Note that the function TRISURF that you were originally trying to use returns a handle to a *patch* object. If you look at the `'FaceColor'`

property for patch objects, you can see that there is no `'texturemap'`

option. That option is only valid for the `'FaceColor'`

property of *surface* objects. You will therefore have to find a way to plot your triangular surface as a *surface* object instead of a *patch* object. Here are two ways to approach this:

## If your data is in a uniform grid...

If the coordinates of your surface data represent a uniform grid such that `z`

is a rectangular set of points that span from `xmin`

to `xmax`

in the x-axis and `ymin`

to `ymax`

in the y-axis, you can plot it using SURF instead of TRISURF:

```
Z = ... %# N-by-M matrix of data
x = linspace(xmin,xmax,size(Z,2)); %# x-coordinates for columns of Z
y = linspace(ymin,ymax,size(Z,1)); %# y-coordinates for rows of Z
[X,Y] = meshgrid(x,y); %# Create meshes for x and y
C = imread('image1.jpg'); %# Load RGB image
h = surf(X,Y,Z,flipdim(C,1),... %# Plot surface (flips rows of C, if needed)
'FaceColor','texturemap',...
'EdgeColor','none');
axis equal
```

In order to illustrate the results of the above code, I initialized the data as `Z = peaks;`

, used the built-in sample image `'peppers.png'`

, and set the `x`

and `y`

values to span from 1 to 16. This resulted in the following texture-mapped surface:

## If your data is non-uniformly spaced...

If your data are not regularly spaced, you can create a set of regularly-spaced `X`

and `Y`

coordinates (as I did above using MESHGRID) and then use one of the functions GRIDDATA or TriScatteredInterp to interpolate a regular grid of `Z`

values from your irregular set of `z`

values. I discuss how to use these two functions in my answer to another SO question. Here's a refined version of the code you posted using TriScatteredInterp:

```
x = ... %# Scattered x data
y = ... %# Scattered y data
z = ... %# Scattered z data
xmin = min(x);
xmax = max(x);
ymin = min(y);
ymax = max(y);
F = TriScatteredInterp(x(:),y(:),z(:)); %# Create interpolant
N = 50; %# Number of y values in uniform grid
M = 50; %# Number of x values in uniform grid
xu = linspace(xmin,xmax,M); %# Uniform x-coordinates
yu = linspace(ymin,ymax,N); %# Uniform y-coordinates
[X,Y] = meshgrid(xu,yu); %# Create meshes for xu and yu
Z = F(X,Y); %# Evaluate interpolant (N-by-M matrix)
C = imread('image1.jpg'); %# Load RGB image
h = surf(X,Y,Z,flipdim(C,1),... %# Plot surface
'FaceColor','texturemap',...
'EdgeColor','none');
axis equal
```

In this case, you have to *first* choose the values of `N`

and `M`

for the size of your matrix `Z`

. In order to illustrate the results of the above code, I initialized the data for `x`

, `y`

, and `z`

as follows and used the built-in sample image `'peppers.png'`

:

```
x = rand(1,100)-0.5; %# 100 random values in the range -0.5 to 0.5
y = rand(1,100)-0.5; %# 100 random values in the range -0.5 to 0.5
z = exp(-(x.^2+y.^2)./0.125); %# Values from a 2-D Gaussian distribution
```

This resulted in the following texture-mapped surface:

Notice that there are jagged edges near the corners of the surface. These are places where there were too few points for TriScatteredInterp to adequately fit an interpolated surface. The `Z`

values at these points are therefore NaN, resulting in the surface point not being plotted.