Editing Talk:2761: 1-to-1 Scale
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:Yup, I think it's what he meant - but I find it unlikely that the gas giants would have this clear cutoff of a "surface". [[Special:Contributions/162.158.189.241|162.158.189.241]] 03:34, 11 April 2023 (UTC) | :Yup, I think it's what he meant - but I find it unlikely that the gas giants would have this clear cutoff of a "surface". [[Special:Contributions/162.158.189.241|162.158.189.241]] 03:34, 11 April 2023 (UTC) | ||
::If there is a gas - liquid phase transition (and I think at least the gas giants have them): Why not? OK, you could see "rain" as blurring a clear cutoff, but wouldn't that also apply to Earth, then?[[User:Tier666|Tier666]] ([[User talk:Tier666|talk]]) 08:04, 11 April 2023 (UTC) | ::If there is a gas - liquid phase transition (and I think at least the gas giants have them): Why not? OK, you could see "rain" as blurring a clear cutoff, but wouldn't that also apply to Earth, then?[[User:Tier666|Tier666]] ([[User talk:Tier666|talk]]) 08:04, 11 April 2023 (UTC) | ||
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I’d think the same citation as stands for ridiculously large would also cover larger than currently exists on earth, and his that citation is not in fact needed? [[Special:Contributions/162.158.174.186|162.158.174.186]] 06:53, 11 April 2023 (UTC) | I’d think the same citation as stands for ridiculously large would also cover larger than currently exists on earth, and his that citation is not in fact needed? [[Special:Contributions/162.158.174.186|162.158.174.186]] 06:53, 11 April 2023 (UTC) | ||
:It seems like the gas-covered worlds are explicitly those with clearly cutoff "surfaces," so maybe in those cases the cutoff is some specific gas density -- which occurs at a consistent radius throughout the planet, thus creating a flat surface. While for rocky worlds (except Venus, which is treated like a gas planet here), a density cutoff can lead to bumpiness due to terrain. [[User:Trimeta|Trimeta]] ([[User talk:Trimeta|talk]]) 03:57, 11 April 2023 (UTC) | :It seems like the gas-covered worlds are explicitly those with clearly cutoff "surfaces," so maybe in those cases the cutoff is some specific gas density -- which occurs at a consistent radius throughout the planet, thus creating a flat surface. While for rocky worlds (except Venus, which is treated like a gas planet here), a density cutoff can lead to bumpiness due to terrain. [[User:Trimeta|Trimeta]] ([[User talk:Trimeta|talk]]) 03:57, 11 April 2023 (UTC) | ||
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:Venus isn't treated as a gas planet. If you look at the surface you can see some cracks and divots. [[User:Psychoticpotato|Psychoticpotato]] ([[User talk:Psychoticpotato|talk]]) 13:39, 6 May 2024 (UTC) | :Venus isn't treated as a gas planet. If you look at the surface you can see some cracks and divots. [[User:Psychoticpotato|Psychoticpotato]] ([[User talk:Psychoticpotato|talk]]) 13:39, 6 May 2024 (UTC) | ||
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On Twitter there seems to be concern that all planets are depicted flat. This may make this a contribution/mockery of the ongoing [https://en.wikipedia.org/wiki/Flat_Earth Flat Earth] discussions in some corners of the internet. --[[Special:Contributions/198.41.242.132|198.41.242.132]] 06:49, 11 April 2023 (UTC) | On Twitter there seems to be concern that all planets are depicted flat. This may make this a contribution/mockery of the ongoing [https://en.wikipedia.org/wiki/Flat_Earth Flat Earth] discussions in some corners of the internet. --[[Special:Contributions/198.41.242.132|198.41.242.132]] 06:49, 11 April 2023 (UTC) | ||
:You can't see the curvature of the Earth when standing on it; doesn't mean it's flat. Since we're looking at the planets at a 1:1 scale, we're literally only seeing a couple of <em>inches</em> of each of their edges (notwithstanding the whole gas-giants-don't-have-a-sharp-edge issue). [[Special:Contributions/162.158.239.20|162.158.239.20]] 12:06, 11 April 2023 (UTC) | :You can't see the curvature of the Earth when standing on it; doesn't mean it's flat. Since we're looking at the planets at a 1:1 scale, we're literally only seeing a couple of <em>inches</em> of each of their edges (notwithstanding the whole gas-giants-don't-have-a-sharp-edge issue). [[Special:Contributions/162.158.239.20|162.158.239.20]] 12:06, 11 April 2023 (UTC) | ||
