Starship Asterisk*

geckzilla wrote:
The dwarf's shadow is negligible and barely noticeable.

geckzilla wrote:Yeah, and that's at maximum possible separation. Say if the planet somehow rotated in such a way that matched their orbital period and the only piece of land for a person to stand on made it so only one star was visible during sunset and sunrise, that person would eventually figure out there are two stars by looking at their shadow at noon, even though the fact would be obscured from direct observation by the glare.

Jim Kaler wrote:
The brighter is a yellow class G2 hydrogen-fusing dwarf star that, with a temperature of 5790-5850 Kelvin (a bit warmer than the solar temperature of 5780 K), appears almost identical to our G2 Sun, certainly an odd coincidence. The companion, over a magnitude fainter, is a cooler (5260-5320 Kelvin) class K1 dwarf, the two making an obvious color contrast. The pair orbit each other every 79.9 years. Though they average 23.2 Astronomical Units apart (21 percent farther than Uranus is from the Sun), the elliptical orbit sends them from a farthest distance of 35 AU to 11, just over Saturn's solar distance.
...
Direct measure of radius through interferometry gives a radius for Alpha-A of 1.21 solar and for Alpha-B of 0.85 solar

geckzilla wrote:

Ann wrote:So, Geck, imagine a planet orbiting Algol. There is an immediate problem here, because Algol A is a B8-type star, very much brighter than the Sun and, compared with our own star, terribly ultraviolet. Life could not exist on a planet orbiting Algol at one A.U. Let's forget about that little detail and pretend that a planet orbiting Algol at one A.U. would be a fine vacationing spot for future spacefaring humans.

What would these humans see? According to Jim Kaler, Algol consists of a primary B8-type star about 95 times brighter than the Sun in optical light, and a shrunken class K giant 4.5 times brighter than the Sun. That would make the bluish primary about 20 times brighter than the yellowish secondary. Also the stars are very close together, separated by only 0.05 A.U. Would Algol B be bright enough and sufficiently well separated from the primary to cast its own shadow on the ground of a planet orbiting at 1 A.U. from the stellar pair? In other words, would objects on the planet cast two obvious shadows on the ground?

Ann

If you can tell me the radius of each star then I can try to simulate it for you. I think you could probably guess better than I could if it has to be guessed. You could tell me in sun-radii if that is easiest for you. I pretty much just put in a temperature in kelvin and convert it to a blackbody for the color and have to guess at the intensity because Blender isn't exactly a physics sim, even though it kinda is.

Ann wrote:So, Geck, imagine a planet orbiting Algol. There is an immediate problem here, because Algol A is a B8-type star, very much brighter than the Sun and, compared with our own star, terribly ultraviolet. Life could not exist on a planet orbiting Algol at one A.U. Let's forget about that little detail and pretend that a planet orbiting Algol at one A.U. would be a fine vacationing spot for future spacefaring humans.

What would these humans see? According to Jim Kaler, Algol consists of a primary B8-type star about 95 times brighter than the Sun in optical light, and a shrunken class K giant 4.5 times brighter than the Sun. That would make the bluish primary about 20 times brighter than the yellowish secondary. Also the stars are very close together, separated by only 0.05 A.U. Would Algol B be bright enough and sufficiently well separated from the primary to cast its own shadow on the ground of a planet orbiting at 1 A.U. from the stellar pair? In other words, would objects on the planet cast two obvious shadows on the ground?

Ann

Chris Peterson wrote:

geckzilla wrote:The ground in my render is a plain gray plane. It has also taken on the color of the sky.

Not to mention that if the stars were as close/large as shown in the poster, the shadows would be penumbral- just vaguely darker areas at most, not showing real edges.

geckzilla wrote:

madtom1999 wrote:A quick blast on a ray tracer will show Mr Russel to be largely correct.

A quick blast on a ray tracer shows that arguing about one little detail being wrong in this illustration is completely silly. Both shadows take on the color of the sky, whatever that may be. The dwarf's shadow is negligible and barely noticeable. Richard Russell et al. are correct in one sense, but the illustration is so "wrong" that nitpicking this one detail over all the other "wrong" parts would seem to miss the forest for the leaf on one tree.

geckzilla wrote:The ground in my render is a plain gray plane. It has also taken on the color of the sky.

Boomer12k wrote:

geckzilla wrote:

madtom1999 wrote:A quick blast on a ray tracer will show Mr Russel to be largely correct.

A quick blast on a ray tracer shows that arguing about one little detail being wrong in this illustration is completely silly. Both shadows take on the color of the sky, whatever that may be. The dwarf's shadow is negligible and barely noticeable. Richard Russell et al. are correct in one sense, but the illustration is so "wrong" that nitpicking this one detail over all the other "wrong" parts would seem to miss the forest for the leaf on one tree.

