Title: Genesis Orals template
1Low Energy Transfers
in the Solar System Applications I Objectif
Lune (Tintin)
Martin.Lo_at_ jpl.nasa.gov
7/5/2004
2004 Summer Workshop on Advanced Topics in
Astrodynamics
2Interplanetary Superhighway
JPL Lagrange Group
1/21/03
3Outline
- Restricted 3 Body Problem Review
- Interactive Shooting Method
- Weak Stability Boundary Method (Tuesday)
- Dynamical System Methods
- Goal and Philosophy
- Low Energy Transfers in Earth-Moon Space
- Shoot the Moon
- Lunar L1 Gateway
- Lunar Sample Return
- New Mission Concepts Orbits
- Low Energy Transfers Between Galilean Moons
- Petit Grand Tour
- Jupiter Icy Moons Tour
- Anatomy of a Flyby
4Outline I Objectif Lune
- Restricted 3 Body Problem Review
- Low Energy Transfers in Earth-Moon Space
- Shoot the Moon
- Lunar L1 Gateway
- Lunar Sample Return
- Potential New Mission Orbits
5Some Historical Notes
- Classical 3-Body Problem
- Newton, Euler, Lagrange, Jacobi , Moulton
- Dynamical Systems Theory
- Poincaré, Birkhoff, Moser, Conley, McGehee
- Development of Libration Missions
- Colombo, Farquhar, Dunham, Folta
- Dynamical Systems Theory for Libration Missions
(mid 1980s) - Simó, Llibre, Goméz, Masdemont, Jorba, Martinez
- Weak Stability Boundary
- Miller Belbruno (1990)
- Resonant Transport via Invariant Manifolds
- Bolt Meiss (1995), Schroer Ott (1996)
- Mission Design Using Invariant Manifolds
- Howell, Lo (1996)
6First Halo Oribt Mission ISEE3/ICE
GSFC Farquhar, Dunham, Folta, et al
Courtesy of D. Folta, GSFC
7Current Libration Missions
WIND
SOHO
ACE
GENESIS
MAP
JWST
Courtesy of D. Folta, GSFC
8(No Transcript)
9Genesis Mission Design, Comet Orbit
- Martin Lo JPL
- Genesis Mission Design Manager
- Kathleen Howell Purdue University
- Department of Aeronautics and Astronautics
- Brian Barden JPL, Purdue University
- Roby Wilson JPL, Purdue University
- Belinda Marchand Purdue University
10- Genesis Mission Uses L1, L2 Heteroclinic
Behavior to Collect Return Solar Wind Samples
to Earth
September 8th, 2004!
11The Genesis Trajectory
1. Transfer 2. Science 3. Return 4. Entry 5.
Backup
Begin Science
End Science
Lunar Orbit
2
3
1
L2
L1
Sun (size position not to scale)
5
4
12Stable Manifold Transfer to Halo Orbit
13Stable Manifold for Genesis Transfer
14More Background Genesis
- Invariant Manifolds Provide Low Energy Transfers
- L1/L2 Heteroclinic Connection Provide Day-Side
Return - Howell, Barden, Wilson, Lo
15Earth Flyby Capture
Earth Return Via L2
16Restricted Three Body Problem (RTBP)
- Newton, first studied the 3 Body Problem
- Rotating Frame
- Euler L1, L2, L3
- Lagrange L4, L5
- Restricted Problem
- 3rd body infinitessimal
- Two primaries move in circles
- Sun-Earth-Spacecraft, Sun-Jupiter-Comet,
- Jacobi Integral
17Restricted Three Body Problem
- Simplified model with energy integral
- Useful for analytic studies
- Symmetries avoid phasing and timing problems
- Still non-integrable, i.e. no orbital elements
- Solutions requires numerical integration
- Key Problem How to replace orbital elements?
- Model sufficiently faithful for mission design
- Can move solutions into full JPL ephemeris
models - Key Problem How to move solutions between models?
