Summary table of probability terms: Difference between revisions

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* Given a random variable, we can compute the cumulative distribution function. How?
* Given a random variable, we can compute the cumulative distribution function. How?
* Given a distribution, we can retrieve a random variable. But this random variable is not unique? This is why we can say stuff like "let <math>X\sim \mathcal D</math>".
* Given a distribution, we can retrieve a random variable. But this random variable is not unique? This is why we can say stuff like "let <math>X\sim \mathcal D</math>".
* Given a distribution <math>\mu</math>, we can compute its density function. How? Just find the derivative. (?)
* Given a distribution <math>\mu</math>, we can compute its density function. How? Just find the derivative of <math>\mu((-\infty,x])</math>. (?)
* Given a cumulative distribution function, we can compute the random variable. (Right?)
* Given a cumulative distribution function, we can compute the random variable. (Right?)
* Given a probability density function, can we get everything else? Don't we just have to integrate to get the cdf, which gets us the random variable and the distribution?
* Given a probability density function, can we get everything else? Don't we just have to integrate to get the cdf, which gets us the random variable and the distribution?

Revision as of 09:43, 1 January 2018

This page is a summary table of probability terms.

Table

Term Symbol Type Definition
Reals R
Borel subsets of the reals B
Sample space Ω
Outcome ω Ω
Events or measurable sets F
Probability measure P or Pr or PF F[0,1]
Probability triple or probability space (Ω,F,P)
Distribution μ or D or D or PB or L(X) or PX1 B[0,1] BP(XB)
Induced probability space (R,B,μ)
Cumulative distribution function or CDF FX R[0,1]
Probability density function or PDF fX R[0,)
Random variable X ΩR
Indicator of A 1A Ω{0,1}
Expectation E or E (ΩR)R

Dependencies

Let (Ω,F,P) be a probability space.

  • Given a random variable X, we can compute its distribution μ. How? Just let μ(B)=PF(XB)
  • Given a random variable, we can compute the probability density function. How?
  • Given a random variable, we can compute the cumulative distribution function. How?
  • Given a distribution, we can retrieve a random variable. But this random variable is not unique? This is why we can say stuff like "let XD".
  • Given a distribution μ, we can compute its density function. How? Just find the derivative of μ((,x]). (?)
  • Given a cumulative distribution function, we can compute the random variable. (Right?)
  • Given a probability density function, can we get everything else? Don't we just have to integrate to get the cdf, which gets us the random variable and the distribution?
  • Given a cumulative distribution function, how do we get the distribution? We have FX(x)=PF(Xx)=PB((,x]), which gets us some of what the distribution PB maps to, but B is bigger than this. What do we do about the other value we need to map?

See also

External links