# Intuitively, why should a random variable have a distribution?

When we think about random variables or random processes, why do we make the a priori assumption that a particular realization had to come from a distribution? Why do we even have the concept of distribution? Is there a way for the concept of randomness to exist without the notion of distribution?

• (Because it would impact the style of answer I'd give) ... what do you understand the terms 'random variable' and 'distribution' to mean? – Glen_b -Reinstate Monica Apr 18 '15 at 7:52
• I mean that the realization had to come from some finite 'box' of values when I talk about distribution. How do we even know the distribution exists before the realization occurs? Why can't the realization come from an infinite set of values? And by random, I mean having no pattern whatsoever. – lord12 Apr 18 '15 at 9:15
• Any variable with a continuous distribution can take an infinite number of possible values. – Glen_b -Reinstate Monica Apr 18 '15 at 9:21
• Certain things are "knightian uncertain". They do not have a distribution, or at least a known distribution. I suppose a Bayesian would say we have no logical prior for such things. My professor used the following example of something that is legitimately uncertain in a prior-less way: what is the probability that aliens are purple? We can guess... but that's not really going to reflect the actual distribution of alien-colors, only our apelike tendency to guess particular numbers. – RegressForward Apr 18 '15 at 10:20

When dealing with random events, your goal is make intelligent guesses / predictions, otherwise all you can do is say "This is random, I don't know what to do" and go home crying.

Philosophically speaking, Distributions and Random Variables are ways to model random events given our prior knowledge (Bayesian approach) or the frequency of past events (Frequentist approach).

And you know what, it actually works...

For example, if you work in the logistic department in a hospital and need to buy diapers for the new born babies, Empirical data shows that modelling the weight of newborns as a normal distribution makes sense, and seem to work quite well.

In measure theory and in probability, a random variable is a measurable function \begin{align*} X: &\Omega \longrightarrow \mathbb{R}\\&\omega\longrightarrow X(\omega)\end{align*} from a set of possible outcomes $\Omega$ to the set $\mathbb{R}$. The set $\Omega$ is a probability space, i.e., $(\Omega, \mathcal{F}, P)$ corresponds to a (usually Borel) $\sigma$-algebra $\mathcal{F}$ and a probability $P$ over the elements of $\mathcal{F}$. For instance, $(\Omega, \mathcal{F}, P)=([0,1],\mathcal{B}([0,1]),\mathcal{U})$ where $\mathcal{U}$ is the uniform measure can produce all real valued random variable with distribution $F_X$ as $$X(\omega)=F_X^{-1}(\omega)$$That we do not know the distribution of a random variable about to be observed or already observed does not impact the very existence of this distribution.

Addendum: There is a philosophical debate in the Philosophy of Sciences about the very notion of randomness, that is whether or not it exists at all, but I do not think this pertains to your question.

Statistics is concerned with the approximation of this distribution within a certain family of distributions, either parametric, i.e., parameterised by a finite dimensional parameter $\theta$,$$X\sim f_\theta(x)$$ or non-parametric, which means using a family of approximations, e.g.,$$X\sim\frac{1}{n}\sum_{i=1}^n\mathcal{N}_p(x_i,\Sigma)$$It is clearly aknowledged that those are approximations in most settings and the truth" about the genuine distribution cannot be established with a finite set of observations.