I love the idea, and this part from NASA's website really sold it for me: "Failure tolerance: Because of the scale of these constellations, a single spacecraft is no longer mission critical. Not only are failures tolerated, they are expected and built into calculations. This fail fast, fail cheap approach is a drastic departure from traditional practices." Thanks Mary for coming on!!!
Unfortunately, public tolerance (or giving politicians the opportunity to grandstand) re: mission failures is what killed off NASA's Faster, Better, Cheaper programs in the late 90's and early 2000's. I had the honor of working on a couple of those. People don't remember the successes (or how comparatively cheap they were to fly) and only focus on failures. It seems to ebb and flow. We went from the Mars Observer failure to BFC missions managed by contractors, and back again to large and sensitive missions managed by JPL. Few people remember, we got the Mars Pathfinder / Sojourner Rover mission for the same price as it took Kevin Costner to produce the film Water World. BFC lets scientists and engineers be bold (but they have to balance that with the public's hunger for success).
Fraser, you're such a good interviewer! I've been following your channel for several years now, and you never cease to impress with your ability to ask relevant and interesting follow up questions. Thanks for the the consistently high quality content!
When this is a 3D array in space, it can measure anything within it's capabilities in any direction. Almost in all directions at the same time - but you mentioned it: The bottlenecks are the computational power at the array or nearby - and the transmission rate, the bandwidth to bring that data back to Earth. When they bring back the raw data of each and every antenna in that array, they can do calculations at home on Earth for any object in any direction. But it requires an enormous bandwidth between Earth and this satellite array at L4 or L5 (or both) that is not available. Or let computers in that array in space do the calculations, but the computers there might be small and might be a compromise to bring the computers up to L4 or L5 and they can't be upgraded like on Earth. So the computers in that array (or near that array) would be programmed to calculate the combination of the signals only for specific directions one at a time. And then they send only the result for this one direction (or just a few directions at once) back to Earth. Every other measurements are lost. They cannot be transmitted as raw data to Earth. They need to find a doable compromise, wow, a difficult work to do...
A solution in mind, perhaps we can utilize Free-space optical communication (along with orbital angular momentum and other kinds of multiplexing) since in space there is no fog, cloud, or anything that renders optical wireless communication to short distances which is in the case for terrestrial OWC.
Sounds like LOFAR, the Low Frequency Array, the new European radio telescope constructed by ASTRON in the Netherlands, operating in the largely unexplored frequency range between 10 and 240 MHz.
Fraser, Great interview on interesting topic. It reminds me of a book I read back in 1960: "Venus Equilateral". IIRC the author was George O,. Smith ( an electrical engineer who worked on radar during WWII). The premise of the book was that knowledge and technology had not progressed from the 1940's but we had found propulsion technology on Mars that allowed us to colonize the inner solar system. It is a bit juvenile, but a great read nonetheless. Also, back in the 1980's, I was giving a lecture at the University of New Mexico and was invited to tour the Very Large Array. Another convolution of modern technology and the Old West. After the VLA was built, they had to tear up all the roads used in its construction for fear of cattle rustlers. Don Ziesig
14:05 - 14:22 As a comsat guy, I'm leery of the difficulty of getting large amounts of data back from large numbers of randomly oriented, "tumbling" satellites, but other than that this sounds like a great idea. =) Given the sheer number of smaller payloads this system would use, it sounds like a payload appropriate to just a launch or three of SpaceX's Starship.
Super exciting! Proxima Centauri is within 30 light years. I love that picture: blip... blip... blip... as it hits each planet. And there you go, you gave them a new idea (both LP's).
A satellite at EM4 and / or EM5 with 12, 20 or 30 30cm telescopes mounted on a geodesic frame could be designed to watch the entire sky simultaneously and instantaneously. (Clearly, the more telescopes, the smaller the angle onserved by any one telescope and the higher the total resolution.) Such a system could be designed to fit within a falcon 9 or heavy fairing, or indeed any laucher fairing, depending, so that it could be launched in one shot. Laser telemetry would have the needed bandwidth to send down the data continuously. One could start small with 12 20cm scopes in a dodecahedra pattern and work your way up to 30 1m scopes. Raw data would be placed into an online repository for researchers to reference. Data would need to also include accurate positional data of the spacecraft for astrometry purposes.
I like the idea of using it for high-resolution monitoring of the Sol system that came up from his question about using multiple Lagrange points around the sun
The architecture tradeoff might be all of the above which is doable with cubesats and a few larger node SATs which could be data collection/retransmission nodes
Fraser i have said it before and will continue to feed your ego, best interviewer in the solar system, wouldnt it be cool if you added lagrange to your name as a tribute and possibly lessen the amounts of times you get it explained to you =D
A great idea, investigating this interstella Plasma and the Plasma filliments are essential for deepspace missions alone let alone drawing in the electrical differential from the Sun to charge spaceships, in theory the electrical charge has more potential than solar radiation
I had this idea years ago so as to search for power grids of advanced civilizations. No one wanted to build the low-frequency telescope. Not only will they be able to detect magnetospheres but power grids also, if they exist.
When LIDO first gave us detection of Gravitational Waves, the first thing I ask myself was "What frequency are those waves"? Are they at the same frequency range as earthquakes?
