>The Deep Space Network has only three 70-meter dishes, and there is a lot of competition for time on them;
It seems like I've heard this time and again, that certain data or measurements couldn't be returned from planetary spacecraft because of limitations in the DSN. I'd guess that a relatively modest investment could double or tripe the DSN availability and bandwidth simply through more antennas and the associated receivers. I'm guessing that the reasons are political (funding), are there technical issues I'm unaware of?
This is absolutely the best comparison. You've really gotta wonder what the under-the-table purpose of that fighter is. As if our closer allies get told "Hey, the ante for participating in PRISM et al is buying 26 of these totally useless fighters that burn up on the runway." I am going to be totally interested in whatever gets declassified about this program in the future.
Why does it need to be under-the-table? It seems pretty clear to me:
— military industry wanting more money
— deterrence
— air superiority
— hi-tech jobs, research and manufacture capabilities
Probably even in this priority order. The bottom line is that there is a lot of good in this "useless fighters", even if it's not as sexy/obvious as DSN. There may be a corruption element, but it doesn't mean that the program is "useless" for general public.
After all, I'm writing this to you using the heir of DARPA's "stupid entanglement of number-crunching machines".
You're implying these things can actually get off the ground. For what American taxpayers are spending on this project, you better believe there better be some bang for that buck. And so far it's amounted to essentially nothing but more of the same companies getting away with pillage.
According to Red Flag results, F22s are extremely effective (e.g. [1]). In fact, even if you take an article that "criticize" F22 (like [2]) and pay an attention to what article really says, it's like "okay-okay, it's the best, BUT YOU KNOW IT CAN SUCK SOMETIMES".
I understand the appeal of blaming govt on excessive spending. Being Russian, I can't agree more (our govt is way worse). However, I believe that blind and self-righteous critique like "it can't get off the ground" is destructive.
I just love the image of a spaceship hacked to do cartwheels in space while shunting power to its backup antenna to double the Tx rate. And that this was developed after it was already in space.
After this and watching Apollo 13 I now have the impression "hacking" is fundamental to space exploration.
The Martian is a thoroughly agreeable read. I thought it might be a bit dry but it's interspersed with some really funny bits that made me laugh out loud.
How long do you think communication session using Arecibo would last?
Edit: apparently some did not get the point I was making. Arecibo's dish is fixed, so there is practically no way to track the object. And earth is rotating. If you had a chance to see the stars through telescope, it rotates FAST. With Arecibo you can only catch a blip of communication.
Suppose like you say, all earth-bound telescopes have a small window of observation. How many hours a day would that be? Aside from watching Contact or Goldeneye, my only source of knowledge about dishes is a C-band. But, according to its wikipedia entry, Arecibo has a 40 degree range of 'motion'.
"To aim the device, the receiver is moved [by cables] to intercept signals reflected from different directions by the spherical dish surface." ... "A parabolic mirror would have varying astigmatism when the receiver is off the focal point, but the error of a spherical mirror is the same in every direction."
The limit: "This allows the Telescope to observe any region of the sky in a forty-degree cone of visibility about the local zenith (between −1 and 38 degrees of declination)".
From universe today, "Pluto’s orbit is also highly inclined. This means that it doesn’t orbit within the same plane as the rest of the Solar System. Instead, Pluto orbits at an angle of 17-degrees."
Arecibo is at latitude 18.3 or so. Not at the equator, but for half a year it's probably tilted more favorably to the middle. Does this make Arecibo even remotely practical for the application?
Arecibo can only be only be pointed slightly by moving the hanging receiver. To communicate with a spacecraft far away you want a dish pointed straight at it, to get a high gain.
Video compression (even lossless) leverages the fact that successive frames are very similar; that's not the case here, as photos can be taken hours apart, in various directions, and in various zoom levels. So you'll get basically the same compression either way...
Any little destablisation will cause it to start to move, because there's nothing to react it. By spinning something around its axis of maximum or minimum moment of inertia, you stablise it - like a bullet being rifled.
The destablisation will come from any number of things - minor gravitational inconsistencies, solar wind, dust, heat radiation from the power source, etc.
This paper says the downlink uses a rate 1/6 forward ECC -- 6 encoded bits for every 1 message bit. From the context, the ~1 kbps figure should mean the information rate; the tone rate would be 6x higher.
6.3. DOWNLINK SYSTEM PERFORMANCE
The downlink card in each IEM is the exciter for the TWTAs
and encodes frame data from the spacecraft C&DH system into
rate 1/6, CCSDS turbocoded blocks.
110 or 300 baud were the "first" modems. My first 1200 baud modem just screamed. In comparison, of course.
An effective 2000 bits/second from Pluto is the stuff of science fiction. (Actually, even SF from the 50s was full of situations like being out of radio contact with Earth because of distances on the order of an AU or so. With available technology they were probably right).
It's mostly a question of power. The 1987 design for the TAU probe communication system would have handled 20 kb/s from 1000 AU... by using between 100 and 260 watts for the transmitter (and relatively big antennas):
Very interesting overall. I like this small factoid, "They can be made even smaller with lossy JPEG compression, but for optical navigation, precision counts; the pictures have to be returned losslessly." I think this implies that the most distant JPEG software is currently in route to Pluto.
Use of lossy compression for science imagery is contentious. Because it's hard to characterize how the compression will affect as-yet-unseen science targets, it's hard to get scientists to accept lossy compression.
You can sometimes get acceptance of prioritized downlink -- let automation decide what is most interesting, and downlink that first. Variations on that idea have been used for Mars rovers.
I once visited a crackpot aliens-on-the-moon conspiracy website. They were showing zoomed-in images of lunar craters purporting to show regular, artificial-looking features indicating alien activity.
Of course in context I'm sure you can guess what was going on. The images were heavily compressed jpegs and I soon realised the 'regular features' were compression artifacts.
Still, it goes to show why some scientists don't like lossy compression. When you're looking at fine detail it's hard to be sure whether what you're seeing is 'real' or not.
I don't think it implies that at all. I think they're saying that the pictures could be compressed with JPEG if they wanted them to be, but they very clearly state that they don't, and nothing in the article indicates that the spacecraft would have any other use for JPEG software.
It seems like I've heard this time and again, that certain data or measurements couldn't be returned from planetary spacecraft because of limitations in the DSN. I'd guess that a relatively modest investment could double or tripe the DSN availability and bandwidth simply through more antennas and the associated receivers. I'm guessing that the reasons are political (funding), are there technical issues I'm unaware of?
Off to read up on this.
edit: They are adding antennas!