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Autonomous Large Distributed CubeSat Space Telescope (ALDCST) ASTE 527: Space Exploration Architectures Concepts Synthesis Studio Midterm Presentation October 16, 2012 Professor: Madhu Thangavelu Concept Presentation: Jesus Isarraras BACKGROUND / HISTORY • NASA – Hubble Space Telescope; ~570km LEO orbit; 2.4m mirror aperture – James Webb Space Telescope scheduled for launch in 2018; 1.5M km (Earth-Sun Lagrangian L2) orbit; 6.5m mirror aperture – Studying next generation UVOIR space observatory through the Advanced Technology Large-Aperture Space Telescope (ATLAST) • California Polytechnic State University & Stanford – Developed CubeSat Standard • Cal Tech & University of Surrey – Autonomous Assembly of a Reconfigurable Space Telescope (AAReST) Technology Development – Surrey Training Research and Nanosatellite Demonstrator (STRaND) payload development for AAReST • Naval Post Graduate School – Pseudospectral Estimation for optimal controls problems 2 RATIONALE • Develop key technologies and architectures for large space apertures to improve the capability of future imaging and sensing using CubeSat innovations http://www.jwst.nasa.gov/comparison.html 3 TIMELINE OF TECHONOLOGIES FOR ADVANCED TELESCOPES 2012 2013 2014 2015 2016 2017 2018 1Q 2Q 3Q 4Q 1Q 2Q 3Q 4Q 1Q 2Q 3Q 4Q 1Q 2Q 3Q 4Q 1Q 2Q 3Q 4Q 1Q 2Q 3Q 4Q 1Q 2Q 3Q 4Q Direct Tech Insert 2020’s JWTS Direct Tech Insert ARReST STRaND-1 STRaND-2 S-Android Logo Payload contains Google Nexus Smartphone; Nexus will fully control nanosat Kinect ATLAST-8m ATLAST-9.2m ATLAST-16m S-Android Logo Kinect Tech for 3D modeling spacial awareness 4 ASSUMPTIONS / GROUNDRULES • • • • • • • Time frame: 10 years Successful STRaND – 1 mission in 2012 Successful STRaND – 2 mission in 2014 Successful ARReST mission in 2015 Successful JWTS launch and mission in 2018 Adaptive Optics Gap size between sub-mirrors is < 0.01D; aberration is minimized 5 CONCEPT - PROPOSAL • Provide an alternative architecture for large primary mirror (D>20m) for space telescopes – Alternative for next generation UVOIR telescopes (e.g ATLAST) – CubeSat cluster with segmented mirrors – Autonomous formation and control • Potential Benefits – – – – Potential lower cost and mass Mirror segment replacement Removes human activity for fielding Faster production/manufacturing http://www.jwst.nasa.gov/comparison.html 6 CONCEPT - LOCATION • Direct extrasolar planetary observations become possible with large (D>20m) apertures – Earth-Sun Lagrangian point L2 – Opportunity to study early universe phenomena, monitor extremely faint and distant galaxies, dark matter and dark energy http://www.jwst.nasa.gov/comparison.html 7 CHALLENGES Deployable mirror segment alignment Achieving high surface accuracy of a large segmented mirror (optical figuring) Surface and structure control stabilization • Vibration isolation and potential jitter control • Control of adaptable/flexible mirrors Wavefront sensing and correction (sensors) Thermal management/distortion mitigation Power management of segmented architecture 8 COMPLEX SUBSYSTEMS Nth Layer N 2 1 1st Inner Layer (center) 2nd Inner Layer Architecture - Structure Launcher • Launcher to hold multiple layers • Layers deployed in sequence • Each layer contains 6 segments • Each segment contains N mirrors 9 COMPLEX SUBSYSTEMS Architecture - Structure Nth CubeSat Layer of Mirror Hex-Frame: provides stability and links Pod’s together Top view of Nth Layer Flexible joints connecting sat’s Top view of Nth Layer