- #1
bothnicum
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How deep in space can current radars reach?
Celestial Reflections: How Far Can Radars Reach in Space?
- Thread starter bothnicum
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In summary: Question 2: Could such a black hole act as a reflector in the sense described above? From what I know, the only way to see a reflection would be if the black hole was very close to the observer. If the black hole was much further away, then the light would just pass straight through it.
- #2
Nereid
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It's as much a question of 'how big is the object we're trying to get a radar image of?' as it is of 'how far away is object?'
AFAIK, Saturn, its rings and moon Titan hold the record:
http://www.aas.org/publications/baas/v34n3/dps2002/109.htm
http://www.news.cornell.edu/Chronicle/03/10.9.03/Titan_hydrocarbon.html
The distance? >1 billion km
In another sense - radar used to first detect an object within, say, 1 million km - I suspect the difficulty is more to do with 'illuminating the sky' than anything else. The methods used to get radar images of Saturn's rings won't really work if your objective is to spot a large meteor closing fast on the Earth.
AFAIK, Saturn, its rings and moon Titan hold the record:
http://www.aas.org/publications/baas/v34n3/dps2002/109.htm
http://www.news.cornell.edu/Chronicle/03/10.9.03/Titan_hydrocarbon.html
The distance? >1 billion km
In another sense - radar used to first detect an object within, say, 1 million km - I suspect the difficulty is more to do with 'illuminating the sky' than anything else. The methods used to get radar images of Saturn's rings won't really work if your objective is to spot a large meteor closing fast on the Earth.
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- #3
bothnicum
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Thanks for excellent links
So it takes 2.25 hours to get a reflection back from Titan
Reflections are interesting. Reflected signal is allways a signal from the history. Radar reflection from Titan tells (among other thigs) that 2.25 hours back in the history some people were experimenting with a radar.
Reflection of sunlight from Pluto tells something about the Sun approximately 10 hours ago.
Could the developments in detecting reflected radiation reach in the future days or even years?
Research of such reflections would provide us a new approach in search of the past?
So it takes 2.25 hours to get a reflection back from Titan
Reflections are interesting. Reflected signal is allways a signal from the history. Radar reflection from Titan tells (among other thigs) that 2.25 hours back in the history some people were experimenting with a radar.
Reflection of sunlight from Pluto tells something about the Sun approximately 10 hours ago.
Could the developments in detecting reflected radiation reach in the future days or even years?
Research of such reflections would provide us a new approach in search of the past?
- #4
Nereid
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No better than taking a picture now and developing the film tomorrow!
- #5
bothnicum
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Picture taking works only when you know that this is the moment and topic you want to watch later. Same is valid for video.
Instead given that basically all celestial objects are reflective, among the incoming radiation there must be (very) weak signals that are reflections from the Sun or even our planet. And the reflections are there also in the case you didn't bring the camera with you.
From a single reflector at the distance of N light years, we will basically get continuous stream originated 2N years ago. Various distances enables us to "see" over various distances in time.
The question is, are there such reflective surfaces big enough.
If one can speak about gravitational lenses, why can't we assume the existence of gravitational reflectors...
- #6
Labguy
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"If one can speak about gravitational lenses, why can't we assume the existence of gravitational reflectors..."
Because, in most basic terms, of the four forces (Strong Nuclear, EM, Weak Nuclear and Gravity), only the first three are known to act as both a repulsive and attractive forces. Gravity is attractive only. So, if "gravity waves", Gravitons, etc. approach a body they are attractive-only and would interact as such and not "reflect" back off that body. They (it, gravity) might change a property of the other body, such as its motion, and we might be able to detect that change by other means. But, the only "gravity" we could detect from the other body would be the influence of its own gravity/mass.
Because, in most basic terms, of the four forces (Strong Nuclear, EM, Weak Nuclear and Gravity), only the first three are known to act as both a repulsive and attractive forces. Gravity is attractive only. So, if "gravity waves", Gravitons, etc. approach a body they are attractive-only and would interact as such and not "reflect" back off that body. They (it, gravity) might change a property of the other body, such as its motion, and we might be able to detect that change by other means. But, the only "gravity" we could detect from the other body would be the influence of its own gravity/mass.
- #7
bothnicum
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Cluster of black holes as a reflector?
Instead of a reflecting surface, could it be possible to find such a cluster of black holes that bends light like a reflecting surface.
Instead of a reflecting surface, could it be possible to find such a cluster of black holes that bends light like a reflecting surface.
- #8
Nereid
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IIRC, there was some discussion recently about black holes acting like very weak reflectors, so that if you looked at the black hole, you would see a (very faint) image of the Sun - light goes out to the black hole, gets bent 180o, and we see the bent light much later.
In practical terms, this isn't very helpful, at least to what bothnicum is looking for. For a start, the black hole 'reflection' ties you down just as much as photos (you can't vary the time delay - that's fixed by the distance to the black hole). Then there's the small matter of actually seeing the 'reflection' - the Sun, as seen from Earth is mag -26; a black hole reflection would likely be about as faint as the faintest galaxies in the recent Hubble Ultra Deep Field (~30 mag), > 20 orders of magnitude!
In practical terms, this isn't very helpful, at least to what bothnicum is looking for. For a start, the black hole 'reflection' ties you down just as much as photos (you can't vary the time delay - that's fixed by the distance to the black hole). Then there's the small matter of actually seeing the 'reflection' - the Sun, as seen from Earth is mag -26; a black hole reflection would likely be about as faint as the faintest galaxies in the recent Hubble Ultra Deep Field (~30 mag), > 20 orders of magnitude!
- #9
bothnicum
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Toroidal black hole as a reflecftor?
Question 1: Are there any evidence of toroidal shape of a black hole?
Question 2: Could such a black hole act as a reflector in the sense described above?
Question 1: Are there any evidence of toroidal shape of a black hole?
Question 2: Could such a black hole act as a reflector in the sense described above?
- #10
Nereid
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Not that I'm aware of.
1. How do radars work in space?
Radars in space work by transmitting radio waves towards a target object, which then reflects the waves back to the radar. The radar then measures the time and strength of the reflected waves to determine the distance and characteristics of the object.
2. What is the maximum distance a radar can reach in space?
The maximum distance a radar can reach in space depends on various factors such as the power of the radar, the sensitivity of the receiver, and the atmospheric conditions. However, with current technology, radars can reach distances of up to 22 billion kilometers.
3. Can radars detect objects in deep space?
Yes, radars can detect objects in deep space. In fact, radars have been used to detect and track objects in our solar system, such as planets, moons, and asteroids. They have also been used to study distant objects in our galaxy and beyond.
4. How accurate are radars in space?
Radars in space can be very accurate, with some being able to measure distances within a few centimeters. However, the accuracy also depends on various factors such as the size and speed of the object being detected, as well as the precision of the radar equipment.
5. What are the limitations of using radars in space?
One of the main limitations of using radars in space is the speed of light, which limits the distance that can be reached and the time it takes for the radar waves to travel and return. Additionally, radars can only detect objects that reflect radio waves, so they may not be able to detect objects that are small or have a low reflectivity. Lastly, atmospheric conditions and interference from other sources can also affect the accuracy and range of radars in space.
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