1 / 26

To Orbit (Continued) and Spacecraft Systems Engineering

To Orbit (Continued) and Spacecraft Systems Engineering. Scott Schoneman 13 November 03. Agenda. Some brief history - a clockwork universe? The Basics What is really going on in orbit - the popular myth of zero-G Motion around a single body Orbital elements Ground tracks Perturbations

kimball
Download Presentation

To Orbit (Continued) and Spacecraft Systems Engineering

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. To Orbit (Continued) and Spacecraft Systems Engineering Scott Schoneman 13 November 03

  2. Agenda • Some brief history - a clockwork universe? • The Basics • What is really going on in orbit - the popular myth of zero-G • Motion around a single body • Orbital elements • Ground tracks • Perturbations • J2 and gravity models • Drag • “Third bodies” • Orbit Propagation

  3. Basic Orbit Equations • Circular Orbit Velocity: • Circular Orbit Period: • Escape Velocity:

  4. Perturbations: Reality is More Complicated Than Two Body Motion

  5. Orbit Perturbations • Non-spherical Earth gravity effects (i.e “J-2 Effects”) • Earth is an “Oblate Spheriod” Not a Sphere • Atmospheric Drag: Even in Space! • “Third” bodies • Other effects • Solar Radiation pressure • Relativistic Effects

  6. (Regresses West) (Regresses East) J2 Effects - Plots • J2-orbit rotation rates are a function of: • semi-major axis • inclination • eccentricity

  7. Applications of J2 Effects • Sun-synchronous Orbits • The regression of nodes matches the Sun’s longitude motion (360 deg/365 days = 0.9863 deg/day) • Keep passing over locations at same time of day, same lighting conditions • Useful for Earth observation • “Frozen Orbits” • At the right inclination, the Rotation of Apsides is zero • Used for Molniya high-eccentricity communications satellites

  8. Third-Body Effects • Gravity from additional objects complicates matters greatly • No explicit solution exists like the ellipse does for the 2-body problem • Third body effects for Earth-orbiters are primarily due to the Sun and Moon • Affects GEOs more than LEOs • Points where the gravity and orbital motion “cancel” each other are called the Lagrange points • Sun-Earth L1 has been the destination for several Sun-science missions (ISEE-3 (1980s), SOHO, Genesis, others planned)

  9. Lagrange Points Application • Genesis Mission: • NASA/JPL Mission to collect solar wind samples from outside Earth’s magnetosphere (http://genesismission.jpl.nasa.gov/) • Launched: 8 August 2001 • Returning: Sept 2004

  10. spacecraft departing planet departing sun-centric velocity hyperbolic flyby (relative to planet) planet’s orbit velocity spacecraft incoming to planet incoming sun-centric velocity Third-Body Effects: Slingshot • A way of taking orbital energy from one body ( a planet ) and giving it to another ( a spacecraft ) • Used extensively for outer planet missions (Pioneer 10/11, Voyager, Galileo, Cassini) • Analogous to Hitting a Baseball: Same Speed, Different Direction

  11. GTO orbit GEO orbit Hohmann Transfer • Hohmann transfer is the most efficient transfer (requires the least DV) between 2 orbit assuming: • Only 2 burns allowed • Circular initial and final orbits • Perform first burn to transfer to an elliptical orbit which just touches both circular orbits • Perform second burn to transfer to final circular GEO orbit Initial Circular Parking Orbit

  12. Earth-Mars Transfer • A (nearly) Hohmann transfer to Mars Mars at Spacecraft Arrival Mars at Spacecraft Departure

  13. Atmospheric Drag • Along with J2, dominant perturbation for LEO satellites • Can usually be completely neglected for anything higher than LEO • Primary effects: • Lowering semi-major axis • Decreasing eccentricity, if orbit is elliptical • In other words, apogee is decreased much more than perigee, though both are affected to some extent • For circular orbits, it’s an evenly-distributed spiral

  14. Atmospheric Drag • Effects are calculated using the same equation used for aircraft: • To find acceleration, divide by m • m / CDA : “Ballistic Coefficient” • For circular orbits, rate of decay can be expressed simply as: • As with aircraft, determining CD to high accuracy can be tricky • Unlike aircraft, determining r is even trickier

  15. Dragging Down the ISS

  16. Applications of Drag • Aerobraking / aerocapture • Instead of using a rocket, dip into the atmosphere • Lower existing orbit: aerobraking • Brake into orbit: aerocapture • Aerobraking to control orbit first demonstrated with Magellan mission to Venus • Used extensively by Mars Global Surveyor • Of course, all landing missions to bodies with an atmosphere use drag to slow down from orbital speed (Shuttle, Apollo return to Earth, Mars/Venus landers)