Looks more like a darker color of the ground...not sky....at least to me...
But then my eyes might be screwed up....

:---[===] *

geckzilla wrote:

madtom1999 wrote:A quick blast on a ray tracer will show Mr Russel to be largely correct.

A quick blast on a ray tracer shows that arguing about one little detail being wrong in this illustration is completely silly. Both shadows take on the color of the sky, whatever that may be. The dwarf's shadow is negligible and barely noticeable. Richard Russell et al. are correct in one sense, but the illustration is so "wrong" that nitpicking this one detail over all the other "wrong" parts would seem to miss the forest for the leaf on one tree.

geckzilla wrote:

madtom1999 wrote:
A quick blast on a ray tracer will show Mr Russel to be largely correct.

A quick blast on a ray tracer shows that arguing about one little detail being wrong in this illustration is completely silly. Both shadows take on the color of the sky, whatever that may be. The dwarf's shadow is negligible and barely noticeable. Richard Russell et al. are correct in one sense, but the illustration is so "wrong" that nitpicking this one detail over all the other "wrong" parts would seem to miss the forest for the leaf on one tree.

https://en.wikipedia.org/wiki/Extraterrestrial_skies#The_sky_of_Titan wrote:
<<Titan is the only moon in the solar system to have a thick atmosphere. Images from the Huygens probe show that the Titanean sky is a light tangerine color. However, an astronaut standing on the surface of Titan would see a hazy brownish/dark orange color. It seems likely that Saturn is permanently invisible behind orange smog, and even the Sun would only be a lighter patch in the haze, barely illuminating the surface of ice and methane lakes.>>

• . https://www.youtube.com/watch?v=rBHx0UwMHLc

madtom1999 wrote:A quick blast on a ray tracer will show Mr Russel to be largely correct.

RichardSRussell wrote:
It should be possible to replicate these lighting conditions here on Earth in a darkened room with 2 bright lights, 1 with a red filter. I don't have enuf time to do it myself, but perhaps somebody else is curious enuf to give it a go and report back on their findings.

rstevenson wrote:

RichardSRussell wrote:
You DO know that the illustration got the shadows reversed, right? The ground under the shadow pointing away from the red star is illuminated only by the white one, so it shouldn't be reddish.

Alhuru wrote:
The shadow from the white star would be illuminated primarily by red light (ignoring reflections from the surface) so would appear red. The shadow from the red star would be (largely) white, but since the overall lighting is red/pink (which the eye would perceive as white-ish) the shadow from the red star would appear to the eye to have a blue/green hue.

Whenever I look at my shadow here on Earth, it's just, well, dark. In fact, it's likely to look dark green if I'm on a lawn, or maybe dark gray if I'm standing in a parking lot -- despite the blueish cast it will actually have from the blue sky. So the shadows in this ilustration are quite accurately indicated, since the ground where the tourist/astronaut/scientist is standing appears to be reddish dirt.

The real problem with the illustration
is that the background red dwarf
is way too big

rstevenson wrote:

RichardSRussell wrote:You DO know that the illustration got the shadows reversed, right? The ground under the shadow pointing away from the red star is illuminated only by the white one, so it shouldn't be reddish.

Alhuru wrote:The shadow from the white star would be illuminated primarily by red light (ignoring reflections from the surface) so would appear red. The shadow from the red star would be (largely) white, but since the overall lighting is red/pink (which the eye would perceive as white-ish) the shadow from the red star would appear to the eye to have a blue/green hue.

Whenever I look at my shadow here on Earth, it's just, well, dark. In fact, it's likely to look dark green if I'm on a lawn, or maybe dark gray if I'm standing in a parking lot -- despite the blueish cast it will actually have from the blue sky. So the shadows in this ilustration are quite accurately indicated, since the ground where the tourist/astronaut/scientist is standing appears to be reddish dirt.

RichardSRussell wrote:You DO know that the illustration got the shadows reversed, right? The ground under the shadow pointing away from the red star is illuminated only by the white one, so it shouldn't be reddish.

Alhuru wrote:The shadow from the white star would be illuminated primarily by red light (ignoring reflections from the surface) so would appear red. The shadow from the red star would be (largely) white, but since the overall lighting is red/pink (which the eye would perceive as white-ish) the shadow from the red star would appear to the eye to have a blue/green hue.

https://en.wikipedia.org/wiki/Kepler-16 wrote:
Kepler-16 is a binary star system in the constellation of Cygnus[4] that was targeted by the Kepler spacecraft. Both stars are smaller than the Sun; the primary, Kepler-16A, is a K-type main-sequence star and the secondary, Kepler-16B, is an M-type red dwarf. They are separated by 0.22 AU, and complete an orbit around a common center of mass every 41 days.

The system is host to one known extrasolar planet in circumbinary orbit: the Saturn-sized Kepler-16b.