Since you didn't specify the exact model of your rollers, I'll represent them in polar coordinations, *i.e.* with a center point and a radius. The ink on each roller will be represented by an additional value, for example:

```
% # Initial state
C = [0, 0; -0.8, -0.6; 1, 0]; % # Roller centers (x, y)
R = [0.5, 0.5, 0.5]; % # Roller radii (r)
ink = [1, 0, 0]; % # Amount of ink on each roller
N = numel(R); % # Amount of rollers
```

Here there's ink only on roller #1 (I chose these values arbitrarily, so they can be changed, of course). For your convenience, you can draw the rollers like so:

```
% # Draw the rollers
figure, hold on
ang = 0:0.1:(2 * pi);
for i = 1:N
plot(C(i, 2) + R(i) * cos(ang), C(i, 1) + R(i) * sin(ang))
text(C(i, 2), C(i, 1), num2str(i))
end
title('Ink rollers'), axis image
```

That should produce the following image:

I'll leave it up to you to draw the ink on each roller :P

**And now to business:**

1) First we find all connected rollers:

```
% # Find connected rollers
isconn = @(m, n)(sum(([1, -1] * C([m, n], :)) .^ 2) - sum(R([m, n])) .^ 2 < eps);
[Y, X] = meshgrid(1:N, 1:N);
conn = reshape(arrayfun(isconn, X(:), Y(:)), N, N) - eye(N);
```

This produces a matrix in which each element in the position (*i*, *j*) is 1 if roller *i* and roller *j* are connected, and 0 if not. In this example, we get:

```
conn =
0 1 1
1 0 0
1 0 0
```

2) The next step is to simulate the ink flow by running a predetermined amount of iterations. In each iteration we simulate one revolution of each roller, *i.e.* we go over each roller and split the ink equally between itself and its neighbors.

```
% # Simulate ink flow for a number of revolutions
disp([sprintf('Initial state:\t\t'), '[', num2str(ink), ']'])
revolutions = 3;
for ii = 1:revolutions
new_ink = zeros(size(ink));
% # Iterate over each roller
for jj = 1:N
if (ink(jj) > 0)
delta_ink = ink(jj) / (sum(conn(jj, :)) + 1);
idx = [jj, find(conn(jj, :))]; % # roller jj and its neighbors
new_ink(idx) = new_ink(idx) + delta_ink;
end
end
ink = new_ink;
disp([sprintf('Revolution #%d:\t\t', ii), '[', num2str(ink), ']'])
end
```

I apologize that I haven't put much effort into optimizing these loops by vectorization. Anyway, these are the amounts of ink on each roller in each revolution:

```
Initial state: [1 0 0]
```

Revolution #1: [0.33333 0.33333 0.33333]

Revolution #2: [0.44444 0.27778 0.27778]

Revolution #3: [0.42593 0.28704 0.28704]

Obviously, you can easily put this code into a function that returns the last state of the rollers, or any other output of your choice. Moreover, you can also revise the algorithm to handle different splitting ratios depending on the radii of the rollers. Good luck!