Just an editing note.. for us earbud wearers.. I found the subtle background music to be too distracting. Otherwise, nothing but love for this channel ❤
I feel like I'm misunderstanding something. How does a collection of observers observe a single photon? Doesn't something have to absorb the photon in order to measure it? Does radio receiving not actually function by absorption, but "just" measuring how local electrons are "influenced" by a "passing" photon?
Maybe they can adapt something of the ELF (3-300 Hertz) submarine communications systems? Everybody has one now. They have to transmit through the ground, then through the sea water, but the submarines can get the signal through some kind of huge antenna. One of my favorite writers had the bad guys using this in a book "Wild Fire" a few decades ago.
FC could have been tongue in cheek right there and said "no need to explain L points to my audience" lol Also I really didn't know Jupiter's mag sphere was bigger than than most stars at certain times but it checks out at some wavelengths! Awesome
Any chance we could work with whatever company to make the cube-sats with multipurpose use and get many benefits and share cost/responsibility to perhaps reduce the amount of overall "junk" that goes up and interferes with, well, anything else we send up there? I know, probably wishful thinking and all, but I always love things that perform multiple tasks even if it might be slightly less effective in one specific area. Maybe for future communications as we expand out into the solar system and all. I'm sure someone smart can figure out a solution so it's more of a win-win-win and all that amazing stuff! Let's go BIG!!! (Like, mind-numbing large for any space telescope and just keep the data flowing, even if there is no way to review it all in the next 100 years) 🌌🌠📡🔭🖥️🚀🛸
@@frasercain It is nice of you. You have done the job at your hand with available informations very skillfully . You make me to dream on the subject. Thank you.
Will this tech be able to track spaceships? Satellites? Space junk? Asteroids? What about airplanes? Surface ships? Submarines? Image Earth underground? Would it detect the effects of a gravity drive? Given an unlimited budget, how long until you can launch your first telescopes? Would you consider making the raw data open source? Sending the raw data back to Earth will allow any researcher to focus the telescope anywhere. All researchers have equal, simultaneous access, just by querying the data archive any year the researcher thinks to run the experiment. Might the telescope array be used for terrestrial air traffic control? Is a 20-second latency “close enough” for some purposes in real-time? Would this array work, even if ground-based?
there must me be loads of other radio sources in the sky on these same frequencies. For starters Jupiter and Saturn will emit very strong on these frequencies. Another thing is that there will be other sources, like black holes, magnetars, quasars etc. Essentially this radio interferometer will be totally swamped. That means, that while idea is very good, they'll not be to differentiate signals.
Picking up very long wavelengths, in Space, does not seem, in itself, a very hard problem. How do you pick up AM radio, with waves up to about 600 meters, on a pocket radio? You wind a helical antenna, with a very long effective length, that fits inside a case less than 10 cm wide. The difference I can see in this situation is how to get directionality. That tends to be done with dishes, but those are not practical at such extreme wavelengths, at least not with conventional techniques.
@elonmusk Please read my comment on this video. You can help groups be "early settlers". Venus has a lot of potential if only because it is stable and complex. A few million human equivalent years of thought and it might be easier than we think.
I wish all those internet and communication satellites put into orbit by SpaceX and other companies had an extra feature onboard that faced away from Earth to search and monitor for any ELE asteroid threats heading towards us as an early warning system. I guess it would cost too much for these companies to operate such an important system, or perhaps they don't care about such threats to human civilisation. But having all those thousands of satellites monitoring the solar system 24/7/365 for rogue asteroids would be extremely useful.
She describes this at tidy because dead craft will be trapped at the Lagrange points. But don't we need to be concerned about a space junk problem at the Lagrange points themselves?
I'm still concerned. A hundred thousand satellites every ten years for thousands of years, plus hundreds of O'Neil cylinders means someone will get hurt. I'd need to see the math to be reassured. Great interview! :-)
@@williammiller5578 I wondered about this too, but it occured to me that we can't really compare it to, for example, the orbital space junk problem. With the Lagrange points, we're basically talking about a whole lot of objects traveling on a highway in the same direction at the same speed. The orbital space junk is more like a bunch of rowdy kids in bumper cars.
@@frasercain the L4/L5 regions of the moon earth system aren't millions of km across, more likely 20 000 km and more like a pancake (comparable with the 300 km thick airspace above all the Pacific's) , but a object cannot stay in those areas if it have a higher velocity relative with the center of those areas, so if are a lot of decommissioned satellites probably you could pick them with a robotic arms in a single mission and clean the space cheap and easy not like on the LEO when you need to adjust your cleaning spacecraft orbital speed and inclination for each piece of garbage by a lot.
Around 12 minutes, this lady is explaining LaGrange points to people who regularly watch Science and Space news, maybe take the training wheels off this interview.
Wonderful interview with very interesting questions and clear answers with a very articulate and clearly knowledgeable Dr Mary Knapp. Looking forward to a follow-up with her and what her team is doing. It would be cool if there was a way to utilize some time and array testing using Starlink Satellites, as they're already over 3,000 in orbit, and the communications part of the equation would be essentially done. Elon might get on board. 🤷♀
Really, really interesting project indeed! 😃 Thanks for the interview, Fraser!!! My only question is about a radio telescope in the far side of the Moon... Couldn't it be built in the same way? (Not using solar power for the operation, of course, but either way...) Anyway, stay safe there with your family! 🖖😊
Loved this interview! The dispersed architecture seems smart for longevity of the array because you can trickle in more elements to replace old ones, and update the instrumentation and data processing to take advantage of new tech, or new missions. It makes so much sense. But I'm also excited to see the local neighborhood in a new wavelength. I expect it to be a bit mind blowing.
