We could and should be doing both ground and orbital radio telescope observations. One really interesting idea I’ve seen floated is to put one on the far-side of the moon; it’d be shielded from all our radio emissions but, of course, it would be somewhat suspectable to interference from the sun for weeks at a time.
What I’ve never understood about Starlink is how it’s better than existing satellite internet beamed from geosynchronous craft… like, geosync is crowded (especially over North America and Europe), but it’s not so crowded we couldn’t put a couple more transponders up there. Objects in geosync rarely have the astronomical side effects that Starlink is apparently causing. It would even solve the Starlink issue of having to have an expense af receiver with active tracking… just nail up a stationary ku-band dish that doesn’t need to move ever. This is already solved technology.
The problem with geosynchronous orbit is that you need to be at a high altitude to maintain it. That increases the packet round trip time to a receiver on the ground. Starlink satellites orbit low enough to give a theoretical 20ms ping. A geostationary satellite would be at best 500ms. It’s fine for some tasks but lousy for applications that need low latency, like video calling.
In the past 6 months, Starlink satellites made 50,000 collision avoidance maneuvers. They now maneuver 275 times a day to avoid crashing into other space objects.
They use an on board AI to calculate the positions, but each time they course-correct, it throws off forecasting accuracy for several days. So a collision isn’t an if, it’s a when, and suddenly we’re in Kessler Syndrome territory. Or maybe enough people will eventually wake up and realize Musk was an actual idiot all along.
But until then, great, low pings for video calls. Hurray.
This is completely factually inaccurate. 2 minutes on Google will help you learn but seeing as how you’ve been spewing crap all over this thread I don’t think it’s worth my time to even bother helping you understand.
Shortest answer is that even if all Starlink satellites suddently exploded at the same time for no reason, they’d fall back to Earth in a matter of weeks. They’re waaaay lower than the other satellites you’re thinking of (see discussion on geo-stationary satellites for why), so they need to be actively pushed every few days just to stay up. They’re so low they’re still subject to atmospheric drag.
The geosynchronous satellites are about 650 65 times higher than Starlink satellites, so the speed of light is a significant limiting factor.
Geosynchronous orbit is 35,700 km (3.57 x 10^7 m) above sea level. At that distance, signals moving at the speed of light (3.0 x 10^8 m/s) take about .12 seconds to go that far. So a round trip is about .240 seconds or 240 milliseconds added to the ping.
Starlink orbits at an altitude of 550 km (5.5 x 10^5 m), where the signal can travel between ground and satellite in about 0.0018 seconds, for 3.6 millisecond round trip. Actual routing and processing of signals, especially relaying between satellites, adds time to the processing.
But no matter how much better the signal processing can get, the speed of light accounts for about a 200-230 millisecond difference at the difference in altitudes.
Unfortunately it’s a hard limit due to the speed of light. Theoretically you could use quantum entanglement to get around it, but then of course you wouldn’t need the satellites anymore.
Sorry, I meant theoretically as in “at some distant point in the future where we’ve figured out how to make it work.” I probably read too much science fiction.
In real life, all quantum entanglement means is that you can entangle two particles, move them away from each other, and still know that when you measure one, the other will have the opposite value. It’s akin to putting a red ball in one box and a blue ball in another, then muddling them up and posting them to two addresses. When opening one box, you instantly know that because you saw a red ball, the other recipient has a blue one or vice versa, but that’s it. The extra quantum bit is just that the particles still do quantum things as if they’re a maybe-red-maybe-blue superposition until they’re measured. That’s like having a sniffer dog at the post office that flags half of all things with red paint and a quarter of all things with blue paint as needing to be diverted to the police magically redirect three eighths of each colour instead of different amounts of the two colours. The balls didn’t decide which was red and which was blue until the boxes were opened, but the choice always matches.
Science fiction quantum entanglement is not the same as real life quantum entanglement. Science fiction has spooky action at a distance, real life doesn’t.
The speed of light is the speed of causality, the speed of information. It is physically impossible to send information at speeds greater than the speed of light.
Just to add, radio telescopes easily have diameters of several 10 to several 100 meters, you won’t put that easily in space. And even if you do, maybe one, not tens of them. And these are often used in network as well for interferometry to have higher spatial resolution, so that would be gone as well.
A couple of satellites can make a larger telescope than we could ever build on earth, and you avoid the natural interference as well as the the interference from other satellites (star link isn’t the only source of interference…).
Not easily, perhaps. But it’s certainly possibly. We already have space technology for unfolding small packages into large sheets. Not to mention, you don’t need a single 100m collection surface when you can accomplish similar things with many smaller surfaces spaced apart. See the Very Large Array.
Is it weird I agree these are terrible and yet also hope this spurs the end of ground based observation in favor of a larger orbital presence?
exactly what i was thinking.
We could and should be doing both ground and orbital radio telescope observations. One really interesting idea I’ve seen floated is to put one on the far-side of the moon; it’d be shielded from all our radio emissions but, of course, it would be somewhat suspectable to interference from the sun for weeks at a time.
