A deployable telescope for sub-meter resolutions from microsatellite platforms

Sub-meter resolution imagery has become increasingly important for disaster response, defence and security applications. Earth Observation (EO) at these resolutions has long been the realm of large and heavy telescopes, which results in high image costs, limited availability and long revisit times. Using synthetic aperture technology, instruments can now be developed that can reach these resolutions using a substantially smaller launch volume and mass. To obtain a competitive MicroSatellite telescope design, a concept study was performed to develop a deployable instrument that can reach a ground resolution of 25 cm from an orbital altitude of 500 km. Two classes of instruments were analysed: the Fizeau synthetic aperture, a telescope that uses a segmented primary mirror, and a Michelson synthetic aperture, an instrument concept that combines the light of a distributed array of afocal telescopes into a final image. In a trade-off the Fizeau synthetic aperture was selected as the most promising concept for obtaining high resolution imagery from a Low Earth Orbit. The optical design of the Fizeau synthetic aperture is based on a full-field Korsch telescope that has been optimized for compactness and an excellent wavefront quality. It uses three aperture segments in a tri-arm configuration that can be folded alongside the instrument during launch. The secondary mirror is mounted on a deployable boom, further decreasing the launch volume. To maintain a high image quality while operating in the harsh and dynamic space environment, one of the most challenging obstacles that must be addressed is the very tight tolerance on the positioning of the three primary mirror segments and the secondary mirror. Following a sensitivity analysis, systems engineering budgets have been defined. The instrument concept features a robust thermo-mechanical design, aimed at reducing the mechanical uncertainties to a minimum. Silicon Carbide mirror segments, the use of Invar for the deployable arms and a main housing with active thermal control, will guarantee a high thermal stability during operations. Since a robust mechanical design alone is insufficient to ensure a diffraction limited performance, an inorbit calibration system was developed. Post launch, a combination of interferometric measurements and capacitive sensors will be used to characterise the system. Actuators beneath the primary mirror segments will then correct the position of the mirror segments to meet the required operating accuracies. During operations, a passive system will be used. This system relies on a phase diversity algorithm to retrieve residual wavefront aberrations and deconvolve the image data. Using this approach, a good end-to-end imaging performance can be achieved.

[1]  Joseph M. Howard,et al.  Optical modeling activities for NASA's James Webb Space Telescope (JWST): Part V. Operational alignment updates , 2008, Astronomical Telescopes + Instrumentation.

[2]  Alex da Silva Curiel,et al.  First Year in Orbit – Results from the Beijing-1 Operational High Resolution Small Satellite , 2008 .

[3]  James R. Fienup,et al.  Remote sensing space science enabled by the multiple instrument distributed aperture sensor (MIDAS) concept , 2004, SPIE Optics + Photonics.

[4]  G. Gubbels,et al.  Melt spun aluminium alloys for moulding optics , 2013, Other Conferences.

[5]  Xing-Fei He,et al.  Time Delay Integration Speeds Up Imaging , 2012 .

[6]  David Laubier,et al.  Optical aperture synthesis: limitations and interest for the earth observation , 2017, International Conference on Space Optics.

[7]  Li Liu,et al.  Novel array configuration and its optimization for sparse aperture imaging systems , 2011 .

[8]  Y. Mellier,et al.  Euclid: Mapping the Geometry of the Dark Universe , 2012 .

[9]  D. Morris,et al.  Backthinned TDI CCD image sensor design and performance for the Pleiades high resolution Earth observation satellites , 2017, International Conference on Space Optics.

[10]  D. Martin,et al.  IXO system studies and technology preparation , 2009, Optical Engineering + Applications.

[11]  Troy E. Meink,et al.  Structural design for deployable optical telescopes , 2000, 2000 IEEE Aerospace Conference. Proceedings (Cat. No.00TH8484).

[12]  James R. Fienup,et al.  Phase retrieval for undersampled broadband images , 1999 .

[13]  Koby Smith,et al.  JWST mirror production status , 2011, Optical Engineering + Applications.

[14]  M. Erdmann,et al.  Gaia basic angle monitoring system , 2012, Optics & Photonics - Optical Engineering + Applications.

[15]  J E Harvey,et al.  Field-of-view limitations of phased telescope arrays. , 1995, Applied optics.

