Compute the reliability of a system with 7 components, neading with at least 2 in full...

Compute the reliability of a system with 4 components in standby parallel configuration, with failure rate...

Compute the reliability of a system with 4 components in standby parallel configuration, with failure rate of 0.000346 after 7600 hours of operation. Correct Answer: 0.729547242 Please solve without using excel.

Compute the reliability of a system with 4 components in standby parallel configuration, with failure rate...

Compute the reliability of a system with 4 components in standby parallel configuration, with failure rate of 0.000346 after 7600 hours of operation ANSWER: 0.729547242 PLEASE SHOW ALL WORK

Compute the reliability of a system with 4 components in series configuration, with failure rate of...

Compute the reliability of a system with 4 components in series configuration, with failure rate of 0.000471 after 860 hours of operation I need correct answer please!

A system consists of n identical components in parallel with each component having a reliability of...

A system consists of n identical components in parallel with each component having a reliability of p. The failure events of the components can be assumed to be independent. Compute the reliability of the system as functions of p and n. Plot system reliability as functions of p and n for the ranges of p = [0.9, 0.99, 0.999] and n = [3, 5, 10, 100, 1000].

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?

Assume that a system works properly if at least three out of five components work properly....

Assume that a system works properly if at least three out of five components work properly. Assume all components have equal reliability r. Compute the probability that the system works properly. Now assume the r=.9. What is the reliability of the system?

A system consisting of four components is said to work whenever both at least one of...

A system consisting of four components is said to work whenever both at least one of components 1 and 2 work and at least one of components 3 and 4 work. Suppose that component ? alternates between working and being failed in accordance with a nonlattice alternating renewal process with distributions ?? and ??,?=1,2,3,4. If these alternating renewal processes are independent, find lim?→∞=?{system is working at time ?}.

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...

The principle of redundancy is used when system reliability is improved through redundant or backup components....

The principle of redundancy is used when system reliability is improved through redundant or backup components. Assume that a​ student's alarm clock has a 5.7​% daily failure rate. Complete parts​ (a) through​ (d) below. a. What is the probability that the​ student's alarm clock will not work on the morning of an important final​ exam? (Round to three decimal places as​ needed.) b. If the student has two such alarm​ clocks, what is the probability that they both fail on...

The principle of redundancy is used when system reliability is improved through redundant or backup components....

The principle of redundancy is used when system reliability is improved through redundant or backup components. Assume that a​ student's alarm clock has a 18.7 ​% daily failure rate. Complete parts​ (a) through​ (d) below. a. What is the probability that the​ student's alarm clock will not work on the morning of an important final​ exam? nothing ​(Round to three decimal places as​ needed.) b. If the student has two such alarm​ clocks, what is the probability that they both...