A Machine has 11 identical components which function independently. The probability that component will fail 0.2....

A machine is composed of 4 components that work independently and each component has its useful...

A machine is composed of 4 components that work independently and each component has its useful life related to an exponential model with an average of 3 years. It is known that the machine only works when the 4 components are in perfect condition. Determine the machine's service life density. Also calculate the probability that the machine's service life will exceed 4 years

A machine is composed of 4 components that work independently and each component has its useful...

A machine is composed of 4 components that work independently and each component has its useful life related to an exponential model with an average of 3 years. It is known that the machine only works when the 4 components are in perfect condition. Determine the machine's service life density. Also calculate the probability that the machine's service life will exceed 4 years

Consider a system with 10 identical components, all of which must work for the system to...

Consider a system with 10 identical components, all of which must work for the system to function. Determine the reliability of the system if the reliability of each component is 0.97. Assume components fail independently. Suppose we want a system reliability of 0.95, what should be the minimum reliability of each component?

An electronic circuit board contains 3000 electronic components. Assume that the probability that each component operates...

An electronic circuit board contains 3000 electronic components. Assume that the probability that each component operates without failure during the useful life of the product is 0.995, and assume that the components fail independently. Approximate the probability that 5 or more of the original 3000 components fail during the useful life of the product

Suppose that a certain system contains three components that function independently of each other and are...

Suppose that a certain system contains three components that function independently of each other and are connected in series, so that the system fails as soon as one of the components fails. Suppose that the length of life of the first component, X1, measured in hours, has an exponential distribution with parameter λ = 0.01; the length of life of the second component, X2, has an exponential distribution with parameter λ = 0.03; and the length of life of the...

An aircraft uses three active and identical engines in parallel. All engines fail independently. At least...

An aircraft uses three active and identical engines in parallel. All engines fail independently. At least one engine must function normally for the aircraft to fly successfully. The probability of success of an engine is 0.8. Calculate the probability of the aircraft crashing. Assume that one engine can only be in two states, i.e., operating normally or failed.

(a) An office has a stock of identical printed forms which are used independently. On any...

(a) An office has a stock of identical printed forms which are used independently. On any working day, at most one of the forms is used, and the probability that one form is used is 1/3. There are 250 working days in the year. (i) Using a suitable approximation, calculate the number of forms that must be in stock at the beginning of the year if there is to be a 95% probability that they will not all be used...

We have a system that has 2 independent components. Both components must function in order for...

We have a system that has 2 independent components. Both components must function in order for the system to function. The first component has 9 independent elements that each work with probability 0.92. If at least 6 of the elements are working then the first component will function. The second component has 6 independent elements that work with probability 0.85. If at least 4 of the elements are working then the second component will function. (a) What is the probability...

Consider n components with independent lifetimes, which are such that component i functions for an exponential...

Consider n components with independent lifetimes, which are such that component i functions for an exponential time with rate λi . Suppose that all components are initially in use and remain so until they fail. (a) Find the probability that component 1 is the second component to fail. (b) Find the expected time of the second failure.

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...