DOCSLIB.ORG

A Realistic Roadmap to Formation Flying Space Interferometry

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
A Realistic Roadmap to Formation Flying Space Interferometry A Realistic Roadmap to Formation Flying Space Interferometry John Monnier, Alicia Aarnio, Olivier Absil, Narsireddy Anugu, Ellyn Baines, Amelia Bayo, Jean-Philippe Berger, L. Ilsedore Cleeves, Daniel Dale, William Danchi, et al. To cite this version: John Monnier, Alicia Aarnio, Olivier Absil, Narsireddy Anugu, Ellyn Baines, et al.. A Realistic Roadmap to Formation Flying Space Interferometry. Bulletin of the American Astronomical Society, 2019. hal-03058930 HAL Id: hal-03058930 https://hal.archives-ouvertes.fr/hal-03058930 Submitted on 12 Dec 2020 HAL is a multi-disciplinary open access L’archive ouverte pluridisciplinaire HAL, est archive for the deposit and dissemination of sci- destinée au dépôt et à la diffusion de documents entific research documents, whether they are pub- scientifiques de niveau recherche, publiés ou non, lished or not. The documents may come from émanant des établissements d’enseignement et de teaching and research institutions in France or recherche français ou étrangers, des laboratoires abroad, or from public or private research centers. publics ou privés. Astro2020 APC White Papers A Realistic Roadmap to Formation Flying Space Interferometry Type of Activity: Ground Based Project Space Based Project Infrastructure Activity Technological Development4 Activity State of the Profession Consideration4 Other Principal Author: Name: John Monnier Institution: University of Michigan Email: [email protected] Phone: 734-763-5822 Endorsers: (names, institutions, emails) Alicia Aarnio, University of North Carolina Greensboro, [email protected] Olivier Absil, University of Liege,` [email protected] Narsireddy Anugu, University of Exeter, [email protected] Ellyn Baines, Naval Research Lab, [email protected] Amelia Bayo, Universidad de Valparaiso, [email protected] Jean-Philippe Berger, Univ. Grenoble Alpes, IPAG, [email protected] L. Ilsedore Cleeves, University of Virginia, [email protected] Daniel Dale, U. Wyoming, [email protected] William Danchi, NASA Goddard Space Flight Center, [email protected] W.J. de Wit, ESO, [email protected] Denis Defrere,` University of Liege,` [email protected] Shawn Domagal-Goldman, NASA-GSFC, [email protected] Martin Elvis, CfA Harvard & Smithsonian, [email protected] Dirk Froebrich, University of Kent, [email protected] Mario Gai, Istituto Nazionale di AstroFisica,, [email protected] Poshak Gandhi, School of Physics & Astronomy, [email protected] Paulo Garcia, Universidade do Porto, Portugal, [email protected] Tyler Gardner, University of Michigan, [email protected] Douglas Gies, Georgia State University, [email protected] Jean-Franc¸ois Gonzalez, Univ Lyon, [email protected] Brian Gunter, Georgia Institute of Technology, [email protected] Sebastian Hoenig, University of Southampton, UK, [email protected] Michael Ireland, Australian National University, [email protected] Anders Jorgensen, New Mexico Institute of Mining & Tech, [email protected] Makoto Kishimoto, Kyoto Sangyo University, Japan, [email protected] 1 Lucia Klarmann, Max-Planck-Institut fur¨ Astronomie, [email protected] Brian Kloppenborg, Georgia Tech Research Institute, [email protected] Jacques Kluska, KU Leuven, [email protected] J Scott Knight, Ball Aerospace & Technologies, [email protected] Quentin Kral, Paris Observatory/Lesia, [email protected] Stefan Kraus, University of Exeter, [email protected] Lucas Labadie, University of Cologne, Germany, [email protected] Peter Lawson, Caltech, Jet Propulsion Laboratory, [email protected] Jean-Baptiste Le Bouquin, University of Michigan, [email protected] David Leisawitz, NASA GSFC, [email protected] E. Glenn Lightsey, Georgia Institute of Technology, [email protected] Hendrik Linz, MPIA Heidelberg, [email protected] Sarah Lipscy, Ball Aerospace [email protected] Meredith MacGregor, Carnegie DTM, [email protected] Hiroshi Matsuo, National Astronomical Observatory of Japan, [email protected] Bertrand Mennesson, JPL, [email protected] Michael Meyer, University of Michigan, [email protected] Ernest A. Michael, University of Chile, [email protected] Florentin Millour, Universite´ Coteˆ d’Azur, fl[email protected] David Mozurkewich, Seabrook Engineering, [email protected] Ryan Norris, Georgia State