21.4.5: Distribution of Extreme Values

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Page ID: 62811

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Problem:

A flashlight uses five batteries. The lifetime of each battery is independent and follows a Gamma distribution with mean 50 days and standard deviation 5 days (shape= 100, scale= 0.500). The flashlight will show light until the first battery dies.

What is the expected time the flashlight will work after receiving five new batteries?

If we know the distribution of the lifetimes of each component, does this mean we know the distribution of the minimum lifetime? Sometimes. Note that sometimes we may be curious about the distribution of a function of random variables... which is also a random variable.

But, it goes beyond simple curiosity. Calculating the distribution of functions of random variables is essential because it allows us to understand how transformations or combinations of random variables behave and how their uncertainty propagates. This knowledge is fundamental in many applications, such as deriving the sampling distribution of an estimator, which forms the basis for hypothesis testing and constructing confidence intervals. Additionally, understanding the distribution of these functions enables probabilistic modeling in scenarios where direct distributions are unavailable, such as in operations research or risk management. It also helps in determining the likelihood of complex events, optimizing decision-making, and evaluating reliability in systems involving random inputs. By studying these distributions, statisticians can make more accurate predictions and draw meaningful inferences in both theoretical and applied contexts.

Solution:

This is a great place for you to think through the problem (algorithmic thinking). What is the first step modeling this physical event? What is the second? Etc.? Write out the steps... and the code... in your notebook. If done correctly, you will obtain the graphic at the bottom of the page.

Conclusions:

The question actually asked for the expected lifetime of the flashlight. The expected lifetime (mean) of the flashlight is 44.3 days, with a standard deviation of 3.1 days (sd). It is nice to know that 90% of the flashlights survive between 39.1 and 49.2 days (quantile).

Distribution of flashlight lives

Extension:

King Rudolph wants to know the effect on flashlight lifetime if the batteries had a lifetime that followed a Gamma distribution with mean 50 days and standard deviation 2 days. What answer should I give to him?

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