1 / 20

Lunar Ranging Group LUNAR Team

Lunar Ranging Group LUNAR Team. Gravitational Physics Lunar Physics Lunar Laser Ranging 12 April 2011 Pasadena, California. Overall Schedule. University of Califonia , San Diego Tom Murphy Via Telephone Goddard Space Flight Centrer Stephen Merkowitz / Alix Preston Via Telephone

bisa
Télécharger la présentation

Lunar Ranging Group LUNAR Team

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. Lunar Ranging GroupLUNAR Team Gravitational Physics Lunar Physics Lunar Laser Ranging 12 April 2011 Pasadena, California

  2. Overall Schedule • University of Califonia, San Diego • Tom Murphy • Via Telephone • Goddard Space Flight Centrer • Stephen Merkowitz / Alix Preston • Via Telephone • University of Maryland, College Park • Doug Currie

  3. Decadal Survey Submissions • Astronomy and AstroPhysics Decadal Survey • Gravitational and Particle Physics Panel Report • Many Excellent Comments on the Value of LLR • Planetary Sciences Decadal Survey • Lunar Geophysical Network • Recommended for New Frontier Mission • Would Place Four Retroreflectors on the Moon

  4. murphy

  5. gsfc

  6. Topics UMd • Talks • Decadal • Computer Simulations • Result • Review Deployment & Roles • GLXP • Candidates • Functions • Deployment • Lander • Surface • Drilling • Lifetime • Murphy • Sun Shade • Dust Bombardment • Future Talks & Activities • Dust • ILRS • Status and Suggestions • Ground Stations • Tests at Frascati • NLSI • Talk • Demonstration

  7. Conference Proceedings • Currie, D. G., , the LLRRA-21/LSSO Team & the MoonLIGHT/INFN-LNF Team 2010, “A Lunar Laser Ranging RetroReflector Array for the 21st Century” 40th Lunar and Planetary Science Conference, The Woodlands, TX 1 • Currie, D. G., Zacny, K., 2010 Regolith Drilling for the Lunar Laser Ranging Retroreflector Array for the 21st Century, LUNAR Workshop, Cambridge MA • Currie, D. G., Zacny, K., the LLRRA-21/LSSO Team & the MoonLIGHT/INFN-LNF Team 2010 ”A Lunar Laser Ranging RetroReflector Array for the 21st Century” Lunar Exploration Analysis Group Washington DC. • Dell'Agnello, S., DelleMonache, G. O., Currie, D. G., et. All, G., & McElfresh D. “The Moon as a test body for General Relativity and new gravitational theories” presented at the conference European Planetary Science Congress 2010 (ESPC2010) at the Angelicum Centre – Pontifical University of Saint Thomas Aquinas, Rome, Italy. • Dell’Agnello, S. , Currie, D. G. , DelleMonacheG. O. , et al Cantone, C. Garattini, M. Martini, M. Intaglietta, N. Lops C. , March, R , Tauraso, R, Bellettini G. , Maiello, M , Berardi, S. , Porcelli, L.; "Next Generation Lunar Laser Ranging and its GNSS Applications"; IEEE Aerospace Conference, Big Sky (MT), • Peron, R.; Bellettini, G.; Berardi, S.; Boni, A.; Cantone, C.; Coradini, A.; Currie, D. G.; Dell'Agnello, S.; DelleMonache, G. O.; , et al. “Advanced instrumentation for Solar System gravitational physics” EGU General Assembly 2010, held 2-7 May, 2010 in Vienna, Austria, • Currie, D. G., DelleMonache & G. O. Dell’Agnello, S. 2010 “A Lunar Laser Retroreflector for the FOR the 21ST Century (LLRRA-21): Selenodesy, Science and Status” 2010 American Geophysical Union Fall Meeting San Francisco, CA • Currie, D. G., Dell’Agnello, S. & DelleMonache, G. O. 2011 “LUNAR LASER RANGING: FLIGHT HARDWARE SIMULATION, TESTING AND STATUS”. Lunar and Planetary Science Conference, The Woodlands, TX ,

  8. Talks, Colloquia and Public Presentations • Talks at Scientific Conferences • Currie, D. G., & the LLRRA-21 Teams 2011 “A LUNAR LASER RANGING RETRO-REFLECTOR ARRAY for the 21st CENTURY” 2nd Lunar Laser Ranging Workshop, International Space Sciences Institute, Bern Switzerland • Currie, D. G., & The LLRRA-21 Teams 2010 “A LUNAR LASER RANGING RETRO-REFLECTOR ARRAY for the 21st CENTURY” LUNAR Workshop Boulder CO • Currie, D. G., Dell’Agnello, S. & DelleMonache, G. O. 2010 A Lunar Laser Ranging Retroreflector Array for the 21st Century ISOT 2010 International Symposium on Optomechatronic Technologies, Toronto, Canada • Currie, D. G., & the LLRRA-21 Teams 2011 “A LUNAR LASER RANGING RETRO-REFLECTOR ARRAY for the 21st CENTURY” 2nd Lunar Laser Ranging Workshop, International Space Sciences Institute, Bern Switzerland • Dell’Agnello, S.; Currie, D. G.; DelleMonache, G. O.; Lops, C.; M. Martini 2010 “LLRRA21/MoonLIGHT: a 2nd Generation Lunar Laser Ranging Array for Precision Gravity Tests and Lunar Science Measurements” at the Conference Global Lunar Conference – Beijing, China. • Ddd 31 May-3 June 2010 talk • Colloquia and Public Presentations • Currie, D. G. 2011 2nd NLSI Commerce Virtual Lecture A Lunar Laser Ranging Retroreflector for the 21st Century

