This is a complicated question, and there are no perfect answers. I'll try to give you an overview of the major concepts, and point you in the direction of some useful reading on the topic.

Assume that you a one dimensional set of data, and you have a finite set of probability distribution functions that you think the data may have been generated from. You can consider each distribution independently, and try to find parameters that are reasonable given your data.
There are two methods for setting parameters for a probability distribution function given data:

- Least Squares
- Maximum Likelihood

In my experience, Maximum Likelihood has been preferred in recent years, although this may not be the case in every field.

Here's a concrete example of how to estimate parameters in R. Consider a set of random points generated from a Gaussian distribution with mean of 0 and standard deviation of 1:

```
x = rnorm( n = 100, mean = 0, sd = 1 )
```

Assume that you know the data were generated using a Gaussian process, but you've forgotten (or never knew!) the parameters for the Gaussian. You'd like to use the data to give you reasonable estimates of the mean and standard deviation. In R, there is a standard library that makes this very straightforward:

```
library(MASS)
params = fitdistr( x, "normal" )
print( params )
```

This gave me the following output:

```
mean sd
-0.17922360 1.01636446
( 0.10163645) ( 0.07186782)
```

Those are fairly close to the right answer, and the numbers in parentheses are confidence intervals around the parameters. Remember that every time you generate a new set of points, you'll get a new answer for the estimates.

Mathematically, this is using maximum likelihood to estimate both the mean and standard deviation of the Gaussian. Likelihood means (in this case) "probability of data given values of the parameters." Maximum likelihood means "the values of the parameters that maximize the probability of generating my input data." Maximum likelihood estimation is the algorithm for finding the values of the parameters which maximize the probability of generating the input data, and for some distributions it can involve numerical optimization algorithms. In R, most of the work is done by fitdistr, which in certain cases will call optim.

You can extract the log-likelihood from your parameters like this:

```
print( params$loglik )
[1] -139.5772
```

It's more common to work with the log-likelihood rather than likelihood to avoid rounding errors. Estimating the joint probability of your data involves multiplying probabilities, which are all less than 1. Even for a small set of data, the joint probability approaches 0 very quickly, and adding the log-probabilities of your data is equivalent to multiplying the probabilities. The likelihood is maximized as the log-likelihood approaches 0, and thus more negative numbers are worse fits to your data.

With computational tools like this, it's easy to estimate parameters for any distribution. Consider this example:

```
x = x[ x >= 0 ]
distributions = c("normal","exponential")
for ( dist in distributions ) {
print( paste( "fitting parameters for ", dist ) )
params = fitdistr( x, dist )
print( params )
print( summary( params ) )
print( params$loglik )
}
```

The exponential distribution doesn't generate negative numbers, so I removed them in the first line. The output (which is stochastic) looked like this:

```
[1] "fitting parameters for normal"
mean sd
0.72021836 0.54079027
(0.07647929) (0.05407903)
Length Class Mode
estimate 2 -none- numeric
sd 2 -none- numeric
n 1 -none- numeric
loglik 1 -none- numeric
[1] -40.21074
[1] "fitting parameters for exponential"
rate
1.388468
(0.196359)
Length Class Mode
estimate 1 -none- numeric
sd 1 -none- numeric
n 1 -none- numeric
loglik 1 -none- numeric
[1] -33.58996
```

The exponential distribution is actually slightly more likely to have generated this data than the normal distribution, likely because the exponential distribution doesn't have to assign any probability density to negative numbers.

All of these estimation problems get worse when you try to fit your data to more distributions. Distributions with more parameters are more flexible, so they'll fit your data better than distributions with less parameters. Also, some distributions are special cases of other distributions (for example, the Exponential is a special case of the Gamma). Because of this, it's very common to use prior knowledge to constrain your choice models to a subset of all possible models.

One trick to get around some problems in parameter estimation is to generate a lot of data, and leave some of the data out for cross-validation. To cross-validate your fit of parameters to data, leave some of the data out of your estimation procedure, and then measure each model's likelihood on the left-out data.