Other planets in our solar system have La Grange points as well. Can't we use really efficient but slower orbital insertion methods to send a few big boxes of these cubesats into Martian or even Jovian L4/L5 configurations? This goes back to Grace Hopper's comment-I know what we can do with one big tractor. What can we do with a few thousand small tractors?
Jupiter's magnetic field is too powerful and for this the interference would be a problem even outside the field, have to use Mars if it has a decent Lagrange point. Or maybe Venus, but both Mars and Venus have no magnetic fields and may be better than Earth if Venus isn't too close to the Sun.
I'm glad Fraser Cain proposed to use both L4 and L5. That would of course be my first thought : I wanna hear those alien radio-talk shows, when they are stuck in the transit around Tau Ceti.
Yes, everyone on the channel was shouting "L4+L5" at the screen. Fraser knows his audience so well :) TBF he was brilliant on this episode. Good guest also, very honest lady with no ego-says "I don't know" when they are not sure, instead of selling us BS like previous guests.
37:35 Given, that SpaceX already has smallsat factory going, maybe it would make sense to just order from them to do a version with astro modification? Are their argon-ion engines enough for station keeping at Lagrange points?
How amazing is Mary Knapp? She is super cute to me😊 watching her animations when she is excited about the subject she is discussing captivate me. Super cool Ms Knapp keep up the good work! And thank you for the type of work you do it's so important to me and all of us i believe. Crushing hard on Mary Knapp❤😊
What an awesome interview, Fraser! It is so great watching another brilliant female scientist with an insight that could change our view of the Universe. Best of luck and insights to you and your team! I will be longing for hearing of and reading about the amazing things you are certain to find.
We should launch a few hundred space radiotelescopes into Sun orbits in like a GPS satellite pattern but around the Sun, at say 1.25 AU, and then we'd have a 100 million km telescope. That should give us enough resolution to read the headlines of exo-newspapers, assuming they use magnetic ink. No, seriously.
The interstellar plasma resulting in diminishing returns is a disappointment. For a while, I've been wondering about the difference between a megameter telescope and a gigameter telescope.
What do you imagine that an observer, in say Andromeda, would conclude from looking at Earth and the amount of technological equipment surrounding the planet?
why would it be "artificial?" if you had a large molten iron core rotating in the center of your spacecraft would that make a natural/organic magnetosphere?
@@JuandeFucaU it probably would cost more power to keep something like that molten and spinning.. rather than using electromagnets, like mri machines.. but bigger. Meby even a hoop on the outside of a spinning habitat.. it could even be used for counterspin possibly..
@@tra-viskaiser8737 well, if we're going to be sensible about this, why bother with a magnetosphere on a spacecraft at all when plenty of things can shield us from radiation better than an electrical field. like water, for instance.
Or maybe an artificial magnetic field for a lunar or martian settlement so the habitat can have windows. Perhaps an artificial magnetic field for a giant space station.
This is perhaps THE MOST exciting projects I've heard of. You absolutely NEVER hear anyone discussing the interstellar Plasma that we know exists, but can't see. The fabric of the Cosmic Web. Within seconds of thinking of my next question, Frasier was asking that exact question like some kind of mind link. With the assumption that many, if not most habitable planets may exist within the halo of Brown Dwarf stars, and are therefore functionality invisible to us, I wonder if this is the technology that could solve this problem. Regardless, I am excited at the prospect of mapping the Cosmic Web and the electromagnetic pathways that link planets, galactic structures, and even galaxies and galactic clusters themselves. We just might learn, as some in the field have been saying for years, that NO object is independent from its environment, and that the reality is much more profound. Such research may reveal that ALL of the visible universe is interconnected, and the electrodynamics of interstellar plasma play a much larger role in the formation and evolution of our universe than the very weak force of gravity. We actually could be a cog in the electromagnetic engine of the entire universe. That would explain a lot and solve what we've been getting wrong about our current models and lead to a tremendous advancement in our knowledge and understanding.
Low frequency tech signature of OUR civilization: 60 Hz alternating current in Western Hemisphere, 50 Hz in Eastern Hemisphere radiating from the continental power grids into space. If ET is using alternating current, which, depending on a time window of how long AC long range transmission tech remains relevant (for us, more than a century and counting and no sign of obsolescence), then that is something to look for. Of course, for ETs, it won't be exactly those freqs, but the range of efficient frequencies would be constrained by engineering considerations. Once magnetospheric or technological planets are LOCATED, they might be a target for more advanced imaging instruments. A problem of the highest resolution instruments is they have a narrow field, and are problematic for FINDING targets to image. You are looking at the sky through a long straw. That problem is resolved if another detection method tells you WHERE TO LOOK.
