# What is the Moon's distance from viewer at horizon? From a viewer's standpoint, when the moon starts to rise at the horizon, is the moon at the furthest distance from the viewer visually? The Moon differs from most satellites of other planets in that its orbit is close to the plane of the ecliptic, and not to Earth's equatorial plane. Remember the moon orbits the earth not the viewer.

• If we assume the Moon's distance from the center of the Earth is constant for a given day or so (which is only approximately true), then yes. The moon is furthest away when it's at your nadir (below your feet), but it's not visible then. For when it's visible, it's furthest at moonrise and moonset, and closest when the moon culminates.
– user967
Jan 17 '16 at 15:51
• Source = Euclidean Geometry. Let's assume the moon has a perfectly circular orbit = 250,000 miles from Earth's center and the Earth has a diameter of exactly 4,000 miles (radius = 2,000). With these assumptions at moon rise or set it is 2,000 + 248,000 miles from an observer or 250,000 miles, but from an observer with the moon directly overhead it is 248,000 miles, as the observer is 2,000 miles closer. This does not take into consideration triangulation distances. I think they would be pretty minimal. Jan 17 '16 at 18:28
• I'm working on an answer to this at github.com/barrycarter/bcapps/blob/master/ASTRO/… but, if you allow for the ellipticity of the Moon's orbit (apogee and perigee), the answer is no: the moon can be further away after it rises than it is at the horizon.
– user967
Jan 18 '16 at 19:21
• Comments are not for extended discussion; this conversation has been moved to chat. Jan 21 '16 at 18:48

What is the Moon's distance from viewer at horizon?

As noted by others, the moon follows an elliptical orbit, which will lead to the greatest change in distance regardless of the observation angle.

However, we can place some upper and lower bounds on what the distance at the horizon would be by using the maximum and minimum orbital radii (the apogee and perigee respectively) along with Pythagoras's theorem. In the image above, the larger circle represents the Earth, and the smaller is the Moon. $R$ is the radius of the Earth, $d$ is the orbital distance of the moon from the Earth's centre, and $x$ is the distance of the Moon from the observer when the Moon is on the horizon.

Pythagoras's theorem states that

$$d^2 = x^2 + R^2$$

Which we can rearrange to give $x$,

$$x = \sqrt{d^2 - R^2}$$

Now just substitue the numbers in. I used the following values from the Orbit of the Moon wiki:

Perigee: 362600 km, Apogee: 405400 km, average orbital distance: 385000km, radius of the Earth: 6371km

At Apogee, $x$ = 405349 km

At Perigee, $x$ = 362544 km

At average orbital distance, $x$ = 384947 km

From a viewers standpoint When the moon starts to rise at the horizon, Is the moon at the furthest distance from the viewer visually?

As noted above, viewing angle is not the primary factor in the distance calculation. However, for a given point in its orbit, the Moon is at its furthest visible radius from the Earth at the Horizon. We can see this by comparing to the Moons distance when directly above the observer. This will be the Moon's orbital radius minus the radius of the Earth. For each orbital point this is:

At Perigee: 356229 km, at Apogee: 399029 km, at average orbital distance: 378629 km

Each of which is around 6300 km closer than when the same orbital configuration is viewed at the Horizon. The Moon may appear larger at the horizon, and hence closer, but this is an illusion.

The Moon differs from most satellites of other planets in that its orbit is close to the plane of the ecliptic, and not to Earth's equatorial plane

For the horizon distance, the position of the observer on the Earth makes no difference: when the Moon is at the Horizon the distance, for a given orbital configuration, will be the same (minus altitude differences on the Earth's surface). However, from some observational positions the Moon will never be directly above, so the second part is location dependent.

I want one source from each of the following governments sites- ( U.K gov)(Russian gov)and (Chinese gov) and the sources HAVE to all state a ''similar'' distance.

I doubt that this data is available publicly on government websites. If it was, you could probably find it yourself.

The Moon's orbit is elliptical, not circular, and the maximum and minimum distance from the Moon to the center of the Earth (apogee and perigee, 405,385 and 363,630 km respectively) are much larger than the radius of the Earth (6370 km). Therefore, the distance you are asking for is very variable and it does not depend so much on the position of the Moon relative to the observer's horizon, but mainly on the position of the Moon along its own orbit.