17.2 Appendix c: data on some common distributions

Applied probability Page 1 / 1

Data are provided on some commonly used discrete and absolutely continuous distributions. Matlab procedures are provided for some.

Discrete distributions

Indicator functions $X = I_{E} P (X = 1) = P (E) = p P (X = 0) = q = 1 - p$
$E [X] = p Var [X] = p q M_{X} (s) = q + p e^{s} g_{X} (s) = q + p s$
Simple random variable $X = \sum_{i = 1}^{n} t_{i} I_{A_{i}} (a primitive form) P (A_{i}) = p_{i}$
$E [X] = \sum_{i = 1}^{n} t_{i} p_{i} Var [X] = \sum_{i = 1}^{n} t_{i}^{2} p_{i} q_{i} - 2 \sum_{i < j} t_{i} t_{j} p_{i} p_{j} M_{X} (s) = \sum_{i = 1}^{n} p_{i} e^{s t_{i}}$
Binomial $(n, p)$ $X = \sum_{i = 1}^{n} I_{E_{i}} with {I_{E_{i}} : 1 \leq i \leq n} iid P (E_{i}) = p$
$P (X = k) = C (n, k) p^{k} q^{n - k}$

$E [X] = n p Var [X] = n p q M_{X} (s) = {(q + p e^{s})}^{n} g_{X} (s) = {(q + p s)}^{n}$
MATLAB : $P (X = k) = ibinom (n, p, k) P (X \geq k) = cbinom (n, p, k)$
Geometric $(p)$ $P (X = k) = p q^{k} \forall k \geq 0$
$E [X] = q / p Var [X] = q / p^{2} M_{X} (s) = \frac{p}{1 - q e^{s}} g_{X} (s) = \frac{p}{1 - q s}$
If $Y - 1 \sim$ geometric $(p)$ , so that $P (Y = k) = p q^{k - 1} \forall k \geq 1$ , then
$E [Y] = 1 / p Var [X] = q / p^{2} M_{Y} (s) = \frac{p e^{s}}{1 - q e^{s}} g_{Y} (s) = \frac{p s}{1 - q s}$
Negative binomial $(m, p)$ . X is the number of failures before the m th success. $P (X = k) = C (m + k - 1, m - 1) p^{m} q^{k} \forall k \geq 0$ .
$E [X] = m q / p Var [X] = m q / p^{2} M_{X} (s) = {(\frac{p}{1 - q e^{s}})}^{m} g_{X} (s) = {(\frac{p}{1 - q s})}^{m}$
For $Y_{m} = X_{m} + m$ , the number of the trial on which m th success occurs. $P (Y = k) = C (k - 1, m - 1) p^{m} q^{k - m} \forall k \geq m$ .
$E [Y] = m / p Var [Y] = m q / p^{2} M_{Y} (s) = {(\frac{p e^{s}}{1 - q e^{s}})}^{m} g_{Y} (s) = {(\frac{p s}{1 - q s})}^{m}$
MATLAB : $P (Y = k) = nbinom (m, p, k)$
Poisson $(μ)$ . $P (X = k) = e^{- μ} \frac{μ^{k}}{k!} \forall k \geq 0$
$E [X] = μ Var [X] = μ M_{X} (s) = e^{μ (e^{s} - 1)} g_{X} (s) = e^{μ (s - 1)}$
MATLAB : $P (X = k) = ipoisson (m, k) P (X \geq k) = cpoisson (m, k)$

Absolutely continuous distributions

Uniform $(a, b)$ $f_{X} (t) = \frac{1}{b - a} a < t < b$ (zero elsewhere)
$E [X] = \frac{b + a}{2} Var [X] = \frac{{(b - a)}^{2}}{12} M_{X} (s) = \frac{e^{s b} - e^{s a}}{s (b - a)}$
Symmetric triangular $(- a, a)$ $f_{X} (t) = \{\begin{matrix} (a + t) / a^{2} & - a \leq t < 0 \\ (a - t) / a^{2} & 0 \leq t \leq a \end{matrix})$
$E [X] = 0 Var [X] = \frac{a^{2}}{6} M_{X} (s) = \frac{e^{a s} + e^{- a s} - 2}{a^{2} s^{2}} = \frac{e^{a s} - 1}{a s} \cdot \frac{1 - e^{- a s}}{a s}$
Exponential $(λ)$ $f_{X} (t) = λ e^{- λ t} t \geq 0$
$E [X] = \frac{1}{λ} Var [X] = \frac{1}{λ^{2}} M_{X} (s) = \frac{λ}{λ - s}$
Gamma $(α, λ)$ $f_{X} (t) = \frac{λ^{α} t^{α - 1} e^{- λ t}}{Γ (α)} t \geq 0$
$E [X] = \frac{α}{λ} Var [X] = \frac{α}{λ^{2}} M_{X} (s) = {(\frac{λ}{λ - s})}^{α}$
MATLAB : $P (X \leq t) = gammadbn (α, λ, t)$
Normal $N (μ, σ^{2})$ $f_{X} (t) = \frac{1}{σ \sqrt{2 π}} exp (- \frac{1}{2} {(\frac{t - μ}{σ})}^{2})$
$E [X] = μ Var [X] σ^{2} M_{X} (s) = exp (\frac{σ^{2} s^{2}}{2} + μ s)$
MATLAB : $P (X \leq t) = gaussian (μ, σ^{2}, t)$
Beta $(r, s)$
$f_{X} (t) = \frac{Γ (r + s)}{Γ (r) Γ (s)} t^{r - 1} {(1 - t)}^{s - 1} 0 < t < 1, r > 0, s > 0$

$E [X] = \frac{r}{r + s} Var [X] = \frac{r s}{{(r + s)}^{2} (r + s + 1)}$
MATLAB : $f_{X} (t) = beta (r, s, t) P (X \leq t) = betadbn (r, s, t)$
Weibull $(α, λ, ν)$
$F_{X} (t) = 1 - e^{- λ {(t - ν)}^{α}}, α > 0, λ > 0, ν \geq 0, t \geq ν$

$E [X] = \frac{1}{λ^{1 / α}} Γ (1 + 1 / α) + ν Var [X] = \frac{1}{λ^{2 / α}} [Γ (1 + 2 / λ) - Γ^{2} (1 + 1 / λ)]$
MATLAB : $(ν = 0$ only)
$f_{X} (t) = weibull (a, l, t) P (X \leq t) = weibulld (a, l, t)$

Relationship between gamma and poisson distributions

If $X \sim$ gamma $(n, λ)$ , then $P (X \leq t) = P (Y \geq n)$ where $Y \sim$ Poisson $(λ t)$ .
If $Y \sim$ Poisson $(λ t)$ , then $P (Y \geq n) = P (X \leq t)$ where $X \sim$ gamma $(n, λ)$ .

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Source: OpenStax, Applied probability. OpenStax CNX. Aug 31, 2009 Download for free at http://cnx.org/content/col10708/1.6

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