As Cheery wrote, a Gaussian distribution covers the whole real set, so there is no way to have numbers both normally distributed and limited in support.

A solution might be to truncate the values: regenerate the values when `randn`

returns a value outside of the desired range.

This can be implemented quite easily (and naively) by the following code:

```
function x = randnlimit(mu, sigma, minVal, maxVal, varargin);
assert(mu>=minVal && mu<=maxVal);
assert(sigma>0);
x = mu + sigma*randn(varargin{:});
outsideRange = x<minVal | x>maxVal;
while nnz(outsideRange)>0
x(outsideRange) = mu + sigma*randn(nnz(outsideRange),1);
outsideRange = x<minVal | x>maxVal;
end
```

**edit** to summarize the discussion @Cheery and I had:
You can choose: either you get a Gaussian, but then you are stuck with values that cover the whole real axis (so also negative values). On the other hand, if you need a limited range, you need to use a different distribution to generate samples from.

Which approach you need depends on your application. Whether the need for a limited support is primordial or the shape of the pdf is the most important.

The code I provided above will be limited to the range `[minVal, maxVal]`

and approximately gaussian when you choose `sigma`

and `mu`

appropriately, i.e. `mu = maxVal/2 + minVal/2`

and `n * sigma = maxVal - minVal`

. For a value of `n`

larger than two, the distribution will be quite close to a real Gaussian. E.g. for `n=2`

, I expect only 5% difference (for `n=3`

, less than 1%). You can of course specify `minVal = 0`

and `maxVal = +Inf`

to select the positive values only.