A very interesting idea, this astronomical megaconstellation. However, I think it would be an expensive space telescope, since it would probably also require powerful relay satellites to deliver the data to Earth. How far do you have to be out of the earth's magnetic field to be able to measure anything? I could well imagine a Pathfinder mission out of a dozen Cubesats at the L3 or L4 point of the Earth-Moon system.
this is absolutely captivating! ^_^ you both were fantastic (communicating is hard sometimes!! especially w topics such as these😅).thanks for sharing ur insights girlie 😊😊
Since you need very low structural integrity in space, how about building an arecibo style mesh dish in space as a spider like 3D print? with a proper dish you don't need computational coherence which might be nasty. And presumably you could weave quite a large dish in space. Say 10km diameter and wouldn't need to be in lagrange, it could be in high earth orbit. Maybe earth moon L4
What about two Smart constellations of cube sats that are semi-autonomous? The 1000's of satellites can be networked together with some type of wireless com system. whether it be Wi-Fi, blue tooth, laser, or even RF. With ion propulsion needing far less fuel source, the individual sats need minimal propulsion for very small corrections to maintain their station within the two constellations at L4 & L5. This could even allow the constellations to expand and shrink and replace malfunctioned or dead sats by cubes maneuvering into the vacated spot within the constellation grid.
Radio telescope.... What's the biggest thing there eh we create black hole pictures ..in our server room .ahum. I suppose they have good wifi there right . And walk around with handheld radios.. An amateur radio with humor would create nice wow signals there.
Hi fraiser, If we eventually left earth to find another new planet to live on perhaps carry on travelling to more planets. Would a planet full of water be best (blocks radiation, make fuel oxygen, grow food) if not which planet do you thinks best. Love your channel m8
How would these satellites fail? Would they just randomly fall out of the Lagrange Points over time? Would thousands of defunct satellites at the L4/L5 points cause a problem for other missions? Or, are the Lagrange Points too big for this to be an issue? This is a cool idea. Hope it works out!
I wish Elon musk helped you with a space telescope and built it with the capability for increasing rings of hexagonal mirrors, with mirror backframe able to connect, dock using robotic arm to build in up space . Starship with jwst mirror backframe attached that can increasing in size by connecting more frames together each time. Starship houses upgradable components . 🙏
So how long before we just start dotting 'all those asteroids' with sensors instead of sending up the whole craft? Yes we need the crafts as well..., just saying 🤷♂ Awesome stuff!
I think these constellation satellites should have a "Suicide Rocket" to send them to the Sun when faulty or decommissioned. That way the entire L4 could be cleared and replenished as the technology matures. The Sun won't mind the extra mass.
Consider the charged moon orbiting closest to Jupiter. The moon should act like an antenna that emits a frequency equal to the orbital frequency. But that makes the wavelength billions of miles long
25000 k resolution astralnet but yeah nice thin to thick test zone , a six switchback , awesome if it could be tuned and confirmed to any variables in known scalar physics methods etc maybe repulsive and more quiet and some lower simulations potential for those that they behave the same throughout the cosmos
It might be interesting to include this in the Fermi paradox explanation list. Aliens deliberately broadcasting messages at ultra-long radio wavelengths to ensure grabbing the attention of civilizations employing fleets of craft outside their atmospheres working in tandem as radio telescopes.
Processing satellite data at L4 or L5 limits growth of the data processing device as hardware technologies develops . Also having a central data collection and processing unit at L3 or L4 puts a single point failure out of reach.
When the humans become less egotistical and “powercentric” they will open the archives in the Vatican and other special holding places of ancient information. They will learn more about their past as well as get clues to which instruments to make and where to locate them to maximize their efforts to discover who they are and where they came from, in all variances of vibration.
![Fusion Reactor To Melt Through Europa's Ice [NIAC 2023]](http://i.ytimg.com/vi/7Idm53V687I/mqdefault.jpg)
I love the idea, and this part from NASA's website really sold it for me:
"Failure tolerance: Because of the scale of these constellations, a single spacecraft is no longer mission critical. Not only are failures tolerated, they are expected and built into calculations. This fail fast, fail cheap approach is a drastic departure from traditional practices."
Thanks Mary for coming on!!!
Unfortunately, public tolerance (or giving politicians the opportunity to grandstand) re: mission failures is what killed off NASA's Faster, Better, Cheaper programs in the late 90's and early 2000's. I had the honor of working on a couple of those. People don't remember the successes (or how comparatively cheap they were to fly) and only focus on failures. It seems to ebb and flow. We went from the Mars Observer failure to BFC missions managed by contractors, and back again to large and sensitive missions managed by JPL. Few people remember, we got the Mars Pathfinder / Sojourner Rover mission for the same price as it took Kevin Costner to produce the film Water World. BFC lets scientists and engineers be bold (but they have to balance that with the public's hunger for success).
@@ivantuma7969 the public is very irrational most of the time due to the seeming prevalence of ignorance.
Fraser, you're such a good interviewer! I've been following your channel for several years now, and you never cease to impress with your ability to ask relevant and interesting follow up questions. Thanks for the the consistently high quality content!
Definitely one of his best interviews, good ideas bouncing off each other, good rapport with the guest, both fully engaged. A+ would recommend.
Brilliant.
This is overdue, we've known for a long time how important our magnetosphere is to life on Earth.
You can also consider using the Lagrange points of multiple planets as opposed to 1, 2 or 3 of Earth alone.
When this is a 3D array in space, it can measure anything within it's capabilities in any direction. Almost in all directions at the same time - but you mentioned it: The bottlenecks are the computational power at the array or nearby - and the transmission rate, the bandwidth to bring that data back to Earth.
