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Jitter in a water power system. Refer to the Journal of
Chapter 7, Problem 91E(choose chapter or problem)
Jitter in a water power system. Refer to the Journal of Applied Physics investigation of throughput jitter in the opening switch of a prototype water power system, Exercise 6.100 (p. 340). Recall that low throughput jitter is critical to successful waterline technology. An analysis of conduction time for a sample of 18 trials of the prototype system yielded \(\bar{x}\) = 334.8 nanoseconds and s = 6.3 nanoseconds. (Conduction time is defined as the length of time required for the downstream current to equal 10% of the upstream current.) A system is considered to have low throughput jitter if the true conduction time standard deviation is less than 7 nanoseconds. Does the prototype system satisfy this requirement? Test using \(\alpha\) = .01.
Questions & Answers
QUESTION:
Jitter in a water power system. Refer to the Journal of Applied Physics investigation of throughput jitter in the opening switch of a prototype water power system, Exercise 6.100 (p. 340). Recall that low throughput jitter is critical to successful waterline technology. An analysis of conduction time for a sample of 18 trials of the prototype system yielded \(\bar{x}\) = 334.8 nanoseconds and s = 6.3 nanoseconds. (Conduction time is defined as the length of time required for the downstream current to equal 10% of the upstream current.) A system is considered to have low throughput jitter if the true conduction time standard deviation is less than 7 nanoseconds. Does the prototype system satisfy this requirement? Test using \(\alpha\) = .01.
ANSWER:Step 1 of 3
The given problem explains about the Jitter in a water power system.
Given an analysis of conduction time for a sample 18 trials of the prototype system yielded nanoseconds and s = 6.3 nanoseconds.
Then if the true conduction time standard deviation is less than 7 nanoseconds.
Our goal is :
We need to find if the prototype system satisfies this requirement.