Asteroid Grand Tour |
Asteroid Grand Tour |
Apr 7 2007, 01:31 AM
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#1
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Merciless Robot Group: Admin Posts: 8783 Joined: 8-December 05 From: Los Angeles Member No.: 602 |
This article from JPL describes recent efforts to derive a main belt multi-asteroid mission trajectory...any of you orbitsmiths out there have some early thoughts/observations?
-------------------- A few will take this knowledge and use this power of a dream realized as a force for change, an impetus for further discovery to make less ancient dreams real.
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Apr 7 2007, 03:10 AM
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#2
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Member Group: Members Posts: 903 Joined: 30-January 05 Member No.: 162 |
I don't know if this is original with me, but I have always liked this concept. (note, this may not fulfill all the mission objectives, or be the fastest)
Launch your probe to pass 60 degress ahead of Jupiter at the time it crosses Jupiter's orbit. You time launch to pass 1 or 2 asteroids in the main belt on your way to encountering a leading Jupiter Trojan. Keep moving out past Jupiter, maybe you get lucky and go by Hidalgo or Chiron (maybe not . . .). Your orbit about the sun is timed to fall back towards the sun so that you cross Jupiter's orbit when the trailing Trojan's are going by and you get to encounter one of them. After that, you fall back through the asteroid belt, and you get to encounter 1 or 2 more asteroids. If your period about the sun is an integer # of years, the probe comes close to earth again, maybe gets a little gravitational nudge to go back out to the asteroid belt again, maybe out of the ecliptic a little bit this go round. (this time, Jupiter Trojans probably elsewhere, so you don't get to see them again, but you do get to go out through the asteroid belt and back again, might pick up to 4 more 'roids) So if the timing isn't too tricky, you get to see up to 8 mainbelts and a couple of Trojans. If you really want to see Chiron, well, you might be jamming up some of the other encounters. Otherwise, if you aren't too picky about which main belts you see (afterall, you get to see up to 8 if luck holds) timing of your launch is pretty much every 13 months or so, might be easier to fly with a little flexibility, rather than trying for a 1 in how many millions shot at 4 specific ones. |
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Apr 7 2007, 03:55 AM
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#3
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Administrator Group: Admin Posts: 5172 Joined: 4-August 05 From: Pasadena, CA, USA, Earth Member No.: 454 |
I thought that article was interesting but wish they'd published some details of the winning trajectory...
--Emily -------------------- My website - My Patreon - @elakdawalla on Twitter - Please support unmannedspaceflight.com by donating here.
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Apr 7 2007, 05:44 AM
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#4
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Merciless Robot Group: Admin Posts: 8783 Joined: 8-December 05 From: Los Angeles Member No.: 602 |
Yeah, Emily. It was notably short of specific targets and/or down-selects, wasn't it? I interpreted this as strictly early concept development activity...nobody's gonna get assertive unless & until a feasible mission strategy emerges.
-------------------- A few will take this knowledge and use this power of a dream realized as a force for change, an impetus for further discovery to make less ancient dreams real.
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Apr 7 2007, 08:02 AM
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#5
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Senior Member Group: Members Posts: 1870 Joined: 20-February 05 Member No.: 174 |
Classic example of a press release about a science/tech item that leaves out the most important piece of info. I see them all the time, and they're not all by ESA press flunkies... not by a long shot!
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Apr 7 2007, 09:45 AM
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#6
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Member Group: Members Posts: 813 Joined: 8-February 04 From: Arabia Terra Member No.: 12 |
The trajectory details for the 2006 GTOC 1 are here:
http://www.esa.int/gsp/ACT/mad/pp/GTOC1/gtoc1results.htm Presumably the results for GTOC 2 have yet to be uploaded. |
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Apr 7 2007, 09:57 AM
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#7
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Founder Group: Chairman Posts: 14431 Joined: 8-February 04 Member No.: 1 |
LOVE it...
EVEEEJSJA EVVEEVVEVEJSJA EEVEEJSA Makes Galileo and Cassini seem like a quick trip to the shops round the corner. Doug |
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Apr 7 2007, 01:45 PM
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#8
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Merciless Robot Group: Admin Posts: 8783 Joined: 8-December 05 From: Los Angeles Member No.: 602 |
30-year mission duration for those long hauls using only 60 kg of propellant...amazing!
