Use inverse functions to get different distributions. The function below shows how I implemented multiple inverse functions into one

- Dist = the distribution type
- a,b,c = parameters of the distribution like minimum, mode, maximum
- Prob = rand()

If you pass multiple random values (between 0 and 1) the result from the function will end up with the shape of the distribution you've selected.

```
Function DistInv(Dist, a, b, c, Prob) As Single
If Dist = "Single" Then
' this is a single value to be used
DistInv = a
ElseIf Dist = "Binomial" Then
' binomial is like a coin flip. Only has a value of 1 or 0. 'a' determines the cut off point
If Abs(Prob) > a Then
DistInv = 0
Else
DistInv = 1
End If
ElseIf Dist = "Random" Then
' uniform distribution between 0% and 100%
DistInv = Prob
ElseIf Dist = "Rand Between" Then
' uniform distribution between the given parameters
DistInv = Prob * (b - a) + a
ElseIf Dist = "Triangular" Then
' Triangular distribution with a = lowest value, b = most likely value and c = highest value
a1 = 1 / ((b - a) * (c - a))
b1 = -2 * a / ((b - a) * (c - a))
C1 = a ^ 2 / ((b - a) * (c - a))
a2 = -1 / ((c - b) * (c - a))
b2 = 2 * c / ((c - b) * (c - a))
C2 = ((c - b) * (c - a) - c ^ 2) / ((c - b) * (c - a))
DistInv = ((-4 * a1 * C1 + 4 * a1 * Prob + b1 ^ 2) ^ (1 / 2) - b1) / (2 * a1)
If DistInv > b Then
DistInv = ((-4 * a2 * C2 + 4 * a2 * Prob + b2 ^ 2) ^ (1 / 2) - b2) / (2 * a2)
End If
ElseIf Dist = "Norm Between" Then
' normal distribution between the given parameters
DistInv = WorksheetFunction.NormInv(Prob, (a + b) / 2, (b - a) / 3.29)
ElseIf Dist = "Norm Mean Dev" Then
' Normal distribution with the average.norm and standard deviation
DistInv = WorksheetFunction.NormInv(Prob, a, b)
ElseIf Dist = "Weibull" Then
' Weibull distribution of probability
'
' inverse of Cumulative Weibull Function
' for a cumulative Weibull distribution F = 1- exp(-((x-c)/b)^a)
' where a is the shape parameter
' b is the scale parameter and
' c is the offset
'
' then solving for x
'
' x = c + b * (-log(1-Prob))^a
DistInv = c + b * (-Log(1 - Prob)) ^ (1 / a)
End If
End Function
```