When they bring back the raw data of each and every antenna in that array, they can do calculations at home on Earth for any object in any direction. But it requires an enormous bandwidth between Earth and this satellite array at L4 or L5 (or both) that is not available.
Or let computers in that array in space do the calculations, but the computers there might be small and might be a compromise to bring the computers up to L4 or L5 and they can't be upgraded like on Earth. So the computers in that array (or near that array) would be programmed to calculate the combination of the signals only for specific directions one at a time. And then they send only the result for this one direction (or just a few directions at once) back to Earth. Every other measurements are lost. They cannot be transmitted as raw data to Earth.
They need to find a doable compromise, wow, a difficult work to do...
A solution in mind, perhaps we can utilize Free-space optical communication (along with orbital angular momentum and other kinds of multiplexing) since in space there is no fog, cloud, or anything that renders optical wireless communication to short distances which is in the case for terrestrial OWC.
Sounds like LOFAR, the Low Frequency Array, the new European radio telescope constructed by ASTRON in the Netherlands, operating in the largely unexplored frequency range between 10 and 240 MHz.
Jus tlove interviewees like her. She's brilliant and all her answers are unambiguous and exactly on the topics asked, not less not more.
Fraser, Great interview on interesting topic. It reminds me of a book I read back in 1960: "Venus Equilateral". IIRC the author was George O,. Smith ( an electrical engineer who worked on radar during WWII). The premise of the book was that knowledge and technology had not progressed from the 1940's but we had found propulsion technology on Mars that allowed us to colonize the inner solar system. It is a bit juvenile, but a great read nonetheless.
Also, back in the 1980's, I was giving a lecture at the University of New Mexico and was invited to tour the Very Large Array. Another convolution of modern technology and the Old West. After the VLA was built, they had to tear up all the roads used in its construction for fear of cattle rustlers.
Don Ziesig
a HUNDRED KILOMETER telescope?!, I think my heart just skipped a beat..
Made of many scopes.
Fantastic idea
Very thoughtful concept.
Great interview 👍
14:05 - 14:22 As a comsat guy, I'm leery of the difficulty of getting large amounts of data back from large numbers of randomly oriented, "tumbling" satellites, but other than that this sounds like a great idea. =)
Given the sheer number of smaller payloads this system would use, it sounds like a payload appropriate to just a launch or three of SpaceX's Starship.
What a great interview!
Super exciting! Proxima Centauri is within 30 light years. I love that picture: blip... blip... blip... as it hits each planet. And there you go, you gave them a new idea (both LP's).
A satellite at EM4 and / or EM5 with 12, 20 or 30 30cm telescopes mounted on a geodesic frame could be designed to watch the entire sky simultaneously and instantaneously. (Clearly, the more telescopes, the smaller the angle onserved by any one telescope and the higher the total resolution.)
Such a system could be designed to fit within a falcon 9 or heavy fairing, or indeed any laucher fairing, depending, so that it could be launched in one shot.
Laser telemetry would have the needed bandwidth to send down the data continuously.
One could start small with 12 20cm scopes in a dodecahedra pattern and work your way up to 30 1m scopes. Raw data would be placed into an online repository for researchers to reference.
Data would need to also include accurate positional data of the spacecraft for astrometry purposes.
I like the idea of using it for high-resolution monitoring of the Sol system that came up from his question about using multiple Lagrange points around the sun
Using two Lagrange points should give you a parallax view.
The architecture tradeoff might be all of the above which is doable with cubesats and a few larger node SATs which could be data collection/retransmission nodes
This was a really interesting interview. Dr Knapp really knows her stuff. 👍
Fraser i have said it before and will continue to feed your ego, best interviewer in the solar system, wouldnt it be cool if you added lagrange to your name as a tribute and possibly lessen the amounts of times you get it explained to you =D
Would be nice if you put the interviewee's name in the videos title.
With small sensors could they be attached to existing craft (such as starlink) to reduce need for shared sub systems like power and propulsion?
A great idea, investigating this interstella Plasma and the Plasma filliments are essential for deepspace missions alone let alone drawing in the electrical differential from the Sun to charge spaceships, in theory the electrical charge has more potential than solar radiation
Hi CHRIS..there is a huge amount of structures and mechanical devices ETC everywhere in this one..great work AGAIN from you man..👍👍
This was excellent! Thank you.
It seems like M I T is at the heart of every big breakthrough these days. Hopkins too.
We've been missing the AM radio transmissions from other planets! OK spend all the money, I want to hear 88.5 from outer space
Imagine we hear a random alien talk show the moment we switch the telescope on.
This is very interesting, thanks for sharing 👍
I had this idea years ago so as to search for power grids of advanced civilizations. No one wanted to build the low-frequency telescope. Not only will they be able to detect magnetospheres but power grids also, if they exist.
When LIDO first gave us detection of Gravitational Waves, the first thing I ask myself was "What frequency are those waves"? Are they at the same frequency range as earthquakes?
Just an editing note.. for us earbud wearers.. I found the subtle background music to be too distracting. Otherwise, nothing but love for this channel ❤
Way cool interview, again!
Now imagine sending a message to ET saying... "Could you guys please shut up? We're trying to observe the star system over there!"... 😬
Cheers, thanks a lot!!
Excellent interview. What do you think about the concept of a quantum interferometer telescope?