University, [email protected] Marc Ollivier, Institut d’Astrophysique Spatiale Orsay, [email protected] Chris Packham, UTSA, [email protected] Romain Petrov, Coteˆ d’Azur University, [email protected] Benjamin Pope, New York University, [email protected] Laurent Pueyo, STScI, [email protected] Sascha Quanz, ETH Zurich, [email protected] Sam Ragland, W.M. Keck Observatory, [email protected] Gioia Rau, NASA/GSFC, [email protected] Zsolt Regaly, Konkoly Observatory, [email protected] Alberto Riva, INAF - Osservatorio Astrofisico di Torino, [email protected] Rachael Roettenbacher, Yale University, [email protected] Giorgio Savini, University College London, [email protected] Benjamin Setterholm, University of Michigan, [email protected] Marta Sewilo, NASA/GSFC, University of Maryland, [email protected] Michael Smith, University of Kent, [email protected] Locke Spencer, University of Lethbridge, [email protected] Theo ten Brummelaar, CHARA - Georgia State University, [email protected] Neal Turner, Jet Propulsion Laboratory, Caltech, [email protected] Gerard van Belle, Lowell Observatory, [email protected] Gerd Weigelt, MPI for Radio Astronomy, [email protected] Markus Wittkowski, ESO, [email protected] 2 Abstract: The ultimate astronomical observatory would be a formation flying interferometer in space, immune to atmospheric turbulence and absorption, free from atmospheric and telescope ther- mal emission, and reconfigurable to adjust baselines according to the required angular resolution. Imagine the near/mid-infrared sensitivity of the JWST and the far-IR sensitivity of Herschel but with ALMA-level angular resolution, or imagine having the precision control to null host star light across 250m baselines and to detect molecules from the atmospheres of nearby exo-Earths. With no practical engineering limit to the formation’s size or number of telescopes in the array, forma- tion flying interferometry will revolutionize astronomy and this White Paper makes the case that it is now time to accelerate investments in this technological area. Here we provide a brief overview of the required technologies needed to allow light to be collected and interfered using separate spacecrafts. We emphasize the emerging role of inexpensive smallSat1 projects and the excitement for the LISA Gravitational Wave Interferometer to push development of the required engineering building-blocks. We urge the Astro2020 Decadal Survey Committee to highlight the need for a small-scale formation flying space interferometer project to demonstrate end-to-end com- petency with a timeline for first stellar fringes by the end of the decade. Caveats: The landscape of formation flying space missions is rapidly developing. In addi- tion, some important relevant past missions are not well known and often were only sparsely described with few published results. The au- thors regret the inevitable incompleteness in trying to summarize an emerging field – please contact [email protected] with corrections and additions. Key Science Goals and Objectives: Long-baseline interferometry in the in- frared and visible from the ground is now rou- tine, obtaining images of stars and their envi- ronments with milli-arcsecond angular resolu- tion, for instance rapidly-rotating stars (Mon- nier et al., 2007), magnetically-active stars (Roettenbacher et al., 2016), stars zipping around our galaxy’s supermassive black hole (Gravity Collaboration et al., 2018a), galactic Novae exploding in realtime (Schaefer et al., Figure 1: Ground-based infrared interferometry has come a long way in the past 20 years. Here we see some 2014), a quasar’s broad-line region (Gravity recent imaging results from Roettenbacher et al. (2016), Collaboration et al., 2018b), and even exo- Schaefer et al. (2014), and Gravity Collaboration et al. planet spectra directly (Gravity Collaboration (2018a), spanning stellar imaging, novae explosions, and et al., 2019). See Figure 1 for a gallery of re- stellar orbits around Sgr A* that probe General Relativ- cent interferometric imagery. ity. Note that the top two image boxes are only 3 milli- arcseconds across while the stellar orbit shown has errors 1Here, smallSats are satellites with mass <180kg, <100 micro-arcseconds. including nanosats, cubesats, microsats, minisats, etc. 3 Despite these remarkable achievements, the sensitivity of this technique2 is harshly limited by atmospheric turbulence – which restricts coherent integration times to << 1 second – and by the high price of large aperture telescopes – generally limiting most visible/IR interferometer facilities to < 1:5m telescopes presently. For example, the CHARA interferometer has a limiting magnitude K∼8 with 1.0m telescopes in the near-IR while the VLTI can reach K∼10 with the 8m UT telescopes3. ALMA has shown us the power of combining the high angular resolution imaging of interferometry with a revolutionary boost in sensitivity. Ground- based facilities have matured to the point that plan- ning can begin for the next generation of capabili- Figure 2: Space
