Let X be a gamma random variable with parameters α > 0 and β > 0....

Let X1,...,Xn i.i.d. Gamma(α,β) with α > 0, β > 0 (a) Assume both α and...

Let X1,...,Xn i.i.d. Gamma(α,β) with α > 0, β > 0 (a) Assume both α and β are unknown, find their momthod of moment estimators: αˆMOM and βˆMOM. (b) Assume α is known and β is unknown, find the maximum likelihood estimation for β.

Let X be a random variable with probability density function fX (x) = I (0, 1)...

Let X be a random variable with probability density function fX (x) = I (0, 1) (x). Determine the probability density function of Y = 3X + 1 and the density function of probability of Z = - log (X).

let X1, . . . , Xn i.i.d. Gamma(α, β), β > 0 known and α...

let X1, . . . , Xn i.i.d. Gamma(α, β), β > 0 known and α > 0 unknown. (a) Find the sufficient statistic for α (b) Use the sufficient statistic found in (a) to find the MVUE of α n . b) Use the sufficient statistic found in (a) to find the MVUE of α n

Let X ∼ Beta(α, β). (a) Show that EX 2 = (α + 1)α (α +...

Let X ∼ Beta(α, β). (a) Show that EX 2 = (α + 1)α (α + β + 1)(α + β) . (b) Use the fact that EX = α/(α + β) and your answer to the previous part to show that Var X = αβ (α + β) 2 (α + β + 1). (c) Suppose X is the proportion of free-throws made over the lifetime of a randomly sampled kid, and assume that X ∼ Beta(2, 8) ....

Let X be a gamma random variable with parameters alpha = 4 and beta = 4....

Let X be a gamma random variable with parameters alpha = 4 and beta = 4. Using Markov's inequality, calculate an upper bound for the probability that X is greater than or equal to 10.

Given α, β > 0, suppose X ∼ Gamma(α, β) and c is a positive constant....

Given α, β > 0, suppose X ∼ Gamma(α, β) and c is a positive constant. Using the method of transformations (Jacobian), show cX ∼ Gamma(α, cβ)

Let X and Y be independent exponentially distributed stochastic variables with parameters α and β. Find...

Let X and Y be independent exponentially distributed stochastic variables with parameters α and β. Find the distribution function (c.d.f.) of X / Y. Please show work involved and general equations used. As much supplementary text as possible will be greatly appreciated

5. Consider the random variable X with the following distribution function for a > 0, β...

5. Consider the random variable X with the following distribution function for a > 0, β > 0: FX (z) = 0 for z ≤ 0 ​= 1 – exp [–(z/a)β] for z > 0 (where exp y = ey) (a) Determine the inverse function of FX (z), where 0 < z < 1. (b) Let a = β = 2 for the random variable X, and define the numbers u1 = .33 and u2 = .9. Use the inverse...

Let Γ(α) be the Gamma function, defined by Γ(α) = ∫∞ 0 e −xx α−1 dx...

Let Γ(α) be the Gamma function, defined by Γ(α) = ∫∞ 0 e −xx α−1 dx for α > 0. Prove that Γ(1/2) = √ π. (Hint: Let y = √ 2x and use properties of the standard normal density function.).

Let X be a random variable with probability density function f(x) = {3/10x(3-x) if 0<=x<=2 .........{0...

Let X be a random variable with probability density function f(x) = {3/10x(3-x) if 0<=x<=2 .........{0 otherwise a) Find the standard deviation of X to four decimal places. b) Find the mean of X to four decimal places. c) Let y=x2 find the probability density function fy of Y.