-------------------- A few will take this knowledge and use this power of a dream realized as a force for change, an impetus for further discovery to make less ancient dreams real.
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Apr 7 2007, 04:50 PM
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#9
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Senior Member Group: Members Posts: 1018 Joined: 29-November 05 From: Seattle, WA, USA Member No.: 590 |
Any idea what "v-infinity" means in the JPL results? To me, it means the "hyperbolic excess," but the show it with positive values even for elliptic orbits.
--Greg |
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Apr 7 2007, 05:49 PM
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#10
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Administrator Group: Admin Posts: 5172 Joined: 4-August 05 From: Pasadena, CA, USA, Earth Member No.: 454 |
Last year's was a very different challenge. From the Problem Description (PDF):
QUOTE The main objective of the optimisation is to maximise the change in the semi-major axis of the asteroid 2001 TW229 subsequent to the impact of an electric propelled spacecraft. I'm more interested in this year's results...I'd love to see a multi-asteroid tour. Dawn will get two, but that's in part because it's aiming for two very specific ones, and is going into orbit at both. Another mission that was less constrained could surely survey more in shorter time.1-The target Consider the asteroid 2001 TW229 and its osculating orbital elements in the J2000.0 heliocentric ecliptic reference frame: a (semi-major axis, AU): 2.5897261 e (eccentricity): 0.2734625 i (inclination, deg.): 6.40734 ω (argument of pericenter, deg.): 264.78691 Ω (Right Ascension of the Ascending Node, deg.): 128.34711 M (mean anomaly at epoch 53600 MJD, deg.): 320.47955 2-The spacecraft Consider a nuclear electric propelled spacecraft with a wet mass of 1500 kg (dry mass can be considered to be zero) and equipped with a thruster with the following capabilities: specific impulse Isp=2500 sec., maximum thrust level T=0.04 N. 3-The mission The spacecraft has to be transferred from Earth to the asteroid 2001 TW229 with a launch in [3653-10958] MJD2000 (Modified Julian Date 2000), corresponding to years 2010 to 2030. The maximum time of flight is 30 years. At arrival the quantity {equation: J = mf |U-rel dot v-ast|} has to be maximised, where mf is the final mass of the spacecraft, U-rel is the velocity of the spacecraft relative to the asteroid at arrival and v-ast is the heliocentric velocity of the asteroid. The launcher available for the mission is able to provide a 2.5 km/sec escape velocity to the spacecraft with no constraint on the escape asymptote direction. Consider also a constraint on the minimum allowed heliocentric distance of 0.2 AU. 4-The dynamical models Consider only the Sun gravity as an external force acting on the spacecraft. Planets may be used to perform swing-bys, in this case the effect should be modelled as an instantaneous direction change on the spacecraft velocity relative to the planet, subject to a constraint on the angle magnitude (a minimum pericenter radius has to be considered, see table below for details). The planet ephemerides used should have an accuracy equivalent to that of JPL DE405 ephemerides (http://ssd.jpl.nasa.gov/horizons.html). Use the numerical values given below and assume the astronomical unit equal to AU=1.4959787066e+008 km, and the Earth standard gravitational acceleration to g0=9.80665 m/s2. CODE Mercury Venus Earth Mars Jupiter Saturn Sun Gravitational Constant, km^3/sec^2 22321 324860 398601.19 42828.3 126700000 37900000 1.32712428 e+011 Minimum pericenter radius allowed during fly-by, km 2740 6351 6678 3689 600000 70000 N/A --Emily -------------------- My website - My Patreon - @elakdawalla on Twitter - Please support unmannedspaceflight.com by donating here.