Load more

Recommended publications
  • Tiny ASTERIA Satellite Achieves a First for Cubesats 16 August 2018, by Lauren Hinkel and Mary Knapp
    Tiny ASTERIA satellite achieves a first for CubeSats 16 August 2018, by Lauren Hinkel And Mary Knapp The ASTERIA project is a collaboration between MIT and NASA's Jet Propulsion Laboratory (JPL) in Pasadena, California, funded through JPL's Phaeton Program. The project started in 2010 as an undergraduate class project in 16.83/12.43 (Space Systems Engineering), involving a technology demonstration of astrophysical measurements using a Cubesat, with a primary goal of training early-career engineers. The ASTERIA mission—of which Department of Earth, Atmospheric and Planetary Sciences Class of 1941 Professor of Planetary Sciences Sara Seager is the Principal Investigator—was designed to demonstrate key technologies, including very Members of the ASTERIA team prepare the petite stable pointing and thermal control for making satellite for its journey to space. Credit: NASA/JPL- extremely precise measurements of stellar Caltech brightness in a tiny satellite. Earlier this year, ASTERIA achieved pointing stability of 0.5 arcseconds and thermal stability of 0.01 degrees Celsius. These technologies are important for A miniature satellite called ASTERIA (Arcsecond precision photometry, i.e., the measurement of Space Telescope Enabling Research in stellar brightness over time. Astrophysics) has measured the transit of a previously-discovered super-Earth exoplanet, 55 Cancri e. This finding shows that miniature satellites, like ASTERIA, are capable of making of sensitive detections of exoplanets via the transit method. While observing 55 Cancri e, which is known to transit, ASTERIA measured a miniscule change in brightness, about 0.04 percent, when the super- Earth crossed in front of its star. This transit measurement is the first of its kind for CubeSats (the class of satellites to which ASTERIA belongs) which are about the size of a briefcase and hitch a ride to space as secondary payloads on rockets used for larger spacecraft.
    [Show full text]
  • ASTERIA Data Guide
    ASTERIA Data Users Guide (v2) Mary Knapp November 2019 1 Overview This document describes the formatting and idiosyncrasies of ASTERIA photometric data. ASTERIA is the Arcsecond Space Telescope Enabling Research In Astrophysics. 2 Brief ASTERIA System Description ASTERIA is a 6U (10 cm x 20 cm x 34 cm) CubeSat spacecraft. ASTERIA was launched August 2017 as payload to the International Space Station and deployed into orbit on November 20, 2017. ASTERIA's current orbit matches the ISS inclination and has an average altitude of approximately 400 km. In this orbit, ASTERIA experiences an average of 30 minutes in Earth's shadow (eclipse) and 60 minutes in sunlight. ASTERIA is 3-axis stabilized via a set of reaction wheels. The reaction wheels are part of the XACT attitude control system provided by Blue Canyon Technology (BCT). Torque rods are used for reaction wheel desaturation. ASTERIA carries a small refractive telescope (f/1.4, ∼85 mm). The telescope focuses light on a 2592 x 2192 pixel CMOS detector. The detector pixels are 6.5 microns, yielding a plate scale of ∼15 arcsec/pixel. The full field of view of the detector is ∼9 x 10 degrees. ASTERIA's camera is deliberately defocused in order to oversample the PSF. 3 Definitions List of definitions for acronyms and other terms with specific meanings in the context of ASTERIA. • Epoch: The spacecraft epoch refers to the bootcount of the spacecraft. An epoch begins when ASTE- RIA's flight computer reboots and sets time to January 1, 1970 (the zero point for Unix timestamps). • Uptime: Spacecraft time is relative and is tracked in seconds from flight computer boot.