What I’ve never understood about Starlink is how it’s better than existing satellite internet beamed from geosynchronous craft… like, geosync is crowded (especially over North America and Europe), but it’s not so crowded we couldn’t put a couple more transponders up there. Objects in geosync rarely have the astronomical side effects that Starlink is apparently causing. It would even solve the Starlink issue of having to have an expense af receiver with active tracking… just nail up a stationary ku-band dish that doesn’t need to move ever. This is already solved technology.
The problem with geosynchronous orbit is that you need to be at a high altitude to maintain it. That increases the packet round trip time to a receiver on the ground. Starlink satellites orbit low enough to give a theoretical 20ms ping. A geostationary satellite would be at best 500ms. It’s fine for some tasks but lousy for applications that need low latency, like video calling.
In the past 6 months, Starlink satellites made 50,000 collision avoidance maneuvers. They now maneuver 275 times a day to avoid crashing into other space objects.
They use an on board AI to calculate the positions, but each time they course-correct, it throws off forecasting accuracy for several days. So a collision isn’t an if, it’s a when, and suddenly we’re in Kessler Syndrome territory. Or maybe enough people will eventually wake up and realize Musk was an actual idiot all along.
But until then, great, low pings for video calls. Hurray.
This is completely factually inaccurate. 2 minutes on Google will help you learn but seeing as how you’ve been spewing crap all over this thread I don’t think it’s worth my time to even bother helping you understand.
Can you debunk it for the rest of us?
Shortest answer is that even if all Starlink satellites suddently exploded at the same time for no reason, they’d fall back to Earth in a matter of weeks. They’re waaaay lower than the other satellites you’re thinking of (see discussion on geo-stationary satellites for why), so they need to be actively pushed every few days just to stay up. They’re so low they’re still subject to atmospheric drag.
Search the web for “star link Kessler syndrome”. It’s well documented. It’s also discussed elsewhere in this thread.
Cite sources please?
Search the web for “starlink Kessler syndrome”. It’s very well documented. It’s also discussed elsewhere in this thread.
Is there any way to improve that? Or is it a hard limit due to physics?
The geosynchronous satellites are about
65065 times higher than Starlink satellites, so the speed of light is a significant limiting factor.Geosynchronous orbit is 35,700 km (3.57 x 10^7 m) above sea level. At that distance, signals moving at the speed of light (3.0 x 10^8 m/s) take about .12 seconds to go that far. So a round trip is about .240 seconds or 240 milliseconds added to the ping.
Starlink orbits at an altitude of 550 km (5.5 x 10^5 m), where the signal can travel between ground and satellite in about 0.0018 seconds, for 3.6 millisecond round trip. Actual routing and processing of signals, especially relaying between satellites, adds time to the processing.
But no matter how much better the signal processing can get, the speed of light accounts for about a 200-230 millisecond difference at the difference in altitudes.
Unfortunately it’s a hard limit due to the speed of light. Theoretically you could use quantum entanglement to get around it, but then of course you wouldn’t need the satellites anymore.
no, you couldn’t. You can’t use quantum entanglement to send information. Only random noise.
Sorry, I meant theoretically as in “at some distant point in the future where we’ve figured out how to make it work.” I probably read too much science fiction.
In real life, all quantum entanglement means is that you can entangle two particles, move them away from each other, and still know that when you measure one, the other will have the opposite value. It’s akin to putting a red ball in one box and a blue ball in another, then muddling them up and posting them to two addresses. When opening one box, you instantly know that because you saw a red ball, the other recipient has a blue one or vice versa, but that’s it. The extra quantum bit is just that the particles still do quantum things as if they’re a maybe-red-maybe-blue superposition until they’re measured. That’s like having a sniffer dog at the post office that flags half of all things with red paint and a quarter of all things with blue paint as needing to be diverted to the police magically redirect three eighths of each colour instead of different amounts of the two colours. The balls didn’t decide which was red and which was blue until the boxes were opened, but the choice always matches.
Science fiction quantum entanglement is not the same as real life quantum entanglement. Science fiction has spooky action at a distance, real life doesn’t.
The speed of light is the speed of causality, the speed of information. It is physically impossible to send information at speeds greater than the speed of light.
it physically cannot work. ever. That’s just how entanglement works. We know that much.
That’s not true either unfortunately
The scale at which we build radio telescopes on the ground simply isn’t possible in space.
Just to add, radio telescopes easily have diameters of several 10 to several 100 meters, you won’t put that easily in space. And even if you do, maybe one, not tens of them. And these are often used in network as well for interferometry to have higher spatial resolution, so that would be gone as well.
Why can’t we use the satellites for interferometry, too?
A couple of satellites can make a larger telescope than we could ever build on earth, and you avoid the natural interference as well as the the interference from other satellites (star link isn’t the only source of interference…).
Not easily, perhaps. But it’s certainly possibly. We already have space technology for unfolding small packages into large sheets. Not to mention, you don’t need a single 100m collection surface when you can accomplish similar things with many smaller surfaces spaced apart. See the Very Large Array.
Not with that attitude.
Or altitude.
No it’s utterly pragmatic.
The future of space exploration is in space.