Assuming a cylinder aligned with the `z`

-axis, radii `R`

linearly spaced along the unit height above the `XY`

-plane (same assumptions as built-in `cylinder`

):

```
function [x,y,z] = solidCylinder(varargin)
%// Basic checks
assert(nargin >= 1, 'Not enough input arguments.');
assert(nargin <= 3, 'Too many input arguments.');
assert(nargout <= 3, 'Too many output arguments.');
%// Parse input
N = 20;
Ax = [];
switch nargin
case 1 %// R
R = varargin{1};
case 2 %// Ax, R or R, N
if ishandle(varargin{1})
Ax = varargin{1};
R = varargin{2};
else
R = varargin{1};
N = varargin{2};
end
case 3 %// Ax, R, N
Ax = varargin{1};
R = varargin{2};
N = varargin{3};
end
%// Check input arguments
if ~isempty(Ax)
assert(ishandle(Ax) && strcmp(get(Ax, 'type'), 'axes'),...
'Argument ''Ax'' must be a valid axis handle.');
else
Ax = gca;
end
assert(isnumeric(R) && isvector(R) && all(isfinite(R)) && all(imag(R)==0) && all(R>0),...
'Argument ''R'' must be a vector containing finite, positive, real values.');
assert(isnumeric(N) && isscalar(N) && isfinite(N) && imag(N)==0 && N>0 && round(N)==N,...
'Argument ''N'' must be a finite, postive, real, scalar integer.');
%// Compute cylinder coords (mostly borrowed from builtin 'cylinder')
theta = 2*pi*(0:N)/N;
sintheta = sin(theta);
sintheta(N+1) = 0;
M = length(R);
if M==1
R = [R;R]; M = 2; end
x = R(:) * cos(theta);
y = R(:) * sintheta;
z = (0:M-1).'/(M-1) * ones(1,N+1); %'
if nargout == 0
oldNextPlot = get(Ax, 'NextPlot');
set(Ax, 'NextPlot', 'add');
%// The side of the cylinder
surf(x,y,z, 'parent',Ax);
%// The bottom
patch(x(1,:) , y(1,:) , z(1,:) , z(1,:) );
%// The top
patch(x(end,:), y(end,:), z(end,:), z(end,:));
set(Ax, 'NextPlot', oldNextPlot);
end
end
```

To check whether points are inside a cylinder of height `L`

(note: assuming a true 'cylinder' as created with `[R R]`

, and NOT some compound object (cones with cylinders) as created by `[R1 R2 ... RN]`

with at least two different values):

```
function p = pointInCylinder(x,y,z)
%// These can also be passed by argument of course
R = 10;
L = 5;
%// Basic checks
assert(isequal(size(x),size(y),size(z)), ...
'Dimensions of the input arguments must be equal.');
%// Points inside the circular shell?
Rs = sqrt(x.^2 + y.^2 + z.^2) <= R;
%// Points inside the top and bottom?
Os = z>=0 & z<=L;
p = Rs & Os;
end
```

`patch`

to draw the top and bottom surfaces you want (defining two circles, draw them as polygons, then fill them)? – Floris Nov 11 '13 at 5:47