Expands to create Hexagon Shape 10 COMPLEX SUBSYSTEMS Architecture - Structure Autonomous formation • Control − ADC − Advanced algorithms (e.g PS) • Sensing − Lasers, optical, IR • Actuation − Cold Gas, PPT, Hall • Comm − Short range wireless − LOS Wireless − Laser 11 COMPLEX SUBSYSTEMS Architecture – Structure Layers Layer 1 2 3 4 5 20 50 75 100 # of Mirrors per Layer 6 12 18 24 30 120 300 450 600 Total Mirrors: Total CubeSats: Total Layers: Total Segments: Diameter 0.3 0.5 0.7 0.9 1.1 4.1 10.1 15.1 20.1 30,300 30,300 5,050 600 12 CONCEPT - COMPLEX SUBSYSTEMS Architecture – Deformable Mirror • Thin deformable mirrors with integrated actuators – >200 independent actuators – Wavefront correction for each mirror (algorithms) – Improved light gathering power – Improved resolution – Thermal management through shape/curvature correction Primary material: Polyvinylidene flouride (PVDF) 370μm http://www.kiss.caltech.edu/study/largestructure/technology.html 13 CONCEPT - COMPLEX SUBSYSTEMS Architecture – Advanced GN&C • Pseudo-spectral estimation – GN&C stability of complete cluster structure – Optimal motion planning for autonomous vehicles in obstacle rich environments – Constraint Non-Linear Problems The Zero Propellant Maneuver demonstrated on the ISS. November 5, 2006 rotated 90 deg and March 3, 2007 rotated 180 degrees Autonomous Reentry and Decent of Reusable Launch Vehicles 14 CONCEPT - EVOLUTION • • • • • • • Mirror packaging Mirror wavefront sensors Flight formation sensors Adaptive optics systems Mirror actuators CubeSat P-POD and dimension growth Instrumentation (cameras, sensors, etc) 15 CONCLUSIONS • Large apertures can be created through CubeSat Cluster design • Segmented and adaptable mirrors future of telescope design • Complex CubeSat architectures affordable options of the future 16 FUTURE QUANTITATIVE STUDY • • • • • • • • Secondary Mirror Deployment Aberration and Mirror stabilization Orbit definition Thermal management of cubesat’s and system architecture (e.g Passive – radiate heat to space vs active – refrigerator system) Sun shield technology Radiation hardening requirements Power Management Communication architecture 17 REFERENCES 1. Patterson, K., Yamamoto, N., Pellegrino, S. (2012). Thin deformable mirrors for a reconfigurable space telescope. Retrieved from http://pellegrino.caltech.edu/PUBLICATIONS/AIAA_SDM2012_1220023%20(2).pdf 2. Postman, M. (2009). Advanced Technology Large Aperture Space Telescope Study NASA. Retrieved from http://www.stsci.edu/institute/atlast/documents/ATLAST_NASA_ASMCS_Public_Report.pdf 3. Keck Institute for Space Studies. (2012)http://www.kiss.caltech.edu/lectures/index.html 4. Steeves, J., Patterson, K., Yamamoto, N., Kobilarov, M., Johnson, G., Pellegrino, S. (2012). AAReST Technology Development. Retrieved from http://kiss.caltech.edu/workshops/smallsat2012/presentations/steeves.pdf 5. Patterson, K., Pellegrino, S., Breckinridge, J. (TBD) Shape correction of thin mirrors in a reconfigurable modular space telescope. Retrieved from: http://www.kiss.caltech.edu/study/largestructure/papers/patterson-pellegrinobreckinridge.pdf 6. McClellan, J. (TBD). Aurora Flight Sciences CubeSat Cluster. Retrieved from: http://icubesat.files.wordpress.com/2012/06/icubesat-org-2012-c-3-3_presentation_mccellan_201205251247.pdf 7. Padin, S. (2003). Design Considerations for a Highly Segmented Mirror. Retrieved from: http://authors.library.caltech.edu/5664/1/PADao03b.pdf 8. Postman, M. (2007). Advanced Technology Large-Aperture Space (ATLAS) Telescope: A