To do these calculations, we'll need some (but not all) of the following numbers. Can you think of which one(s) we don't need?

The orbital period $T$ is the time (in seconds) it takes to go around the planet. To find it, we start by setting the gravitational force equal to the centripetal force:

$$ \frac{GMm}{r^2} = \frac{mv^2}{r} $$

Here's what all those variables mean:

• $G$ = 6.67 x 10^-11 N·m²/kg² is the universal gravitational constant. We usually call it “big gee”.
• $M$ is the mass of the planet (or star).
• $m$ is the mass of what orbits around. Notice how $m$ cancels in this equation. It means that the mass of the orbiting object has no effect on the speed at which it orbits. Again, lucky for the ISS astronauts!
• $r$ is the distance (radius) between the centre of mass of the planet (or star) and that of the orbiting object.
• $v$ is the tangential speed of the orbiting object. That is, it's the speed, parallel to the surface, at which the object is flying.

$v$ can calculated by taking the total distance around the Earth (the circumference of a circle) divided by the period of revolution, $T$, which is what we're really after:

$$v = \frac{2\pi r}{T}$$

Thus, the previous equation becomes:

$$ \frac{GMm}{r^2} = \frac{m}{r}\left(\frac{2\pi r}{T} \right)^2 $$

Simplifying and solving for $T$, we get:

$$ T = 2 \pi \sqrt{\frac{r^3}{GM}}$$

Again, notice that the only mass that matters is that of the Earth, not the Moon or the ISS.

So for the ISS, the orbital period is:

$$ T = 2 \pi \sqrt{\frac{(6.37\times 10^6 + 4.2\times 10^5)^3}{(6.67 \times 10^{-11})(5.97 \times 10^{24})}} = 55\underline{7}1 \text{ sec} = 92.\underline{8}5 \text{ min}$$

And for the Moon, it's:

$$ T = 2 \pi \sqrt{\frac{(6.37\times 10^6 + 4.2\times 10^5 + 1.74\times 10^6)^3}{(6.67 \times 10^{-11})(5.97 \times 10^{24})}} = 78\underline{4}4 \text{ sec} = 13\underline{0}.7 \text{ min}$$

The reason I've underlined some digits is because they are the last significant ones. I kept a few digits afterwards so I can reuse these results in subsequent calculations without accumulating rounding errors.

We know how long it takes for the ISS and the Moon to go around Earth (360°). Now, we need to find the fraction of their orbit when they are above the horizon.

The ISS

If we draw a right triangle from the centre of the Earth to the ISS and to us, we see that

• the vertical side of the triangle is the radius of the Earth (6370 km)
• and the hypotenuse is the radius of the ISS's orbit (6370 km + 420 km = 6790 km)
• The angle of this right triangle is: $$\cos^{-1}\left(\frac{6370}{6790}\right) = 20.258^{\circ}$$
• Which means the fly by duration is: $$ \frac{(2)(20.258^\circ)}{360^\circ} 92.\underline{8}5 \text{ min} = 10.\underline{4}4 \text{ min}$$

The Moon

For the Moon, it's a bit more complicated since we can't treat it as a point (like the ISS). Instead, we have to find out where the Moon's centre is when its tip breaks above the horizon.

• To find the vertical leg of the right triangle, we subtract the Earth's and the Moon's radii: 6370 km - 1740 km = 4630 km.
• To find the hypotenuse of the triangle, we add the Earth's radius with the surface distance and the Moon's radius: 6370 km + 420 km + 1740 km = 8530 km
• Then, the angle of this right triangle is: $$\cos^{-1}\left(\frac{4630}{8530}\right) = 57.126^{\circ}$$
• Which means the fly by duration is: $$ \frac{(2)(57.126^\circ)}{360^\circ} 13\underline{0}.7 \text{ min} = 41.\underline{4}8 \text{ min } $$

Visible Surface Area

Before calculating specific cases, we need to derive a general formula for calculating the percentage of visible surface area as a function of the angle.

• Let's start by rotating the Moon so that the visible part is pointing to the right.
• Next, we draw an infinitesimally small strip on the surface that goes all the way around (in green).
• That strip is essentially a very thin rectangle wrapped around. Its length is $2\pi r$ and its width is $R d\theta$
• The area of that strip is thus: $dA = (2 \pi r)(R d\theta)$
• As $\theta$ changes, $r$ changes as such: $r = R\sin\theta$
• So the area element is: $dA = (2 \pi R\sin\theta)(R d\theta) = 2 \pi R^2 \sin\theta d\theta$
• To find the total visible area, we integrate between 0 and the final angle $\theta$:

$$A(\theta) = \int_0^\theta 2 \pi R^2 \sin\theta' d\theta'$$ $$ = 2 \pi R^2 \int_0^\theta \sin\theta' d\theta'$$ $$ = 2 \pi R^2 \cos\theta \Big|_\theta^0$$ $$ = 2 \pi R^2 (1 - \cos\theta)$$

• Let's test it. We know that the total surface area of a sphere is $4\pi R^2$. According to our formula, we need θ = 180° to cover the whole circle: $ A = 2 \pi R^2 (1 - \cos(180^\circ)) = 2 \pi R^2 \big(1 - (-1)\big) = 4 \pi R^2$

• So the percentage of the surface area we see is given by:

$$ 100\% \times \frac{A(\theta)}{A_\text{sphere}} = 100\% \times \frac{2 \pi R^2 (1 - \cos\theta)}{4 \pi R^2} $$

At The Horizon:

The first step is to find all sides and angles of this right triangle.

• To find the horizontal side, we start by finding the coordinates of the Moon's centre.
  • Since it's right above the horizon, the y-coordinate is $6370 + 1740 = 8110$
  • Then we use the equation of the Moon's orbit to find the x-coordinate: $$ x^2 + y^2 = (6370 + 420 + 1740)^2 $$ $$ x^2 + (8110)^2 = (8530)^2 $$ $$ x = 26\underline{4}3.6$$

• The hypotenuse of the triangle is $\sqrt{1740^2 + 26\underline{4}3.6^2} = 31\underline{6}4.9$

• This means that the closest point of the Moon is 3164.9 km - 1740 km = 1424.9 km from us.

Next we find the angles:

• The angle at “You Are Here” is:

$$\tan^{-1}\left( \frac{1740}{2643.6} \right) = 33.35^\circ$$

• So the angular size is double: 66.7°

• And the angle at the centre of the Moon is 90° - 33.35° = 56.65° so the percentage of the surface we see is: $50\% \big(1 - \cos(56.65°)\big) = 22.5 \%$

Overhead:

The same calculations are much simpler in this case.

• The hypotenuse is simply 1740 km + 420 km = 2160 km and we don't need the other side.

• The angle at “You Are Here” is: $$\sin^{-1}\left( \frac{1740}{2160} \right) = 53.66^\circ$$

• So the angular size is double: 107.3°

• And the angle at the centre of the Moon is 90° - 53.66° = 36.34° so the percentage of the surface we see is: $50\% \big(1 - \cos(36.34°)\big) = 9.7 \%$