  9. Computer Simulations • Problems • Commercial Software Issues • Computer Failures • 300 Million Beer’s Law Calculations for Each • Computer simulation Objectives • End to End Simulation • Technical Objectives • Selection of Thermal Coatings • Effects of Shorter Sun Shade • GLXP Candidates for Size / Angular Tolerances • Eclipse Effects • For LLRRA-21, not Apollo

  10. Computer Simulations500 Time Steps Over a Lunation • HeatLoad3D • IDL – University of Maryland • Evaluates Solar Heat Loads in CCR at ~ a Million Nodes • Thermal Desktop • Commercial - Cullimorgan and Ring Technologies • Combine CCR Heat Loads with Solar Inputs to Temperature at 1733 Nodes • TempToPhase • IDL – University of Maryland • Converts Temperatures from thermal Desktop into Phase Errors • Code V • Commercial - • Combines Thermal Phase Errors with TIR Phases and Effect of Offset Angles • Analysis • IDL – University of Maryland • Converts Far Field Diffraction Patterns into Useful Operational Results

  11. Frascati Testing • Thermal Vacuum Tests • Optical Table for Far Field Diffraction Pattern • InfraRed Camera for Temperature Meaurements • Optical Simulator for “Sun” • Thermal Sensors on CCR • Images of Chamber and CCR Face

  12. Different Deployment VersionsSingle Shot Range Accuracy • Current Single Shot Accuracy is ~20 mm • If Mounted on Lander • Thermal Expansion of Lander • Heat Flux from Lander • Single Shot Accuracy of 1-3 millimeters • If a Surface Deployment • Thermal Expansion of Regolith • Heat Flux from Lander • Sub-Millimeter Single Shot Accuracy • If an Anchored Deployment • Anchored at ~1 meter depth • Better than 100 micron Single Shot Accuracy

  13. Google Lunar X Prize • Prize by Google Corporation for 30 M$ • Only Private Money for GLXP Objectives • Can Be Government Money • For Other Objectives – Like LLRRA-21 • Currently Working with: • Lunar Express, Hai Li • Astrobotics David Gump • Moon Express Bob Richards • NextGreatLeap Michael Joyce • Penn State University Miles Smith • FREDNET Sean Casey • Multiple Missions that May Be Successful • Achieve an Array of Retroreflectors

  14. Deployment Lander

  15. Surface Deployment

  16. Anchored DeploymentAstrobotics & Honeybee

  17. Lifetime of LLRRA-21 • Degradation of Laser Returns • Tom Murphy and APOLLO Station • Factor of 9.6 over 40 years • Amelioration of Problem • Sun Shade • Blocks Dust Deposition • Block Micrometeorite Bombardment • But What is the Real Reason for Degradation? • For Micrometeorite Bombardment • Test at Horanyi’s Dust Accelerator

  18. Signal Level for One LLRRA-21 • Briefly • LLRRA-21 Signal ~ Equal to Apollo 15 Array • Therefore Can Works with Sub-Meter Telescopes • Will Need to Upgrade of Laser, Timing Electronics • McDonald at 0.67 meter Currently successfully Ranges to A15 • Long Life - Dust Issues Handled with SunShade • More Precisely – IsoThermal • Station Angle LLRRA-21 Signal Return • Latitude Offsets w.r.t. A15 • 45 Yes 78% • 45 No 58% • 00 Yes 88% • 00 No 71%

  19. Future Objectives • Schedule: >> Driven by the Google Lunar X Prize Launch • April/December 2013 i.e., Astrobotics • Need to Finalize the Design • Need to Attain Sufficient TRL to Obtain Funding i.e., T/V/O Test • Need to Fabricate/Test/Integrate Flight Hardware • Simulations to Optimize Thermal Coatings • To Control Thermal Gradients and thus Signal • Optimize within Limits of Pracitical Coatings • Different Choices for Different GLXP Missions • Interactions with GLXP Teams • Each has Different Physical & Organizational Structures • Therefore Each Requires Somewhat Different Thermal Design • Each Requires Different Emplacement Procedures

  20. Future Talks & Activities • Evaluate Dust Bombardment • MihalyHoranyi – Dust Accelerator - Early May • International Laser Ranging Service Meeting – Late May • Present Status of LLRRA-21 to Actual Ranging Groups • Collect Suggestions from Operators • Present What is Needed for Ground Stations for LLRRA-21 • Thermal/Vacuum/Optical Tests at Frascati • Early June – TRL 6.5 -> TRL 7.0 • NASA Lunar Science Institute – Mid July • Talk on LLRRA-21 Hardware and GLXP Mission Status • Report on Honeybee Grant on Pneumatic Drill for LLRRA-21 • Demonstration of Pneumatic Drilling • Probably Mounted on Astrobotic Lander

More Related