You can use the function NCHOOSEK to compute the binomial coefficient. With that, you can create a function that computes the value of the probability mass function for a set of `k`

values for a given `N`

and `p`

:

```
function pmf = binom_dist(N,p,k)
nValues = numel(k);
pmf = zeros(1,nValues);
for i = 1:nValues
pmf(i) = nchoosek(N,k(i))*p^k(i)*(1-p)^(N-k(i));
end
end
```

To plot the probability mass function, you would do the following:

```
k = 0:40;
pmf = binom_dist(40,0.5,k);
plot(k,pmf,'r.');
```

and the cumulative distribution function can be found from the probability mass function using CUMSUM:

```
cummDist = cumsum(pmf);
plot(k,cummDist,'r.');
```

**NOTE:** When the binomial coefficient returned from NCHOOSEK is large you can end up losing precision. A very nice alternative is to use the submission Variable Precision Integer Arithmetic from John D'Errico on the MathWorks File Exchange. By converting your numbers to his `vpi`

type, you can avoid the precision loss.