I feel like I'm misunderstanding something. How does a collection of observers observe a single photon? Doesn't something have to absorb the photon in order to measure it? Does radio receiving not actually function by absorption, but "just" measuring how local electrons are "influenced" by a "passing" photon?
Maybe they can adapt something of the ELF (3-300 Hertz) submarine communications systems? Everybody has one now. They have to transmit through the ground, then through the sea water, but the submarines can get the signal through some kind of huge antenna. One of my favorite writers had the bad guys using this in a book "Wild Fire" a few decades ago.
Awesome interview!
This sounds like a really good idea. I hope she gets all the financial and governmental support she needs.
FC could have been tongue in cheek right there and said "no need to explain L points to my audience" lol
Also I really didn't know Jupiter's mag sphere was bigger than than most stars at certain times but it checks out at some wavelengths! Awesome
But then people would say I shouldn't interrupt her.
@@frasercain it's a tightrope isn't it....she didn't spend much time on it so no problem right. I really enjoyed this one she knew her stuff
Any chance we could work with whatever company to make the cube-sats with multipurpose use and get many benefits and share cost/responsibility to perhaps reduce the amount of overall "junk" that goes up and interferes with, well, anything else we send up there? I know, probably wishful thinking and all, but I always love things that perform multiple tasks even if it might be slightly less effective in one specific area. Maybe for future communications as we expand out into the solar system and all. I'm sure someone smart can figure out a solution so it's more of a win-win-win and all that amazing stuff! Let's go BIG!!! (Like, mind-numbing large for any space telescope and just keep the data flowing, even if there is no way to review it all in the next 100 years) 🌌🌠📡🔭🖥️🚀🛸
mazing interview, there is so many great people with amazing ideas.
This idea can pay off for weak gravitational waves. Nice video..
Good interview & good wishes for both of you.
Oh interesting, I hadn't thought of that.
@@frasercain
It is nice of you. You have done the job at your hand with available informations very skillfully . You make me to dream on the subject.
Thank you.
Will this tech be able to track spaceships? Satellites? Space junk? Asteroids? What about airplanes? Surface ships? Submarines? Image Earth underground? Would it detect the effects of a gravity drive?
Given an unlimited budget, how long until you can launch your first telescopes? Would you consider making the raw data open source?
Sending the raw data back to Earth will allow any researcher to focus the telescope anywhere. All researchers have equal, simultaneous access, just by querying the data archive any year the researcher thinks to run the experiment.
Might the telescope array be used for terrestrial air traffic control? Is a 20-second latency “close enough” for some purposes in real-time?
Would this array work, even if ground-based?
Wow for exoplanets this seems better than JWST
there must me be loads of other radio sources in the sky on these same frequencies. For starters Jupiter and Saturn will emit very strong on these frequencies. Another thing is that there will be other sources, like black holes, magnetars, quasars etc. Essentially this radio interferometer will be totally swamped.
That means, that while idea is very good, they'll not be to differentiate signals.
yeah, data management in space will be a neat problem to have to solve
wow this guy has good questions
Sounds like you need Arecibo in space. This idea is more realistic.
RE: Techno signatures. Should other technos use the equivalent of Project ELF, then possibly this could be detected.
Shes great
Perhaps a subfrequency of this ultra low spectrum can detect life
Picking up very long wavelengths, in Space, does not seem, in itself, a very hard problem. How do you pick up AM radio, with waves up to about 600 meters, on a pocket radio? You wind a helical antenna, with a very long effective length, that fits inside a case less than 10 cm wide. The difference I can see in this situation is how to get directionality. That tends to be done with dishes, but those are not practical at such extreme wavelengths, at least not with conventional techniques.
@elonmusk Please read my comment on this video. You can help groups be "early settlers". Venus has a lot of potential if only because it is stable and complex. A few million human equivalent years of thought and it might be easier than we think.
I wish all those internet and communication satellites put into orbit by SpaceX and other companies had an extra feature onboard that faced away from Earth to search and monitor for any ELE asteroid threats heading towards us as an early warning system. I guess it would cost too much for these companies to operate such an important system, or perhaps they don't care about such threats to human civilisation. But having all those thousands of satellites monitoring the solar system 24/7/365 for rogue asteroids would be extremely useful.
She describes this at tidy because dead craft will be trapped at the Lagrange points. But don't we need to be concerned about a space junk problem at the Lagrange points themselves?
No, the L4/L5 are giant regions, millions of kilometers across. There's lots of room.
@@frasercain Ahhh, this is where a little further reading would have helped. I didn't realize how large they were. 🤯
I'm still concerned. A hundred thousand satellites every ten years for thousands of years, plus hundreds of O'Neil cylinders means someone will get hurt. I'd need to see the math to be reassured.
Great interview! :-)
@@williammiller5578 I wondered about this too, but it occured to me that we can't really compare it to, for example, the orbital space junk problem. With the Lagrange points, we're basically talking about a whole lot of objects traveling on a highway in the same direction at the same speed. The orbital space junk is more like a bunch of rowdy kids in bumper cars.
@@frasercain the L4/L5 regions of the moon earth system aren't millions of km across, more likely 20 000 km and more like a pancake (comparable with the 300 km thick airspace above all the Pacific's) , but a object cannot stay in those areas if it have a higher velocity relative with the center of those areas, so if are a lot of decommissioned satellites probably you could pick them with a robotic arms in a single mission and clean the space cheap and easy not like on the LEO when you need to adjust your cleaning spacecraft orbital speed and inclination for each piece of garbage by a lot.
