First, it looks like you're off on the wrong step using `random`

. Second, you're correct in that the documentation for Matlab's `ProbDist`

classes is not particularly good and lacks examples.

Let's use the these parameters that match those that you used (however I'm not sure if you bounds, `a`

and `b`

, are meant to be to be probabilities, `P(X)`

, -do you want do integrate over a range of probabilities? -in that case you actually want to use the inverse CDF):

```
mu = 1; sig = 1;
a = 0.3; b = 0.6;
```

You have several options depending on what you need. It'll likely be easiest to use the `integral`

function to perform numerical integration (quadrature). First you can implement the CDF yourself:

```
normalCDF = @(t,mu,sig)(1+erf((t-mu)./(sqrt(2)*sig)))/2;
q = integral(@(t)normalCDF(t,mu,sig),a,b)
```

Or use one of the older style cdf function, `normcdf`

in this case:

```
q = integral(@(t)normcdf(t,mu,sig),a,b)
```

Or use the general `cdf`

function (type `help cdf`

to see a list of all of the supported distributions for the older style CDFs):

```
q = integral(@(t)cdf('norm',t,mu,sig),a,b)
```

Or use one of the new `ProbDistUnivParam`

class methods:

```
normalPD = ProbDistUnivParam('normal',[mu sig]);
q = integral(@(t)normalPD.cdf(t),a,b)
```

See here for a list of distributions supported with this new class. Note that the `.cdf(t)`

is not to be confused with the `cdf`

function used just above. This one is a method of the `ProbDistUnivParam`

class. Type `help ProbDistUnivParam`

and `help ProbDistUnivParam/cdf`

.

If you want to attempt to solve for symbolic solutions, then you'll likely need to implement CDF functions yourself. Most high level Matlab functions support floating point calculations only unless they are part of the Symbolic Toolbox. Here's how you might go about solving for for these symbolically using `int`

:

```
syms t MU SIG A B real
normalCDFsym = (1+erf((t-MU)./(sqrt(2)*SIG)))/2;
qsym = simplify(int(normalCDFsym,t,A,B)); % Solve integral symbolically
pretty(qsym) % Print out result
q = subs(qsym,{MU,SIG,A,B},{mu,sig,a,b}) % Plug in numeric values
```

Note that for more complicated distributions, you may not always be able to get a solution. Also, here I've left `MU`

, `SIG`

, `A`

, and `B`

all as symbolic. In some cases you may not be able to get a solution with all symbolic parameter so you can try letting some of them be explicit values if you know what those values are, e.g.:

```
syms t MU A real
normalCDFsym = (1+erf((t-MU)./(sqrt(2)*sym(1))))/2;
qsym = simplify(int(normalCDFsym,t,A,sym(0.6))); % Solve integral symbolically
pretty(qsym) % Print out result
q = subs(qsym,{MU,A},{mu,a}) % Plug in numeric values
```