[16]  Robert D. Sigler,et al.  Multiple instrument distributed aperture sensor (MIDAS) science payload concept , 2004, SPIE Astronomical Telescopes + Instrumentation.

[17]  Gary H. Blackwood,et al.  Optical delay line nanometer-level pathlength control law design for space-based interferometry , 1998, Astronomical Telescopes and Instrumentation.

[18]  Thomas B. Parsonage,et al.  JWST beryllium telescope: material and substrate fabrication , 2004, SPIE Astronomical Telescopes + Instrumentation.

[19]  R. Laureijs,et al.  Euclid: ESA's mission to map the geometry of the dark universe , 2012, Other Conferences.

[20]  Brett deBlonk,et al.  Silicon Carbide Technologies for Lightweighted Aerospace Mirrors , 2008 .

[21]  James E. Harvey,et al.  Fundamental limitations on off-axis performance of phased telescope arrays , 1990, Astronomical Telescopes and Instrumentation.

[22]  Laurent M. Mugnier,et al.  Continuous High-Resolution Earth Observation with Multiple Aperture Optical Telescopes , 2005 .

[23]  B. Sedghi,et al.  E-ELT primary mirror control system , 2008, Astronomical Telescopes + Instrumentation.

[24]  James R. Fienup,et al.  Comparison of reconstruction algorithms for images from sparse-aperture systems , 2002, SPIE Optics + Photonics.

[25]  H. Philip Stahl,et al.  Enabling future space telescopes: mirror technology review and development roadmap , 2009 .

[26]  Stephen C. Unwin,et al.  Working on the Fringe: Optical and IR Interferometry from Ground and Space , 1999 .

[27]  James R. Fienup,et al.  Phase Diversity with Broadband Illumination , 2007 .

[28]  Shoushun Chen,et al.  A Time-Delay-Integration CMOS image sensor with pipelined charge transfer architecture , 2012, 2012 IEEE International Symposium on Circuits and Systems.

[29]  James R. Fienup,et al.  Optical misalignment sensing and image reconstruction using phase diversity , 1988 .

[30]  Mark S. Lake,et al.  A Revolute Joint With Linear Load-Displacement Response for Precision Deployable Structures , 1996 .

[31]  A. Labeyrie,et al.  Hypertelescopes: The Challenge of Direct Imaging at High Resolution , 2013, New Concepts in Imaging: Optical and Statistical Models.

[32]  J. Fienup,et al.  Optical wavefront measurement using phase retrieval with transverse translation diversity. , 2009, Optics express.

[33]  Glenn D. Boreman,et al.  Modulation Transfer Function in Optical and Electro-Optical Systems , 2001 .

[34]  James R. Fienup,et al.  Joint estimation of object and aberrations by using phase diversity , 1992 .

[35]  J. Goodman Introduction to Fourier optics , 1969 .

[36]  J. M. Beckers,et al.  Performance Of The Multiple Mirror Telescope (MMT) I. MMT-The First Of The Advanced Technology Telescopes , 1982, Astronomical Telescopes and Instrumentation.

[37]  Maurice Te Plate,et al.  The cryogenic refocusing mechanism of NIRSpec opto-mechanical design, analysis, and testing , 2008, Astronomical Telescopes + Instrumentation.

[38]  Michael Sholl,et al.  Comparison of on-axis three-mirror-anastigmat telescopes , 2007, SPIE Optical Engineering + Applications.

[39]  Nicholas Devaney,et al.  Status of the design and fabrication of the GTC mirrors , 2000, Astronomical Telescopes and Instrumentation.

[40]  Chein-I. Chang Hyperspectral Data Exploitation: Theory and Applications , 2007 .

[41]  L. D. Peterson,et al.  Deployable Optics for Earth Observing Lidar Instruments , 2004 .

[42]  S Lake Mark,et al.  A Deployable Primary Mirror for Space Telescopes , 1999 .

[43]  Laurent M. Mugnier,et al.  Multiple aperture optical telescopes: some key issues for earth observation from a GEO orbit , 2019, International Conference on Space Optics — ICSO 2004.

[44]  Yunjin Kim,et al.  Nuclear Spectroscopic Telescope Array (NuSTAR) Mission , 2013, 2013 IEEE Aerospace Conference.

