Review:
Random Variables and Distribution Functions
Review Random Variables
Review Random Variables
Discrete Random Variables
Binomial Distribution
Poisson Distribution
Continuous Random Variables
Uniform Distribution
Normal Distribution
Random Variables
A random variable is function that maps the sample space to real value.
Discrete Random Variables
Review Random Variables
Discrete Random Variables
Binomial Distribution
Poisson Distribution
Continuous Random Variables
Uniform Distribution
Normal Distribution
Discrete Random Variables
A random variable is considered to be discrete if it can only map to a finite or countably infinite number of distinct values.
PMF
The probability mass function of discrete variable can be represented by a formula, table, or a graph. The Probability of a random variable Y can be expressed as \(P(Y=y)\) for all values of \(y\).
CDF
The cumulative distribution function provides the \(P(Y\leq y)\) for a random variable \(Y\).
Expected Value
The expected value is the value we expect when we randomly sample from population that follows a specific distribution. The expected value of Y is
\[ E(Y)=\sum_y yP(y) \]
Variance
The variance is the expected squared difference between the random variable and expected value.
\[ Var(Y)=\sum_y\{y-E(Y)\}^2P(y) \]
\[ Var(Y) = E(X^2) - E(X)^2 \]
Known Distributions
| Distribution | Parameter(s) | PMF \(P(Y=y)\) |
|---|---|---|
| Bernoulli | \(p\) | \(p\) |
| Binomial | \(n\) and \(p\) | \((^n_y)p^y(1-p)^{n-p}\) |
| Geometric | \(p\) | \((1-p)^{y-1}p\) |
| Negative Binomial | \(r\) and \(p\) | \((^{y-1}_{r-1})p^{r-1}(1-p)^{y-r}\) |
| Hypergeometric | \(N\), \(n\), and \(r\) | \(\frac{(^r_y)(^{N-r}_{n-y})}{(^N_n)}\) |
| Poisson | \(\lambda\) | \(\frac{\lambda^y}{y!} e^{-\lambda}\) |
Binomial Distribution
Review Random Variables
Discrete Random Variables
Binomial Distribution
Poisson Distribution
Continuous Random Variables
Uniform Distribution
Normal Distribution
Binomial Distribution
An experiment is said to follow a binomial distribution if
- Fixed \(n\)
- Each trial has 2 outcomes
- The probability of success is a constant \(p\)
- The trials are independent of each
\(P(X=x)=(^n_x)p^x(1-p)^{n-x}\)
Expected Value of a Binomial Distribution
Continued
Poisson Distribution
Review Random Variables
Discrete Random Variables
Binomial Distribution
Poisson Distribution
Continuous Random Variables
Uniform Distribution
Normal Distribution
Poisson Distribution
The poisson distribution describes an experiment that measures that occurrence of an event at specific point and/or time period.
\(P(X=x)=\frac{\lambda^x}{x!}e^{-\lambda}\)
Expected Value of a Poisson Distribution
Continuous Random Variables
Review Random Variables
Discrete Random Variables
Binomial Distribution
Poisson Distribution
Continuous Random Variables
Uniform Distribution
Normal Distribution
Continuous Random Variables
A random variable \(X\) is considered continuous if the \(P(X=x)\) does not exist.
CDF
The cumulative distribution function of \(X\) provides the \(P(X\leq x)\), denoted by \(F(x)\), for the domain of \(X\).
Properties of the CDF of \(X\):
- \(F(-\infty)\equiv \lim_{y\rightarrow -\infty}F(y)=0\)
- \(F(\infty)\equiv \lim_{y\rightarrow \infty}F(y)=1\)
- \(F(x)\) is a nondecreaseing function
The probability density function of the random variable \(X\) is given by
\[ f(x)=\frac{dF(x)}{d(x)}=F^\prime(x) \]
wherever the derivative exists.
Properties of pdfs:
- \(f(x)\geq 0\)
- \(\int^\infty_{-\infty}f(x)dx=1\)
- \(P(a\leq X\leq b) = P(a<X<b)=\int^b_af(x)dx\)
Expected Value
The expected value for a continuous distribution is defined as
\[ E(X)=\int x f(x)dx \]
The expectation of a function \(g(X)\) is defined as
\[ E\{g(X)\}=\int g(x)f(x)dx \]
Expected Value Properties
- \(E(c)=c\), where \(c\) is constant
- \(E\{cg(X)\}=cE\{g(X)\}\)
- \(E\{g_1(X)+g_2(X)+\cdots+g_n(X)\}=E\{g_1(X)\}+E\{g_2(X)\}+\cdots+E\{g_n(X)\}\)
Variance
The variance of continuous variable is defined as
\[ Var(X) = E[\{X-E(X)\}^2] = \int \{X-E(X)\}^2 f(x)dx \]
Uniform Distribution
Review Random Variables
Discrete Random Variables
Binomial Distribution
Poisson Distribution
Continuous Random Variables
Uniform Distribution
Normal Distribution
Uniform Distribution
A random variable is said to follow uniform distribution if the density function is constant between two parameters.
\[ f(x) = \left\{\begin{array}{cc} \frac{1}{b-a} & a \leq x \leq b\\ 0 & \mathrm{elsewhere} \end{array}\right. \]
Expected Value
Normal Distribution
Review Random Variables
Discrete Random Variables
Binomial Distribution
Poisson Distribution
Continuous Random Variables
Uniform Distribution
Normal Distribution
Normal Distribution
A random variable is said to follow a normal distribution if the the frequency of occurrence follow a Gaussian function.
\[ f(x)=\frac{1}{\sqrt{2\pi \sigma^2}}\exp\left\{-\frac{(x-\mu)^2}{2\sigma^2}\right\} \]
Expected Value
Continued