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Apr 7 2007, 11:39 PM
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#11
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Senior Member Group: Members Posts: 2530 Joined: 20-April 05 Member No.: 321 |
I'll echo my concept of a retrograde solar orbit for a truly grand tour of the asteroids. A craft would use a Jupiter gravity assist to enter a retrograde orbit with perihelion 2.6 AU and aphelion 5.2 AU. When it first returned to the asteroid belt, it would fire its engines to enter a roughly circular orbit barreling in reverse right down the middle of the asteroid belt. It would be trivial to set a course intersecting any two asteroids named as primary goals. Other encounters would happen automatically, with the craft passing the radial position of some asteroid or other every few hours. Of course, in most cases, the distance would be quite great, but every few months should bring a somewhat close encounter even if only by chance. With a few more manuevers and a little planning, it should be easy to set up a large number of encounters, albeit fast ones. This would result in a lot of encounters that would map only half of an asteroid (with the craft flying by too fast to see the other half rotate into daylight), but the numbers should roll up rather impressively. I would think a dozen encounters would be a conservative estimate.
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Apr 8 2007, 06:52 AM
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#12
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Founder Group: Chairman Posts: 14431 Joined: 8-February 04 Member No.: 1 |
Your flyby velocity would be ENORMOUS though - you might sail past something like Matilde or Eros at 4 or 5km/sec on a conventional flyby - and then maybe 20km/sec if you were going the other way....eek. I'm fairly sure that you could do something like CONTOUR for asteroids with some intelligent trajectory design, 3, 4 asteroids with 3 or 4 times the data collected at each one. If you picked them right, you would get a good 'grab bag' of different types of bodies. Going the other way I imagine the spacecraft would be going "ARHGHHHHHHHHHhhhhhhhhhhhhhhhhhhhhhhhhh" all the time Perhaps you could bounce in and out ot the asteroid belt using Mars as a grav-assist teach time. Dawn but without the orbiting - you could get really nice long lazy flybys of many asteroids I would have thought. If you're going to Jupiter you would have to have crazy Juno/Rosetta like solar arrays, and if you're getting THOSE< might as well just use 2-3kw and chuck an ion engine or 5 on the back.
Doug |
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Apr 8 2007, 11:22 AM
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#13
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Senior Member Group: Members Posts: 3648 Joined: 1-October 05 From: Croatia Member No.: 523 |
Well, DI's encounter with Tempel-1 was 10 km/s so that's "only" twice as slow. I don't believe high flyby speeds would be a major drawback here. Most of these bodies are very small so you get spatially resolved datasets only in the immediate vicinity of the target (say a couple of hours) and you're not likely to stick around for much of (rotational) global coverage even with speeds in the 5 km/s range. What I'm saying is the benefit of a slow encounter isn't that great. Of course, you'd really want to put cameras capable of getting more than one image per minute *cough*Cassini*cough* to maximize science return, but even DI had that. The potential for visiting many more targets seems to outweigh this drawback to me.
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Apr 8 2007, 03:07 PM
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#14
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Merciless Robot Group: Admin Posts: 8783 Joined: 8-December 05 From: Los Angeles Member No.: 602 |
It may be that some variation of JR's idea was explored by some of the teams in this year's trajectory optimization competition, but their focus seems to be on deriving planetary "pump-up" gravitational assists. If I'm visualizing this correctly, such assists cannot occur for a spacecraft in a retrograde orbit?...
-------------------- A few will take this knowledge and use this power of a dream realized as a force for change, an impetus for further discovery to make less ancient dreams real.
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Apr 8 2007, 06:00 PM
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#15
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Member Group: Members Posts: 910 Joined: 4-September 06 From: Boston Member No.: 1102 |
The four asteroid tour (each a different type) is a very interesting problem. It is a hard version of the traveling salesman problem where you try to minimize the travel distance of visiting a bunch of cities (a NP-complete problem). To make it interesting, all the cities are moving around—they are asteroids--and you don’t know which four to pick initially. While a great deal is known about NP-complete problems, the asteroid tour is a new twist. To get a winning tour requires bring together a team with great math and computer algorithm skills as well as models for where several thousand asteroids of the four types are going to be for the next several years. Since a frontal approach to the problem would take up years of computer time (if not the age of the universe) the trick is to come up with brilliant assumptions and shortcuts that make it a problem that is doable on reasonable computer (or cluster) in a few weeks. My hats off to the team from Polytechnic of Turin, Italy.
Floyd -------------------- |
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