Calculate the cumulative hazard rate for the Weibull distribution with the parametres β=2.5, η=200h at time...

The reliability of a component is modelled by a two parameter Weibull distribution with a shape...

The reliability of a component is modelled by a two parameter Weibull distribution with a shape factor (β) equal to 2, and scale factor (η) equal to 100 weeks. The reliability function (R(t)) as a function of time (weeks) is: ?(?) = ?-(t/η)^β a) Explain what the reliability function represents, and when it might be used? (1 mark) b) If the component has survived for 20 weeks of operation, what is the probability that the component will fail in the...

Assume that the lifespan of an Asian hornet follows a Weibull distribution with parameters β =...

Assume that the lifespan of an Asian hornet follows a Weibull distribution with parameters β = 2.0 and δ = 62 days. a)Determine the probability that an Asian hornet lives longer than 50 days. b)Determine the mean time in days until death of an Asian hornet. c)Determine the median life time of Asian hornet in days. (Hint: For median, m , P ( X ≤ m ) = 0.5 , X i s t h e l i f e...

The length of time in hours that a certain part lasts follows a Weibull distribution with...

The length of time in hours that a certain part lasts follows a Weibull distribution with parameters α = 2 and β = 2. a. What are the mean and standard deviation of this distribution? b. What is the probability that the part lasts less than 1 hour? c. What is the equation for the failure rate of the part? d. If the distribution is actually Gamma instead of Weibull find the equation for the failure rate of the part...

The lifespan of a system component follows a Weibull distribution with α (unknown) and β=1. (hint:...

The lifespan of a system component follows a Weibull distribution with α (unknown) and β=1. (hint: start with confidence interval for μ) f(x)=αβX^(β-1) exp(-αX^β) a. Derive 92% large sample confidence interval for α. b. Find maximum likelihood estimator of α.

Suppose that the time to death X has an exponential distribution with hazard rate and that...

Suppose that the time to death X has an exponential distribution with hazard rate and that the right-censoring time C is exponential with hazard rate . LetT min(X,C) and 1 ifX C;0 ,if X C. Assume that X and C are independent. (a) Find P( 1) (b) Find the distribution of T. (c) Show that and T are independent. (d) Let (T1, 1),...,(Tn, n) be a random sample from this model. Show that the maximum likelihood estimator of is n...

The lifespan of a system component follows a Weibull distribution with α (unknown) and β=1. (hint:...

The lifespan of a system component follows a Weibull distribution with α (unknown) and β=1. (hint: start with confidence interval for μ) f(x)=αβXβ-1 exp(-αXβ) a.      Derive 92% large sample confidence interval for α. b.      Find maximum likelihood estimator of α.

The lifespan of a system component follows a Weibull distribution with α (unknown) and β=1. (hint:...

The lifespan of a system component follows a Weibull distribution with α (unknown) and β=1. (hint: start with confidence interval for μ) f(x)=αβXβ-1 exp(-αXβ) a.      Derive 92% large sample confidence interval for α. b.      Find maximum likelihood estimator of α.

Suppose a car radiator useful lifetime has Weibull distribution with β = 1.5 and the mean...

Suppose a car radiator useful lifetime has Weibull distribution with β = 1.5 and the mean lifetime of 150,000 miles. John has just bought a used car with 180,000 miles and original radiator which is still good. What is the probability that it’s going to last at least 20,000 miles more before needing replacement?

3. Suppose a car radiator useful lifetime has Weibull distribution with β = 1.5 and the...

3. Suppose a car radiator useful lifetime has Weibull distribution with β = 1.5 and the mean lifetime of 150,000 miles. John has just bought a used car with 180,000 miles and original radiator which is still good. What is the probability that it’s going to last at least 20,000 miles more before needing replacement?

A particular circulation pump has a Weibull lifetime distribution with a rate parameter λ = 0.064...

A particular circulation pump has a Weibull lifetime distribution with a rate parameter λ = 0.064 per 1000 hours and a shape parameter β = 1.23. What is the probability that this pump will run for at least 1300 hours? Express your answer rounded to three decimal places.