The trick is to apply the transformation on your `vertices`

, but keep the same `faces`

data. This way the faces always link the same points, regardless of their new positions.

Since there are no sample data I took the Matlab example as a starting point. This is coming from the Matlab `isosurface`

page (very slightly modified for this example):

```
%// Generate an isosurface
[x,y,z,v] = flow;
fv = isosurface(x,y,z,v,-3) ;
figure(1);cla
p1 = patch(fv,'FaceColor','red','EdgeColor','none');
%// refine the view
grid off ; set(gca,'Color','none') ; daspect([1,1,1]) ; view(3) ; axis tight ; camlight ; lighting gouraud
```

This output:

Nothing original so far. Just note that I used the single structure output type `fv`

instead of the 2 separate arrays `[f,v]`

. It is not critical, just a choice to ease the next call to the patch object.

I need to retrieve the vertices coordinates:

```
%// Retrieve the vertices coordinates
X = fv.vertices(:,1) ;
Y = fv.vertices(:,2) ;
Z = fv.vertices(:,3) ;
```

You can then apply your transformation. I choose a simple one in this example, but any transformation function is valid.

```
%// Transform
X = -X.*Y.^2 ;
Y = Y.*X ;
Z = Z*2 ;
```

Then I rebuild a new structure for the patch which will display the transformed object.

*This is the important bit:*

```
%// create new patch structure
fvt.vertices = [X Y Z] ; %// with the new transformed 'vertices'
fvt.faces = fv.faces ; %// but we keep the same 'faces'
```

Then I display it the same way (well with a slightly different angle for a better view):

```
%// Plot the transformed isosurface
figure(2);cla
pt = patch( fvt ,'FaceColor','red','EdgeColor','none');
%// refine the view
grid off ; set(gca,'Color','none') ; daspect([1,1,1]) ; view(-3,4) ; axis tight ; camlight ; lighting gouraud
```

Which produces the figure:

*(If you paste all the code snippet in one file it should run and give you the same output.)*

`T`

on all the initial volume coordinates`x,y,z`

(`[X,Y,Z]=T(x,y,z)`

, then pull the isosurface on these new coordinates (`[f, v] = isosurface(X, Y, Z, v, isovalue)`

). Regarding the value of the field`v`

it may or may not make sense to apply the transformation to it (if even possible), that depends only on your specific problem. – Hoki Sep 22 '14 at 10:33