Suppose someone drops a rock off a cliff of height h. As it falls, I snap a million photographs, at random intervals. On each picture I measure the distance the rock has fallen. Question: What is the average of all these distances? That is to say, what is the time average of the distance traveled?

Question

Suppose someone drops a rock off a cliff of height [latex] h[/latex]. As it falls, I snap a million photographs, at random intervals. On each picture I measure the distance the rock has fallen. Question: What is the average of all these distances? That is to say, what is the time average of the distance traveled?

Accepted Answer

The rock starts out at rest, and picks up speed as it falls; it spends more time near the top, so the average distance will surely be less than [latex]{h}/{2}[/latex] . Ignoring air resistance, the distance [latex] x[/latex] at time [latex] t[/latex] is [latex] x\left(t\right) = \frac{1}{2} g t^{2}.[/latex]

The velocity is [latex] {dx }/{dt} = gt [/latex] , and the total flight time is [latex] T = \sqrt{{2h}/{g}} [/latex] .The probability that a particular photograph was taken between [latex] t [/latex] and [latex] t + dt [/latex] is [latex]{ dt }/{T} [/latex] , so the probability that it shows a distance in the corresponding range [latex] x [/latex] to [latex] x + dx [/latex] is

[latex]\frac{dt}{T}=\frac{dx }{gt} \sqrt{\frac{g}{2h} } = \frac{1}{2\sqrt{hx} } dx [/latex] .

Thus the probability density (Equation 1.14):

{probability that an individual (chosen at random)lies between x and (x + dx)} = [latex]\rho(x)dx[/latex]

is

[latex] \rho \left(x\right) = \frac{1}{2\sqrt{hx} } [/latex] , [latex] ( 0\leq x \leq h )[/latex]

(outside this range, of course, the probability density is zero).

We can check this result, using Equation 1.16:

[latex]\int_{-\infty}^{+\infty}{\rho(x)dx}=1[/latex]

[latex] \int_{0}^{h}{\frac{1}{2\sqrt{hx} }} dx = \frac{1}{2\sqrt{h} }\left(2x^{{1}/{2}} \right)\mid ^{h}_{0} = 1 [/latex]

The average distance (Equation 1.17):

[latex]\left\langle x\right\rangle=\int_{-\infty}^{+\infty}{\rho(x)dx} [/latex]

is

[latex]\left\langle x\right\rangle = \int_{0}^{h}{x\frac{1}{2\sqrt{hx} }} dx = \frac{1}{2\sqrt{h} }\left(\frac{2}{3} x^{{3}/{2}} \right)\mid ^{h}_{0} = \frac{h}{3} [/latex]

which is somewhat less than [latex] {h}/{2} [/latex] , as anticipated.

Figure 1.7 shows the graph of [latex] \rho \left(x\right) [/latex].Notice that a probability density can be infinite though probability itself (the integral of ρ) must of course be finite (indeed, less than or equal to1).

Question 1.2: Suppose someone drops a rock off a cliff of height h. As it ...

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