Let B~Binomial(n,p) denote a binomially distributed random variable with n trials and probability of success p....

Let X be a binomial random variable with n = 400 trials and probability of success...

Let X be a binomial random variable with n = 400 trials and probability of success p = 0.01. Then the probability distribution of X can be approximated by Select one: a. a Hypergeometric distribution with N = 8000,  n = 400,  M = 4.     b. a Poisson distribution with mean 4. c. an exponential distribution with mean 4. d. another binomial distribution with  n = 800, p = 0.02 e. a normal distribution with men 40 and variance 3.96.

Assume that Y is distributed according to a binomial distribution with n trials and probability p...

Assume that Y is distributed according to a binomial distribution with n trials and probability p of success. Let g(p) be the probability of obtaining either no successes or all successes, out of n trials. Find the MLE of g(p).

Suppose we have a binomial distribution with n trials and probability of success p. The random...

Suppose we have a binomial distribution with n trials and probability of success p. The random variable r is the number of successes in the n trials, and the random variable representing the proportion of successes is p̂ = r/n. (a) n = 44; p = 0.53; Compute P(0.30 ≤ p̂ ≤ 0.45). (Round your answer to four decimal places.) (b) n = 36; p = 0.29; Compute the probability that p̂ will exceed 0.35. (Round your answer to four...

Let Y denote a geometric random variable with probability of success p, (a) Show that for...

Let Y denote a geometric random variable with probability of success p, (a) Show that for a positive integer a, P(Y > a) = (1 − p) a (b) Show that for positive integers a and b, P(Y > a + b|Y > a) = P(Y > b) = (1 − p) b This is known as the memoryless property of the geometric distribution.

Consider a binomially distributed random variable constructed from a series of 8 trials with a 60%...

Consider a binomially distributed random variable constructed from a series of 8 trials with a 60% chance of success on any given trial. Calculate the probability that there are more than 3 successes.

Let X be the binomial random variable obtained by adding n=4 Bernoulli Trials, each with probability...

Let X be the binomial random variable obtained by adding n=4 Bernoulli Trials, each with probability of success p=0.25. Define Y=|X-E(x)|. Find the median of Y. A.0 B.1 C.2 D.3 E.Does not exist

Suppose  is a Binomial random variable for which there are 8 independent trials and probability of success...

Suppose  is a Binomial random variable for which there are 8 independent trials and probability of success 0.5 and is a Binomial random variable for which there are 10 independent trials and probability of success 0.5. What is the difference in their means? a. 1 b. 1.25 c. 1.5 d. 0.5 e. 2

consider a binomially distributed random variable resulting from a series of 100 independent trials with a...

consider a binomially distributed random variable resulting from a series of 100 independent trials with a 70% chance of success on any given trial. use the normal approximation to ESTIMATE the probability of observing more than 64 but less than 76 successes

A) Suppose we are considering a binomial random variable X with n trials and probability of...

A) Suppose we are considering a binomial random variable X with n trials and probability of success p. Identify each of the following statements as either TRUE or FALSE. a) False or True - The variance is greater than n. b)    False or True - P(X=n)=pn. c)    False or True - Each individual trial can have one of two possible outcomes. d)    False or True - The largest value a binomial random variable can take is n + 1. e)...

Let X denote a random variable that follows a binomial distribution with parameters n=5, p=0.3, and...

Let X denote a random variable that follows a binomial distribution with parameters n=5, p=0.3, and Y denote a random variable that has a Poisson distribution with parameter λ = 6. Additionally, assume that X and Y are independent random variables. Derive the joint probability distribution function for X and Y. Make sure to explain your steps.