  17. Reentry Dynamics: Coming Back to Earth • Ballistic Reentry • Suborbital • Reentry Vehicles • Orbital • Mercury and Gemini • Skip Entry • Apollo • Gliding Entry • Shuttle

  18. “Systems” Engineering • Looking at the “Big” Picture • Requirements: What Does the Satellite Need to Do? When? Where? How? • Juggling All The Pieces • Mission Design: Orbits, etc. • Instruments and Payloads • Electronics and Power • Communications • Mass • Attitude Control • Propulsion • Cost and Schedule

  19. Mission Design • Low Earth Orbit (LEO) • Earth or Space Observation • International Space Station Support • Rendezvous and Servicing • Geosynchronous Orbit (GEO) • Communication Satellites • Weather Satellites • Earth and Space Observation • Lunar and Deep Space • Lunar • Inner and Outer Planetary • Sun Observing

  20. Spacecraft Design Considerations • Instruments and Payloads • Optical Instruments • RF Transponders (Comm. Sats) • Experiments • Electronics and Power • Solar Panels and Batteries • Nuclear Power • Communications • Uplink/Downlink • Ground Station Locations • Frequencies and Transmitter Power

  21. Spacecraft Design Considerations(Cont’d) • Mass Properties • Total Mass • Distribution of Mass (Moments of Inertia) • Attitude Control • Thrusters: Cold Gas and/or Chemical Propulsion • Gravity Gradient (Non-Spherical Earth Effect) • Spin Stablized • Magnetic Torquers • Propulsion • Orbit Maneuvering and/or Station Keeping • Chemical or ‘Exotic’ • Propellant Supply

  22. Spacecraft Design Considerations(Cont’d) • Cost and Schedule • Development • Launch • Mission Lifetime • 1 Month, 1 Year, 1 Decade?

  23. Spacecraft Integration and Test

  24. GPS Satellites • Constellation of 24 satellites in 12,000 nm orbits • First GPS satellite launched in 1978 • Full constellation achieved in 1994. • 10 Year Liftetime • Replacements are constantly being built and launched into orbit. • Weight: ~2,000 pounds • Size: ~17 feet across with the solar panels extended. • Transmitter power is only 50 watts or less.

  25. References • Orbit simulation tools: http://www.colorado.edu/physics/2000/applets/satellites.html http://home.wanadoo.nl/dms/video/orbit.html Current satellites in their orbits: NASA “JTRACK”: http://liftoff.msfc.nasa.gov/RealTime/Jtrack/3d/JTrack3D.html “Heavens Above” web page: http://www.heavens-above.com/ • Satellite Tool Kit Astronautics Primer: http://www.stk.com/resources/help/help/stk43/primer/primer.htm • Other orbital mechanics primers: http://aerospacescholars.jsc.nasa.gov/HAS/Cirr/SS/L2/orb1.htm • http://www.heavens-above.com/ • History of Orbital Mechanics: • http://es.rice.edu/ES/humsoc/Galileo/Things/ptolemaic_system.html • http://es.rice.edu/ES/humsoc/Galileo/Things/copernican_system.html • http://www-gap.dcs.st-and.ac.uk/~history/Mathematicians/Kepler.html • http://www-gap.dcs.st-and.ac.uk/~history/Mathematicians/Brahe.html • http://www-gap.dcs.st-and.ac.uk/~history/Mathematicians/Halley.html • http://www-gap.dcs.st-and.ac.uk/~history/Mathematicians/Newton.html

  26. References • Third-Body Effects • Interplanetary Superhighway Description: http://www.cds.caltech.edu/~shane/superhighway/description.html • http://www.wired.com/wired/archive/7.12/farquhar_pr.html "The Art of Falling" - about Robert Farquhar, the ISEE-3/ICE trajectory, the NEAR trajectory • Genesis mission trajectory: http://cfa-www.harvard.edu/~hrs/ay45/2001/2and3BodyOrbits.html • Texts • Spacecraft Mission Design, Brown, Charles, (AIAA): a good, compact introduction, with lots of handy formula pages • Space Mission Analysis & Design, Larson & Wertz : a good techincal introduction with lots of practical formulas, charts, and tables • Space Vehicle Design, Griffin and French, (AIAA): Good overview of all facets of space vehicles • Spaceflight Dynamics, Wiesel, W., (McGraw-Hill): Good, readable coverage of spacecraft design • Chobotov, Vladimir: Orbital Mechanics (2nd edition) (AIAA series): Classic, but dry and detailed text on many orbital mechanics topics

More Related