18Coupled Restricted Three Body Problem
- Simplified Model of Solar System
- More complex than Copernican coupled two body
problems - Example Sun-Earth-Moon-Spacecraft System
- Earth-Moon-S/C LL1, LL2, LL5
- Sun-Earth-S/C EL1, EL2,
19Projection of Energy Surfaces at 4 Levels
- (a) Planet, Sun, eXterior regions separated by
grey - forbidden region
- (b) L1 energy level opens regions between P and S
- (c) L2 energy level opens regions between P, S,
and X - (d) L4 and L5 regmain trapped in grey region
20From AU to au Comets Atomic Physics
- Uncanny Similarity of Transport Theory in 3 Body
Problem - Rydberg Atom In Cross Fields
- Chemical Transition State Theory
Atomic Halo Orbit
Atomic L1
Atomic Potential Energy Surface
21Dynamical Systems Theory
22Pendulum Analogy for Conic Orbits
- The Sun-Earth-Spacecraft Three Body Problem Is
Highly Nonlinear - But Orbits Near Earth Are Stable Conics, Can
Ignore Third Body - Pendulum Is Also Nonlinear
- q - Sin( q )
- But for Small q, Pendulum Motion is Stable and
Acts Like Harmonic Oscillator - q - q
- In Both Cases, Nonlinear Effects Are Not
Noticeable, Linear Approximations Are Good
23Pendulums Special Return Orbit
- Pendulum Manifolds Provide Special Return
Orbit, Connects Inverted Pendulum Solution to
Itself - This Enables Travel Through Vast Regions of Space
with Little or No Energy - This Exploits Sensitivity of the Dynamics to
Control the Orbit with Minimal Energy - Similar to Genesis Earth Return Orbit Design
24Orbital Zoology Near the Lagrange Points
X
S Sun Region J Jupiter Region X Exterior
Region (Outside Jupiters Orbit)
S
J
- Four Families of Orbits, Conley 1968, McGehee
1969, Ref. Paper - Periodic Orbit (Planar Lyapunov)
- Spiral Asymptotic Orbit (Stable Manifold
Pictured) - Transit Orbits (MUST PASS THRU LYAPUNOV ORBIT)
- Non-Transit Orbits (May Transit After Several
Revolutions)
25Orbital Zoology Near the Lagrange Points
- Four Families of Orbits, Conley 1968, McGehee
1969, Ref. Paper - Periodic Orbit (Planar Lyapunov)
- Spiral Asymptotic Orbit (Stable Manifold
Pictured) - Transit Orbits
- Non-Transit Orbits (May Transit After Several
Revolutions)
26Stable Unstable Manifolds of Unstable Periodic
Orbits
- Unstable Periodic Orbits
- Portals to the Network
- Generate the Tubes
- Green Tube Stable Manifold
Orbits Approach the L1 Periodic Orbit, No
DV Needed - Red Tube Unstable Manifold
Orbits Leave the L1 Periodic Orbit - Systematically Map Out Orbit Space
Planet
MWL - 11
27 Poincare Sections
- Invariant Manifold Structures in Higher
Dimensions Too Complex - Poincare Sections Reduce the Dimensions by 1
- Turns Differential Equations into Maps in Phase
Space - Periodic Orbits Become Finite Number of Points
- Chaotic Orbits Cover Large Portions of Phase
Space - Reveals Resonance Structure of Phase Space
- Show the Existence of Chaos in the System
28 Mapping the Space Using Cross Sections
29Manifolds Connect Solar System
(Lo Ross)
Jupiter
- Legend
- ? Comets
- ? Asteroids
- ? Kuiper Belt
- Object
- ? L1 IPS Orbits
- ? L2 IPS Orbits
Saturn
Uranus
Neptune
30Map of the Orbital Families Near L2
Poincaré Section at L2
Simo, Gomez, Jorba, Llibre, Masdemont,
31Tori of Lissajous Orbits Immersed in
3 Space
Courtesy of Josep Maria Mandella
32Manifolds Tunneling Through Phase Space
- Cross Section of Tube Intersection Partitions
Global Behavior - Yellow Region Tunnels Through from X Through J to
S Regions - Green Circle J to S Region, Red Circle X to J
Region - Genesis-Type Trajectory Between L2 and L1 Halo
Orbits (Heteroclinic)
33(No Transcript)
34(No Transcript)
35Invariant Manifolds Jupiter Comets
- Transport Between 32 and 23 resonances
- Via heteroclinic orbits between orbits around
JL1, JL2 - Temporary Capture (Ballistic Capture)
- Koon, Lo, Marsden, Ross, 2000
- Howell, Marchand, Lo, 2000
- Belbruno, B. Marsden, 1997 WSB Theory
36Shoot the Moon! RESCUE MISSION 911 Hiten, HAC,
Discover, June 1999
37Shoot the Moon
Shoot the Moon Low Energy Transfer Ballistic
Capture
38Lunar L1 Gateway Station
JPL Lagrange Group
7/5/04
39Problem Human Service to Libration Missions
- ISSUE 3 Months Transfers to EL2 Too Long for
Humans - Short Transfers Too Difficult
- Infrastructure Too Expensive
TPF _at_Earth L2
STA-103 astronauts replaced gyros needed for
orientation of the Hubble Space Telescope.
JSC
40(No Transcript)
41Lunar L1 to Earth L2 Transfer
- Build Instruments S/C Lunar L1 Station
- Transfer S/C from L1 to Earth-L2 LIO (Libration
Oribit) - Service S/C at Earth L2 LIO from Lunar L1 Gateway
Hub
42Solution Human Servicing at Lunar L1 Gatewy
- Build Instruments S/C Lunar L1 Gateway for EL2
- Service S/C at Earth L2 from Lunar L1 Gateway
Module
ARTIST CONCEPTION
43IPS in Earths Neighborhood
- Portals/Interchange Halo Orbits, Unstable
Orbits - Lanes Invariant Manifold Tubes
ARTIST CONCEPTION
44Gateway Architecture (JSC)
GPS Constellation
Earths Neighborhood
Source James Geffre, JSC
Crew departs from and returns to ISS
L1 Gateway
Lunar Habitat
Lunar Lander
Crew Transfer Vehicle
- Crew Transfer Vehicle
- Transports crew between ISS and Gateway
- Nominal aerocapture to ISS, or direct Earth
return contingency capability
- L1 Gateway
- Gateway to the Lunar surface
- Outpost for staging missions to Moon, Mars and
telescope construction - Crew safe haven
- Lunar Lander
- Transports crew between Gateway and Lunar Surface
- 9 day mission (3 days on Lunar surface)
- Lunar Habitat
- 30-day surface habitat placed at Lunar South Pole
- Enables extended-duration surface exploration and
ops studies
45Gateway Configurations (JSC)
Source James Geffre, JSC
LEO, Transit, L1 Stand-by Configuration
Launch Configuration
Telescope Operations Configuration
Lunar Operations Configuration
46Lunar Sample Return via the Interplanetary
Supherhighway
Lunar Orbit
Goto LSR Vugraphs
JPL Caltech
8/6/2002
47New Mission Concepts Orbits