If they added a small telescope antenna to each starlink sat they could piggy back data.
let us phheer...
Thank you for interviewing a woman.
..there's all the grant money you could ever need..Propose we have the highest resolution of our suns EMF/CME
Around 12 minutes, this lady is explaining LaGrange points to people who regularly watch Science and Space news, maybe take the training wheels off this interview.
Fraser asked and it was a part of the explanation, and if you know everything anyhow, why bother watching?
ZHYFLANIIKE
100 percent waste of money...black holes is a THEORY.
A loaf of bread and a big cereal box are roughly the same size that was a stupid comparison
_Lagrange points_
Have you heard about these things?
Wonderful interview with very interesting questions and clear answers with a very articulate and clearly knowledgeable Dr Mary Knapp. Looking forward to a follow-up with her and what her team is doing. It would be cool if there was a way to utilize some time and array testing using Starlink Satellites, as they're already over 3,000 in orbit, and the communications part of the equation would be essentially done. Elon might get on board. 🤷♀
Really, really interesting project indeed! 😃
Thanks for the interview, Fraser!!!
My only question is about a radio telescope in the far side of the Moon... Couldn't it be built in the same way? (Not using solar power for the operation, of course, but either way...)
Anyway, stay safe there with your family! 🖖😊
Loved this interview! The dispersed architecture seems smart for longevity of the array because you can trickle in more elements to replace old ones, and update the instrumentation and data processing to take advantage of new tech, or new missions. It makes so much sense. But I'm also excited to see the local neighborhood in a new wavelength. I expect it to be a bit mind blowing.
Other planets in our solar system have La Grange points as well. Can't we use really efficient but slower orbital insertion methods to send a few big boxes of these cubesats into Martian or even Jovian L4/L5 configurations? This goes back to Grace Hopper's comment-I know what we can do with one big tractor. What can we do with a few thousand small tractors?
Jupiter's magnetic field is too powerful and for this the interference would be a problem even outside the field, have to use Mars if it has a decent Lagrange point. Or maybe Venus, but both Mars and Venus have no magnetic fields and may be better than Earth if Venus isn't too close to the Sun.
I'm glad Fraser Cain proposed to use both L4 and L5. That would of course be my first thought : I wanna hear those alien radio-talk shows, when they are stuck in the transit around Tau Ceti.
real Sirius radio shows?
Yes, everyone on the channel was shouting "L4+L5" at the screen. Fraser knows his audience so well :) TBF he was brilliant on this episode. Good guest also, very honest lady with no ego-says "I don't know" when they are not sure, instead of selling us BS like previous guests.
37:35 Given, that SpaceX already has smallsat factory going, maybe it would make sense to just order from them to do a version with astro modification? Are their argon-ion engines enough for station keeping at Lagrange points?
How amazing is Mary Knapp? She is super cute to me😊 watching her animations when she is excited about the subject she is discussing captivate me. Super cool Ms Knapp keep up the good work! And thank you for the type of work you do it's so important to me and all of us i believe. Crushing hard on Mary Knapp❤😊
What an awesome interview, Fraser! It is so great watching another brilliant female scientist with an insight that could change our view of the Universe. Best of luck and insights to you and your team! I will be longing for hearing of and reading about the amazing things you are certain to find.
We should launch a few hundred space radiotelescopes into Sun orbits in like a GPS satellite pattern but around the Sun, at say 1.25 AU, and then we'd have a 100 million km telescope. That should give us enough resolution to read the headlines of exo-newspapers, assuming they use magnetic ink. No, seriously.
The interstellar plasma resulting in diminishing returns is a disappointment. For a while, I've been wondering about the difference between a megameter telescope and a gigameter telescope.
This is my favorite kind of show.
So much to learn from this type of discussion.
Thanks for all your hard work!
This interview is So Freaking Good. 2023 space new slaps.
I really enjoyed this interview with Dr. Knapp. Very informative and insightful!
A really interesting interview, thank you both!
What do you imagine that an observer, in say Andromeda, would conclude from looking at Earth and the amount of technological equipment surrounding the planet?
How hard would it be to generate an artificial magnetosphere that's strong enough to protect interstellar spacecraft?
It would probably require fusion amounts of power. Meby something strong enough could be made with multiple high power fission reactors.
why would it be "artificial?"
if you had a large molten iron core rotating in the center of your spacecraft would that make a natural/organic magnetosphere?
@@JuandeFucaU it probably would cost more power to keep something like that molten and spinning.. rather than using electromagnets, like mri machines.. but bigger. Meby even a hoop on the outside of a spinning habitat.. it could even be used for counterspin possibly..
@@tra-viskaiser8737 well, if we're going to be sensible about this, why bother with a magnetosphere on a spacecraft at all when plenty of things can shield us from radiation better than an electrical field. like water, for instance.
Or maybe an artificial magnetic field for a lunar or martian settlement so the habitat can have windows. Perhaps an artificial magnetic field for a giant space station.
This is perhaps THE MOST exciting projects I've heard of.
You absolutely NEVER hear anyone discussing the interstellar Plasma that we know exists, but can't see. The fabric of the Cosmic Web.
Within seconds of thinking of my next question, Frasier was asking that exact question like some kind of mind link.
