangle is our point with the following condition:
whichTriangle = iDec < jDec, // ie "are we above or under the line j = jTronc + distanceBetweenLandscapePoints - (i-iTronc)"
indThirdPointOfTriangle = indTronc +dim*whichTriangle +1-whichTriangle, // Top-right point of the square or bottm left, depending on which triangle we are in.
// Intrapolating the point's height:
deltaHeight1 = (displayHeightMap[indTronc] - displayHeightMap[indThirdPointOfTriangle]),
deltaHeight2 = (displayHeightMap[indTronc+dim+1] - displayHeightMap[indThirdPointOfTriangle]),
height = displayHeightMap[indThirdPointOfTriangle] + deltaHeight1 * (1-(whichTriangle? jDec:iDec)) + deltaHeight2 * (!whichTriangle? jDec:iDec),
posX = i*distanceBetweenLandscapePoints - SIZE/2,
posY = j*distanceBetweenLandscapePoints - SIZE/2,
posZ = height - WATER_LVL;
// 3D Projection:
var temp1 = cosYaw*(posY - camPosY) - sinYaw*(posX - camPosX),
temp2 = posZ - camPosZ,
dX = (sinYaw*(posY - camPosY) + cosYaw*(posX - camPosX)),
dY = sinPitch*temp2 + cosPitch*temp1,
dZ = cosPitch*temp2 - sinPitch*temp1,
pixelY = dY / dZ * minDim + canvasHeight,
pixelX = dX / dZ * minDim + canvasWidth,
canvasInd = pixelY * canvasWidth*2 + pixelX;
if (!zBuffer[canvasInd] || (dZ < zBuffer[canvasInd])) { // We check if what we want to draw will be visible or behind another element. If it will be visible (for now), we draw it and update the zBuffer:
zBuffer[canvasInd] = dZ;
// Color:
a.fillStyle = a.strokeStyle = EvaluateColor(displayHeightMap, indTronc); // Personal tweaking.
a.fillRect(pixelX, pixelY, 1, 1);
}
}
```