2.6: Tom and Jerry Dive Into a Pool, Who Splashes First (Video Solution))

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Two students, Tom and Jerry, are jumping off a diving board into a swimming pool. Tom just drops straight downward off the board, and Jerry runs off the same board with some horizontal velocity v0.
a. Which diver, Tom or Jerry, has the greater splashdown speed? Or are they the same?
b. Calculate the splashdown speed for each diver, if the height of the board is 10 m, and Jerry's initial velocity is v0 = 4.5 m/s.

Summary

00:00:09 Introduction to a classical physics problem involving two divers, Tom and Jerry. Tom falls straight down from a diving board, while Jerry has an initial velocity in the x-direction. The question asks which diver has the greatest splashdown speed and requires calculating the splashdown speed for each diver given the height and Jerry's initial speed. The instructor, Prem-Raj Ruffin, begins by analyzing Tom's motion, noting that Tom starts with zero initial velocity in both x and y directions but speeds up as he falls.

00:01:30 Starting with the initial condition of Tom starting with zero initial velocity in both x and y directions but speeds up as he falls the instructor calculates Tom's final velocity, noting that acceleration due to gravity is 9.8 m/s².

00:08:32 The instructor moves on to analyze Jerry's motion.

00:13:22 The instructor talksabout a common mistake made in such problems, assuming that because Tom and Jerry have the same vertical velocity, they have the same impact speed.

00:18:06 The instructor summarizes the key insight: when comparing an object falling straight down to one with horizontal velocity, the object with horizontal velocity will always have a greater impact speed because it has velocity components in both directions. The instructor encourages students to practice this problem and similar ones repeatedly to reinforce physics concepts, comparing this practice to rehearsing a musical instrument. The instructor concludes by thanking the audience for submitting the problem and indicates that another physics problem will be discussed next time.

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