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The display for an uncropped version of the image would not only be larger than any display on earth. It would be larger than earth. [[Special:Contributions/162.158.86.243|162.158.86.243]] 06:59, 11 April 2023 (UTC) | The display for an uncropped version of the image would not only be larger than any display on earth. It would be larger than earth. [[Special:Contributions/162.158.86.243|162.158.86.243]] 06:59, 11 April 2023 (UTC) | ||
:By necessity, at least as large as Jupiter. Maybe slightly above two Jupiters (max dimension squared compared to display height*width of any common aspect ratio) if you wanted to not overlay any of the others at all. And make the lower limit a packing-problem, then add a buffer so there isn't the actual need for any to touch. [[Special:Contributions/172.70.90.253|172.70.90.253]] 10:02, 11 April 2023 (UTC) | :By necessity, at least as large as Jupiter. Maybe slightly above two Jupiters (max dimension squared compared to display height*width of any common aspect ratio) if you wanted to not overlay any of the others at all. And make the lower limit a packing-problem, then add a buffer so there isn't the actual need for any to touch. [[Special:Contributions/172.70.90.253|172.70.90.253]] 10:02, 11 April 2023 (UTC) | ||
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1-to-1 scale means 'assume all planets are the same size,' right? I see Earth's grass is shown to be as large as Martian rocks, because Earth is a third again as large. (At the scale where grass is visible, Earth looks flat.) At first I thought the point was that altitude variation in cloud-tops varied so little that a gas giant shrunk down to Earth size would be featureless and have a distinct edge, but that's wrong. Ground isn't cloud-tops. Do gas giants have any solid ground? We've seen Jupiter eat comets, and it makes sense they would've collected at least some minerals and metals. According to [[https://www.teachastronomy.com/textbook/The-Giant-Planets-and-Their-Moons/Internal-Structure-of-the-Gas-Giant-Planets/|Teach Astronomy]], gas giants have Earth-sized solid cores. I'm guessing gas giants' immense gravity compresses their cores into featureless spheres, which, if scaled to Earth-size and viewed at the scale where one could see grass, would look flat. Yes? | 1-to-1 scale means 'assume all planets are the same size,' right? I see Earth's grass is shown to be as large as Martian rocks, because Earth is a third again as large. (At the scale where grass is visible, Earth looks flat.) At first I thought the point was that altitude variation in cloud-tops varied so little that a gas giant shrunk down to Earth size would be featureless and have a distinct edge, but that's wrong. Ground isn't cloud-tops. Do gas giants have any solid ground? We've seen Jupiter eat comets, and it makes sense they would've collected at least some minerals and metals. According to [[https://www.teachastronomy.com/textbook/The-Giant-Planets-and-Their-Moons/Internal-Structure-of-the-Gas-Giant-Planets/|Teach Astronomy]], gas giants have Earth-sized solid cores. I'm guessing gas giants' immense gravity compresses their cores into featureless spheres, which, if scaled to Earth-size and viewed at the scale where one could see grass, would look flat. Yes? | ||
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:Gravity itself won't compress (and 'flatten') the cores. "Shell theory" shows that gravitational force only counts from the proportion of the body that is within the radius of the bit you're concerned with. But there'll also be the external pressure (from being at the bottom of a thick atmosphere that ultimately ''is'' above far more of the planetary mass) and possibly a degree of compression density to make any Earth-sized core slightly heavier than if it was just a bare core of the same size but shorn of outer layers. | :Gravity itself won't compress (and 'flatten') the cores. "Shell theory" shows that gravitational force only counts from the proportion of the body that is within the radius of the bit you're concerned with. But there'll also be the external pressure (from being at the bottom of a thick atmosphere that ultimately ''is'' above far more of the planetary mass) and possibly a degree of compression density to make any Earth-sized core slightly heavier than if it was just a bare core of the same size but shorn of outer layers. | ||