    [Show full text]
  • Exoplanet Program Analysis Group (Exopag) Report Astrophysics Advisory Committee (APAC) Meeting
    Exoplanet Program Analysis Group (ExoPAG) Report Astrophysics Advisory Committee (APAC) Meeting Victoria Meadows (ExoPAG Chair) Oct 23rd, 2018 Credit: NASA ExoPAG EC Membership Victoria Meadows (Chair) University of Washington Tom Barclay Goddard Space Flight Center Jessie Christiansen NExScI/Caltech Rebecca Jensen-Clem UC-Berkeley Tiffany Glassman Northrup Grumman Aerospace Systems Eliza Kempton University of Maryland Dimitri Mawet Caltech Michael Meyer University of Michigan Tyler Robinson Northern Arizona University Chris Stark Space Telescope Science Institute Johanna Teske Carnegie Observatories -> DTM Alan Boss (Past Chair) Carnegie Institution of Washington Martin Still (ex officio) NASA Credit: NASA Status of SAGs and SIGs Year SAG or SIG Title Lead 2018 SAG 16 Exoplanet Biosignatures (closed) Domagal-Goldman 2018 SAG 17 Community Resources Needed for K2 and TESS Planetary Candidate Confirmation Ciardi & Pepper (requesting closeout at this meeting) -- SAG 19 Exoplanet imaging signal detection theory and rigorous contrast metrics (active - Mawet & Jensen-Clem closeout expected in 2019) -- SIG 2 Exoplanet Demographics (Initiated at last meeting) Christiansen & Meyer -- SAG 20 Impact of JWST Delay on Exoplanet Science (requesting initiation at this meeting) Teske & Deming Credit: NASA ExoPAG Recent Activities • Robinson led the ExoPAG EC in agenda development for the ExoPAG19 meeting to be held in Seattle, Jan 5-6, 2019, prior to the Winter AAS. – Mini-science symposium on characterization of nearby planetary systems. – Showcase for exoplanet inputs to the Decadal Survey. • Additional call for an ExEP-funded program to support student travel to the ExoPAG19 meetings. Deadline Nov 1. Stark to administer program with ExEP. • Closeout of SAG17 presented by Ciardi to ExoPAG18 on July 29th.
    [Show full text]
  • AWS Ground Station Antenna ASTERIA AWS
    N E T 3 0 8 - R Enabling automated astrophysics with AWS Ground Station Tom Soderstrom Shayn Hawthorne CTIO, JPL Office of the CIO Senior Manager, AWS Ground Station Amazon Web Services © 2019, Amazon Web Services, Inc. or its affiliates. All rights reserved. Agenda Intro to AWS Ground Station AWS Ground Station overview – customer view Demo ASTERIA AWS Ground Station experiment AWS Ground Station • Managed ground stations • No long-term commitments required • Simple, pay-as-you-go pricing – pay by the minute • Close proximity to AWS Regions • Self-service scheduling • First-come, first- served Traditional ground station challenges • Build, lease, or rent • Large up-front capital to build • Expensive and complex to maintain • Inelastic scaling • Opaque pricing • Scheduling conflicts and contention High-level architecture Customer VPC Downlink Antenna Tracking Mission data control processing EC2 Uplink Antenna Software radio / System data recovery Digitizer / Scheduling Tracking radio Telemetry and Control Self-service and automation through AWS Console and AWS APIs/SDK AWS Security and Identity Key events • Customers configure what they want to do (Mission Profile + Configs) • Customers reserve/schedule a Contact (Mission Profile + Configs + Satellite + Ground Station + Timing) • System executes the Contact Configuration • Customers create a Mission Profile consisting of multiple Configs to configure the antenna system for a contact • Configs and Mission Profiles are created via an API Mission Profile Dataflow Dataflow Edge Tracking Config
    [Show full text]
  • Professor Sara Seager Massachusetts Institute of Technology
    Professor Sara Seager Massachusetts Institute of Technology Address: Department of Earth Atmospheric and Planetary Science Building 54 Room 1718 Massachusetts Institute of Technology 77 Massachusetts Avenue Cambridge, MA, USA 02139 Phone: (617) 253-6779 (direct) E-mail: [email protected] Citizenship: US citizen since 7/20/2010 Birthdate: 7/21/1971 Professional History 1/2011–present: Massachusetts Institute of Technology, Cambridge, MA USA • Class of 1941 Professor (1/2012–present) • Professor of Planetary Science (7/2010–present) • Professor of Physics (7/2010–present) • Professor of Aeronautical and Astronautical Engineering (7/2017–present) 1/2007–12/2011: Massachusetts Institute of Technology, Cambridge, MA USA • Ellen Swallow Richards Professorship (1/2007–12/2011) • Associate Professor of Planetary Science (1/2007–6/2010) • Associate Professor of Physics (7/2007–6/2010) • Chair of Planetary Group in the Dept. of Earth, Atmospheric, and Planetary Sciences (2007–2015) 08/2002–12/2006: Carnegie Institution of Washington, Washington, DC, USA • Senior Research Staff Member 09/1999–07/2002: Institute for Advanced Study, Princeton NJ • Long Term Member (02/2001–07/2002) • Short Term Member (09/1999–02/2001) • Keck Fellow Educational History 1994–1999 Ph.D. “Extrasolar Planets Under Strong Stellar Irradiation” Department of Astronomy, Harvard University, MA, USA 1990–1994 B.Sc. in Mathematics and Physics University of Toronto, Canada NSERC Science and Technology Fellowship (1990–1994) Awards and Distinctions Academic Awards and Distinctions 2018 American Philosophical Society Member 2018 American Academy of Arts and Sciences Member 2015 Honorary PhD, University of British Columbia 2015 National Academy of Sciences Member 2013 MacArthur Fellow 2012 Raymond and Beverly Sackler Prize in the Physical Sciences 2012 American Association for the Advancement of Science Fellow 2007 Helen B.