[45]  Marvin J. Weber,et al.  Handbook of Optical Materials , 2002 .

[46]  Daniel Feuermann,et al.  First direct measurement of the spatial coherence of sunlight. , 2012, Optics letters.

[47]  David Laubier,et al.  Optical design of a Michelson wide-field multiple-aperture telescope , 2004, SPIE Optical Systems Design.

[48]  Paul A. Lightsey,et al.  Optical design and analysis of the James Webb Space Telescope: optical telescope element , 2004, SPIE Optics + Photonics.

[49]  Virendra N. Mahajan,et al.  Zernike annular polynomials for imaging systems with annular pupils , 1984 .

[50]  James R Fienup,et al.  Complex pupil retrieval with undersampled data. , 2009, Journal of the Optical Society of America. A, Optics, image science, and vision.

[51]  J R Fienup,et al.  Phase retrieval algorithms: a comparison. , 1982, Applied optics.

[52]  J. R. Nijenhuis,et al.  The opto-mechanical performance prediction of thin mirror segments for E-ELT , 2016, Integrated Modeling of Complex Optomechanical Systems.

[53]  Frederic Falzon,et al.  A New Concept of Synthetic Aperture Instrument for High Resolution Earth Observation from High Orbits , 2005 .

[54]  Bernd Harnisch,et al.  ULTRA-LIGHTWEIGHT C/SIC MIRRORS AND STRUCTURES , 1998 .

[55]  Marcel J. E. Golay,et al.  Point Arrays Having Compact, Nonredundant Autocorrelations , 1971 .

[56]  Charles M. Falco,et al.  Fabrication and characterization of beryllium-based multilayer mirrors for soft x-rays , 1992, Optics & Photonics.

[57]  R. Gerchberg A practical algorithm for the determination of phase from image and diffraction plane pictures , 1972 .

[58]  I. Glaser,et al.  Optical micro-satellite telescopes using a synthetic aperture approach for improved resolution , 2010, Optical Engineering + Applications.

[59]  Guang-ming Dai,et al.  Orthonormal polynomials in wavefront analysis: analytical solution. , 2007, Journal of the Optical Society of America. A, Optics, image science, and vision.

[60]  Hugo S Vargas SiC Design Guide: Manufacture of Silicon Carbide Products (Briefing charts) , 2010 .

[61]  B. Jurcevich,et al.  The Solar Optical Telescope for the Hinode Mission: An Overview , 2007, 0711.1715.

[62]  Gary Matthews,et al.  The Current and Future State-ofthe-art Glass Optics for Space-based Astronomical Observatories , 2009 .

[63]  M. Rohde,et al.  Metal mirrors with excellent figure and roughness , 2008, Optical Systems Design.

[64]  Tilman Werner Stuhlinger,et al.  All-reflective phased array imaging telescopes , 1991, Other Conferences.

[65]  David W. Miller,et al.  Design, Implementation and Operation of a Sparse Aperture Imaging Satellite , 2002 .

[66]  Robert A. Gonsalves,et al.  Phase Retrieval And Diversity In Adaptive Optics , 1982 .

[67]  D. Korsch Anastigmatic three-mirror telescope. , 1977, Applied optics.

[68]  David T. Leisawitz,et al.  Mirror requirements for SAFIR , 2004, SPIE Astronomical Telescopes + Instrumentation.

[69]  Laurent M. Mugnier,et al.  Imaging with multi-aperture optical telescopes and an application , 2001 .

[70]  John S. Johnson,et al.  Rapid fabrication of lightweight silicon-carbide mirrors , 2002, SPIE Optics + Photonics.

[71]  Robert K. Tyson Introduction to Adaptive Optics , 2000 .

[72]  Mary J. Edwards Current fabrication techniques for ULE and fused silica lightweight mirrors , 1998, Astronomical Telescopes and Instrumentation.

[73]  Jérôme Idier,et al.  Marginal estimation of aberrations and image restoration by use of phase diversity. , 2003, Journal of the Optical Society of America. A, Optics, image science, and vision.

[74]  Mats G. Lofdahl,et al.  Evaluation of phase-diversity techniques for solar-image restoration , 1996 .