:As to flatness, I can take you to very flat stretches of Earth and very lumpy bits (depends which direction I go, from where I am now), all within 30 minutes' drive. We can'teven know how representative a sample of planetary cross-sections we are seeing (once we get over the issues of gas/space boundaries for gas-giants), but I bet there are bits that resemble the diagram... If you ''really'' want it to be so real. [[Special:Contributions/172.71.242.87|172.71.242.87]] 11:05, 11 April 2023 (UTC) | :As to flatness, I can take you to very flat stretches of Earth and very lumpy bits (depends which direction I go, from where I am now), all within 30 minutes' drive. We can'teven know how representative a sample of planetary cross-sections we are seeing (once we get over the issues of gas/space boundaries for gas-giants), but I bet there are bits that resemble the diagram... If you ''really'' want it to be so real. [[Special:Contributions/172.71.242.87|172.71.242.87]] 11:05, 11 April 2023 (UTC) | ||
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There are several pieces of information here that are featured but don't make sense to me. What's the function of the dark polygon in the center? Why are the lines showing each surface going in random directions? Why is the surface of each planet so flat at a full scale rendition? When I look out my window at full sized Earth, it's not flat. It's quite bumpy, actually. But perhaps he doesn't mean these are full size, he might be saying that they're all shrunk, but the same amount, so 1:1:1:1:1... but even then, I'm totally lost. | There are several pieces of information here that are featured but don't make sense to me. What's the function of the dark polygon in the center? Why are the lines showing each surface going in random directions? Why is the surface of each planet so flat at a full scale rendition? When I look out my window at full sized Earth, it's not flat. It's quite bumpy, actually. But perhaps he doesn't mean these are full size, he might be saying that they're all shrunk, but the same amount, so 1:1:1:1:1... but even then, I'm totally lost. | ||
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"What's the function of the dark polygon in the center?" | "What's the function of the dark polygon in the center?" | ||
I think it is a view of the dark sky, "above" the surface of the Earth, Mars, etc. [[User:Rps|Rps]] ([[User talk:Rps|talk]]) 11:43, 11 April 2023 (UTC) | I think it is a view of the dark sky, "above" the surface of the Earth, Mars, etc. [[User:Rps|Rps]] ([[User talk:Rps|talk]]) 11:43, 11 April 2023 (UTC) | ||
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Is this an ant on earth, over the letters "EA" ? On my monitor, set for my less-than-perfect vision, it is 15mm long, which (at a 1:1 scale) makes it a cow ant, or a large african ant. I guess people with normal vision get fire and carpenter ants instead? And those on smartphones get pavement ants?[[Special:Contributions/172.68.50.73|172.68.50.73]] 11:00, 11 April 2023 (UTC) | Is this an ant on earth, over the letters "EA" ? On my monitor, set for my less-than-perfect vision, it is 15mm long, which (at a 1:1 scale) makes it a cow ant, or a large african ant. I guess people with normal vision get fire and carpenter ants instead? And those on smartphones get pavement ants?[[Special:Contributions/172.68.50.73|172.68.50.73]] 11:00, 11 April 2023 (UTC) | ||
:I do believe it is! It's 6 mm on my desktop monitor and 3 mm on my phone. We also don't know what side of the Earth we're looking at, so I suppose it could really be any ant, including the one in your local area. I like to think it's a black garden ant (''Lasius niger''), since I'm most familiar with those :) [[Special:Contributions/162.158.239.25|162.158.239.25]] 12:16, 11 April 2023 (UTC) | :I do believe it is! It's 6 mm on my desktop monitor and 3 mm on my phone. We also don't know what side of the Earth we're looking at, so I suppose it could really be any ant, including the one in your local area. I like to think it's a black garden ant (''Lasius niger''), since I'm most familiar with those :) [[Special:Contributions/162.158.239.25|162.158.239.25]] 12:16, 11 April 2023 (UTC) | ||