Technology Roadmap for the Next Decade. Retrieved from: http://www.stsci.edu/institute/atlast/documents/Submitted_proposal_TEAM_DISTN.pdf 9. Fundamental Optics. Retrieved from: http://cvimellesgriot.com/Products/Documents/TechnicalGuide/Fundamental-Optics.pdf 10. Naval Post Graduate School. (2012). Conference Papers. Retrieved from: http://www.nps.edu/academics/gnclab/Conference.html 18 Thank you for your time! Jesus Isarraras [email protected] 19 BACKUP CHARTS 20 CONCEPT - COMPLEX SUBSYSTEMS Large Space Aperture Architecture Comparison ALDCST HST JWST Herschel Space Observatory Segmented Monolithic Segmented Monolithic Primary Aperture (m) 20 2.4 / 0.3 6.5 3.5 Mirror Mass (kg) 635 (mirrors, actuators) 828 705 300 (full telescope) Wavelength (μm) .11 - 2 (UV,IR) 0.8 – 2.5 (IR) 0.1 – 0.8 (UV, visible) 0.6 to 28 (IR) 60 to 500 (IR) Earth-Sun L2 Lagrange point; 1.5 million km LEO; 570km Earth-Sun L2 Lagrange point; 1.5 million km Earth-Sun L2 Lagrange point; 1.5 million km Resolution 10 μm in IR 0.1 arcsec in red light; Main camera; 16M pixels 2 μm in IR Main camera: 32M pixels 5 – 50 arcsec Size (L x W) (m) TBD 13.2 x 4.2 22 x 12 9 x 4.5 Mission Length 10 yr? 15 5-10 yr >3 Total Dev Cost ($M) <$1B $1.5B $1B €1.1 Type of Mirror Orbit 21 Preliminary Mass Calculations • From Patterson, K., Pellegrino, S., Breckinridge, J. Shape correction of thin mirrors in a reconfigurable modular space telescope Complete mirror structure w/ areal density ~2kg/m^2: 23 COMPLEX SUBSYSTEMS Architecture - Structure Hex-Frame Contains • ADC • Comm Link Enhancement • Layer Stabilization • Network Communication 24 CONCEPT - COMPLEX SUBSYSTEMS Architecture – Secondary Mirror & Instruments 10cm 6U CubeSat Focal Plane Secondary Mirror Detector Deployer Instruments (Camera, Optical/IR Sensors, etc) 25 Formation Flying Control Challenges • Complexity – Systems of systems (interconnection/coupling) • Communication and Sensing – Limited bandwidth, connectivity, and range – What? When? To whom? – Data Dropouts, Robust degradation • Arbitration – Team vs. Individual goals • Resources – Always limited, especially on a CubeSat 26 27 28 Hubble Space Telescope • Payload: Optics: The telescope is an f/24 Ritchey-Chretien Cassegrainian system with a 2.4 m diameter primary mirror and a 0.3 m Zerodur secondary. The effective focal length is 57.6m. The Corrective Optics Space Telescope Axial Replacement (COSTAR) package is a corrective optics package designed to optically correct the effects of the primary mirror's aberration on the Faint Object Camera (FOC), Faint Object Spectrograph (FOS), and the Goddard High Resolution Spectrograph (GHRS). COSTAR displaced the High Speed Photometer during the first servicing mission to HST. Hubble Space Telescope • Instruments: The Wide Field Planetary Camera (JPL) consists of four cameras that are used for general astronomical observations from far-UV to near-IR. The Faint Object Camera (ESA) uses cumulative exposures to study faint objects. The Faint Object Spectrograph (FOS) is used to analyze the properties of celestial objects such as chemical composition and abundances, temperature, radial velocity, rotational velocity, and magnetic fields. The FOS is sensitive from 1150 Angstroms (UV) through 8000 Angstroms (near-IR). The Goddard High Resolution Spectrometer (GHRS) separates incoming light into its spectral components so that the composition, temperature, motion, and other chemical and physical properties of objects can be analyzed. The HRS is sensitive between 1050 and 3200 Angstroms.