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 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 7 components, neading with at least 2 in full...

Compute the reliability of a system with 7 components, neading with at least 2 in full operation with the MTTF of each component being 2100 hours, after 2510 hours of operation Correct Answer: 0.676128323 Please solve without using excel. Please show all work.

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].

A system composes of three components. These components have constant failure rates of 0.0004, 0.0005, 0.0003...

A system composes of three components. These components have constant failure rates of 0.0004, 0.0005, 0.0003 failures per hour. The system will stop working, if any one of its components fails. Calculate the following: 1. The reliability of the system at 2500 hour running time? 2. The system hazard rate? 3. Mean time to failure of the system?

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...

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...

An electrical system consists of 2 components (C1 and C2) functioning independently and are set in...

An electrical system consists of 2 components (C1 and C2) functioning independently and are set in a parallel layout. The failure time of each component follows an exponential distribution with rate 2 every year. Identify the failure density and failure distribution of any component. Hence, calculate the probability of any component i) failing in less than 8 months. ii) surviving after 10 months.

1. An electronic system has two different types of components in joint operation. Let X1 and...

1. An electronic system has two different types of components in joint operation. Let X1 and X2 denote the Random Length of life in hundreds of hours of the components of Type I and Type II (Type 1 and Type 2), respectively. Suppose that the joint probability density function (pdf) is given by f(x1, x2) = { (1/8)y1 e^-(x1 + x2)/2, x1 > 0, x2 > 0 0 Otherwise. a.) Show that X1 and X2 are independent. b.) Find E(Y1+Y2)...

Find all solutions to the system: 2x ≡ 4 (mod 5) 3x ≡ 5 (mod 7)...

Find all solutions to the system: 2x ≡ 4 (mod 5) 3x ≡ 5 (mod 7) 7x ≡ 2 (mod 13) need help with discrete math HW, please write solutions clearly, and please don't just answer wrong solution, cus then i will need to post the same question twice. i appreciate every help i can get but please let someone else help me solve the question if you're not sure about any part to avoid reposting. thanks, will rate best...