With the assumption that many, if not most habitable planets may exist within the halo of Brown Dwarf stars, and are therefore functionality invisible to us, I wonder if this is the technology that could solve this problem.
Regardless, I am excited at the prospect of mapping the Cosmic Web and the electromagnetic pathways that link planets, galactic structures, and even galaxies and galactic clusters themselves.
We just might learn, as some in the field have been saying for years, that NO object is independent from its environment, and that the reality is much more profound.
Such research may reveal that ALL of the visible universe is interconnected, and the electrodynamics of interstellar plasma play a much larger role in the formation and evolution of our universe than the very weak force of gravity.
We actually could be a cog in the electromagnetic engine of the entire universe. That would explain a lot and solve what we've been getting wrong about our current models and lead to a tremendous advancement in our knowledge and understanding.
Low frequency tech signature of OUR civilization: 60 Hz alternating current in Western Hemisphere, 50 Hz in Eastern Hemisphere radiating from the continental power grids into space. If ET is using alternating current, which, depending on a time window of how long AC long range transmission tech remains relevant (for us, more than a century and counting and no sign of obsolescence), then that is something to look for. Of course, for ETs, it won't be exactly those freqs, but the range of efficient frequencies would be constrained by engineering considerations.
Once magnetospheric or technological planets are LOCATED, they might be a target for more advanced imaging instruments. A problem of the highest resolution instruments is they have a narrow field, and are problematic for FINDING targets to image. You are looking at the sky through a long straw. That problem is resolved if another detection method tells you WHERE TO LOOK.
A very interesting idea, this astronomical megaconstellation.
However, I think it would be an expensive space telescope, since it would probably also require powerful relay satellites to deliver the data to Earth.
How far do you have to be out of the earth's magnetic field to be able to measure anything?
I could well imagine a Pathfinder mission out of a dozen Cubesats at the L3 or L4 point of the Earth-Moon system.
this is absolutely captivating! ^_^ you both were fantastic (communicating is hard sometimes!! especially w topics such as these😅).thanks for sharing ur insights girlie 😊😊
Since you need very low structural integrity in space, how about building an arecibo style mesh dish in space as a spider like 3D print? with a proper dish you don't need computational coherence which might be nasty. And presumably you could weave quite a large dish in space. Say 10km diameter and wouldn't need to be in lagrange, it could be in high earth orbit. Maybe earth moon L4
What about two Smart constellations of cube sats that are semi-autonomous? The 1000's of satellites can be networked together with some type of wireless com system. whether it be Wi-Fi, blue tooth, laser, or even RF. With ion propulsion needing far less fuel source, the individual sats need minimal propulsion for very small corrections to maintain their station within the two constellations at L4 & L5. This could even allow the constellations to expand and shrink and replace malfunctioned or dead sats by cubes maneuvering into the vacated spot within the constellation grid.
Radio telescope.... What's the biggest thing there eh we create black hole pictures ..in our server room .ahum.
I suppose they have good wifi there right . And walk around with handheld radios..
An amateur radio with humor would create nice wow signals there.
Hi fraiser, If we eventually left earth to find another new planet to live on perhaps carry on travelling to more planets. Would a planet full of water be best (blocks radiation, make fuel oxygen, grow food) if not which planet do you thinks best. Love your channel m8
How would these satellites fail? Would they just randomly fall out of the Lagrange Points over time? Would thousands of defunct satellites at the L4/L5 points cause a problem for other missions? Or, are the Lagrange Points too big for this to be an issue? This is a cool idea. Hope it works out!
I wish Elon musk helped you with a space telescope and built it with the capability for increasing rings of hexagonal mirrors, with mirror backframe able to connect, dock using robotic arm to build in up space . Starship with jwst mirror backframe attached that can increasing in size by connecting more frames together each time. Starship houses upgradable components . 🙏
So how long before we just start dotting 'all those asteroids' with sensors instead of sending up the whole craft? Yes we need the crafts as well..., just saying 🤷♂
Awesome stuff!
I think these constellation satellites should have a "Suicide Rocket" to send them to the Sun when faulty or decommissioned. That way the entire L4 could be cleared and replenished as the technology matures. The Sun won't mind the extra mass.
Isn't the Lagrange points causing problems for the James Web space telescope be🎉hit by dust and stuff?
Consider the charged moon orbiting closest to Jupiter. The moon should act like an antenna that emits a frequency equal to the orbital frequency. But that makes the wavelength billions of miles long
25000 k resolution astralnet but yeah nice thin to thick test zone , a six switchback , awesome if it could be tuned and confirmed to any variables in known scalar physics methods etc maybe repulsive and more quiet and some lower simulations potential for those that they behave the same throughout the cosmos
Wow she's good.
Yeah, great chat.
It might be interesting to include this in the Fermi paradox explanation list. Aliens deliberately broadcasting messages at ultra-long radio wavelengths to ensure grabbing the attention of civilizations employing fleets of craft outside their atmospheres working in tandem as radio telescopes.
Processing satellite data at L4 or L5 limits growth of the data processing device as hardware technologies develops . Also having a central data collection and processing unit at L3 or L4 puts a single point failure out of reach.
When the humans become less egotistical and “powercentric” they will open the archives in the Vatican and other special holding places of ancient information. They will learn more about their past as well as get clues to which instruments to make and where to locate them to maximize their efforts to discover who they are and where they came from, in all variances of vibration.