# Measure height of 3d block for [x y] point

I have following data:

``````kx = 20;
ky = 20;
k  = [kx ky];

PointsL = [
[ 32   0   0] % P1
[387   0   0]
[475   0   0]
[475  30   0]
[602  30   0] % P5
[602 220   0]
[475 220   0]
[475 737   0]
[387 737   0]
[ 32 737   0] % P10
[ 32 555   0]
[  0 555   0]
[  0 277   0]
[ 27 277   0]
[ 27 250   0] % P15
[  0 250   0]
[  0  57   0]
[ 32  57   0] % P18
];
PointsH = [
[ 32   0 270] % P1
[387   0 270]
[475   0 183]
[475  30 183]
[602  30 183] % P5
[602 220 183]
[475 220 183]
[475 737 183]
[387 737 270]
[ 32 737 270] % P10
[ 32 555 270]
[  0 555 270]
[  0 277 270]
[ 27 277 270]
[ 27 250 270] % P15
[  0 250 270]
[  0  57 270]
[ 32  57 270] % P18
];
``````

`PointsL` are points of the lower surface - all with `z=0`.

`PointsH` are points of the higher surface - changable in z-axis.

All of them are representing points of room.

Following code draws 3d model:

``````plength = size(PointsL,1);
for i=1:plength
if i == 1
pl1 = PointsL(plength,:);
ph1 = PointsH(plength,:);
else
pl1 = PointsL(i-1,:);
ph1 = PointsH(i-1,:);
end
pl2 = PointsL(i,:);
ph2 = PointsH(i,:);

line([pl1(1) pl2(1)], [pl1(2) pl2(2)], [pl1(3) pl2(3)]);
line([ph1(1) ph2(1)], [ph1(2) ph2(2)], [ph1(3) ph2(3)]);
line([pl1(1) ph1(1)], [pl1(2) ph1(2)], [pl1(3) ph1(3)]);
end

p1 = PointsH(2,:);
p2 = PointsH(9,:);
line([p1(1) p2(1)], [p1(2) p2(2)], [p1(3) p2(3)]);

p1 = PointsH(4,:);
p2 = PointsH(7,:);
line([p1(1) p2(1)], [p1(2) p2(2)], [p1(3) p2(3)]);
``````

Is it possible to get height (`z` value) for given `x,y` values ?

-

Ok, I was going to say that this could easily be done using `TriScatteredInterp()` on `PointsH`. I realised that it was not that simple to get it to produce what I wanted. I resorted to adding extra points and moving them around to create the right interpolation triangles.

I finally got something that can produce the z-value corresponding to the point (a,b).

Here is what I ended up doing...

``````epsilon = 1e-8;

PointsL_diff = epsilon*[
[ -1   0   0] % P1
[  0  -1   0]
[  0  -1   0]
[  1   0   0]
[  0  -1   0] % added
[  1  -1   0]
[  1   0   0] % P5
[  0  -1   0]
[  1   1   0]
[  1   1   0]
[  0   1   0]
[  1   0   0] % added
[  0   1   0]
[ -1   0   0] % P10
[  0   1   0] % added
[ -1   1   0]
[ -1   1   0]
[ -1   0   0]
[  0  -1   0] % added
[ -1  -1   0]
[ -1   1   0] % P15
[ -1   0   0]
[  0   1   0] % added
[ -1  -1   0]
[ -1  -1   0] % P18
];

PointsL = [
[ 32   0   0] % P1
[ 32   0   0] % added
[387   0   0]
[475   0   0]
[475  30   0]
[602  30   0] % P5
[602 220   0]
[475 220   0]
[475 737   0]
[387 737   0]
[ 32 737   0] % P10
[ 32 737   0] % added
[ 32 555   0]
[  0 555   0]
[  0 277   0]
[  0 277   0] % added
[ 27 277   0]
[ 27 250   0] % P15
[  0 250   0]
[  0 250   0] % added
[  0  57   0]
[ 32  57   0] % P18
];

PointsH = [
[ 32   0 270] % P1
[387   0 270]
[475   0 183]
[475  30 183]
[602  30 183] % P5
[602 220 183]
[475 220 183]
[475 737 183]
[387 737 270]
[ 32 737 270] % P10
[ 32 555 270]
[  0 555 270]
[  0 277 270]
[ 27 277 270]
[ 27 250 270] % P15
[  0 250 270]
[  0  57 270]
[ 32  57 270] % P18
];

% plot bounds
x_min = -200;
x_max = 800;
y_min = -200;
y_max = 800;

newPointsL = PointsL + PointsL_diff;

x = [PointsH(:,1); newPointsL(:,1); x_min; x_max; x_min; x_max];
y = [PointsH(:,2); newPointsL(:,2); y_min; y_min; y_max; y_max];
z = [PointsH(:,3); newPointsL(:,3);     0;     0;     0;     0];

F = TriScatteredInterp(x,y,z); % default is linear interpolation

% find z-value for point (a,b)
a = 100;
b = 200;
z_value = F(a,b)

% generate mesh and plot surface
ti_x = x_min:10:x_max;
ti_y = y_min:10:y_max;
[qx,qy] = meshgrid(ti_x,ti_y);
qz = F(qx,qy);
mesh(qx,qy,qz);
hold on;
plot3(x,y,z,'o');
``````

... and here is the figure the code produces:

-
That's what I need. Thank you very much ! –  hsz Dec 8 '12 at 14:25
@hsz Glad I could help - even if it wasn't the most beautiful solution... –  user1884905 Dec 8 '12 at 19:31

Quick general way:

Try `Data Cursor` option in the figure windows Tool bar.

If you have to do it mathematically,then you have to create a `3×n Martix` of this plot artificially, and it'll be easy to find `z` for any given `x,y`. –  Sameh Kamal Dec 7 '12 at 20:17