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It took me a good while to figure out this one; I don't normally need to come here, but this one stumped me at first. (The comments as of right now weren't too illuminating either.) I think the lack of color was an issue; I first thought the black polygon in the center was the earth, and then interpreted the various lines as a <em>really</em> weird diagram type I'd never seen before, like a phase diagram or something; I also considered one-dimensional planets. [https://imgur.com/a/yJOYvk1 I colored in the planets to aid me.] The way I now interpret this one is thus: imagine an observer sitting a tremendous distance away from the solar system, and they have a camera with an extremely supremely highly zooming telephoto lens. Then a lining-up of all eight planets happens – I believe this is impossible IRL (because of resonances or something), but just go with it. The observer manages to snap this incredible image of a teeny tiny spot of the sky, which simultaneously manages to include the very very edges of all the planets as well as some of the sky behind them all. The sky is the black polygon: it has nebulae and stars. Neptune is in front of Uranus, and that as well as Mercury are in front of Saturn, which is in front of both Jupiter and Mars; Venus is between Mercury, Mars and the Earth, and the Earth is also behind Jupiter. The reason why these are all so smooth is <em>because</em> it's such a small area: we're literally only seeing a couple of square inches of the surface of each of the rocky planets. (See, you can see an individual ant on the Earth. Go to the most rugged mountain range you can find and observe a couple of square inches; it'll be locally flat.) The lack of atmospheres on the rocky planets as well as the hard edges of the gas giants are artistic license. This one is a member of the genre of "true yet unhelpful diagrams"; I'm surprised that isn't a category on this wiki. – [[Special:Contributions/162.158.238.4|162.158.238.4]] 12:58, 11 April 2023 (UTC) | It took me a good while to figure out this one; I don't normally need to come here, but this one stumped me at first. (The comments as of right now weren't too illuminating either.) I think the lack of color was an issue; I first thought the black polygon in the center was the earth, and then interpreted the various lines as a <em>really</em> weird diagram type I'd never seen before, like a phase diagram or something; I also considered one-dimensional planets. [https://imgur.com/a/yJOYvk1 I colored in the planets to aid me.] The way I now interpret this one is thus: imagine an observer sitting a tremendous distance away from the solar system, and they have a camera with an extremely supremely highly zooming telephoto lens. Then a lining-up of all eight planets happens – I believe this is impossible IRL (because of resonances or something), but just go with it. The observer manages to snap this incredible image of a teeny tiny spot of the sky, which simultaneously manages to include the very very edges of all the planets as well as some of the sky behind them all. The sky is the black polygon: it has nebulae and stars. Neptune is in front of Uranus, and that as well as Mercury are in front of Saturn, which is in front of both Jupiter and Mars; Venus is between Mercury, Mars and the Earth, and the Earth is also behind Jupiter. The reason why these are all so smooth is <em>because</em> it's such a small area: we're literally only seeing a couple of square inches of the surface of each of the rocky planets. (See, you can see an individual ant on the Earth. Go to the most rugged mountain range you can find and observe a couple of square inches; it'll be locally flat.) The lack of atmospheres on the rocky planets as well as the hard edges of the gas giants are artistic license. This one is a member of the genre of "true yet unhelpful diagrams"; I'm surprised that isn't a category on this wiki. – [[Special:Contributions/162.158.238.4|162.158.238.4]] 12:58, 11 April 2023 (UTC) | ||
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