    [Show full text]
  • Big Exoplanet Science with Small Satellites David R
    Big Exoplanet Science with Small Satellites David R. Ardila1, Varoujan Gorgian1, Mark Swain1, Michael Saing1 Competitive exoplanet science can be done with small telescopes: consortiums like KELT and WASP (transits), MINERVA (radial velocity and transits), OGLE (microlensing), and many others, demonstrate the power of dedicated ground facilities with small apertures to advance the field. Dedicated observations from space with small satellites (SmallSats) would allow dedicated continuous observing, with darker backgrounds, at wavelengths not reachable from the ground. Here we describe some of current and planned SmallSat missions for exoplanet science. The community has produced a number of concept studies that we use to illustrate their potential. With the promise of lower cost, the use of new technology, shorter development times, and frequent access to space, SmallSats provide unique opportunities to advance exoplanet science. What is a Small Satellite? We define a SmallSat as having mass ≤180 kg. The limit comes from the capabilities of the Evolved Expendable Launch Vehicle (EELV) Secondary Payload Adapter (ESPA). Then, another possible definition is a satellite small enough to be a secondary payload. At the upper mass end, a SmallSat will have payload dimensions close to ~50 cm x 50 cm x 50 cm, and will fit a 30-40 cm diameter telescope. At the lower end, the Breakthrough Starshot recently launched six 4 grams satellites (Crane 2017). For comparison, the Galaxy Evolution Explorer (GALEX), had a mass of 277 kg and a telescope diameter of 50 cm (NASA 2003). By this writing, NASA’s Astrophysics Division has never launched a SmallSat, although four CubeSats are planned, two of those for exoplanet science.
    [Show full text]
  • Enabling and Enhancing Astrophysical Observations with Autonomous Systems
    Enabling and Enhancing Astrophysical Observations with Autonomous Systems Rashied Amini1;a, Steve Chien1, Lorraine Fesq1, Jeremy Frank2 , Ksenia Kolcio3, Bertrand Mennsesson1, Sara Seager4, Rachel Street5 July 10, 2019 Endorsements Patricia Beauchamp1, John Day1, Russell Genet6, Jason Glenn7, Ryan Mackey1, Marco Quadrelli1, Rebecca Ringuette8, Daniel Stern1, Tiago Vaquero1 1NASA Jet Propulsion Laboratory 2NASA Ames Research Center 3Okean Solutions 4 arXiv:2009.07361v1 [astro-ph.IM] 15 Sep 2020 Massachusetts Institute of Technology 5Las Cumbres Observatory 6California Polytechnic State University 7University of Colorado at Boulder 8University of Iowa a [email protected] c 2019 California Institute of Technology. Government sponsorship acknowledged. 1 Executive Summary Servicing is a legal requirement for WFIRST Autonomy is the ability of a system to achieve and the Flagship mission of the 2030s [5], yet goals while operating independently of exter- past and planned demonstrations may not pro- nal control [1]. The revolutionary advantages vide sufficient future heritage to confidently meet of autonomous systems are recognized in nu- this requirement. In-space assembly (ISA) is cur- merous markets, e.g. automotive, aeronautics. rently being evaluated to construct large aper- Acknowledging the revolutionary impact of au- ture space telescopes [6]. For both servicing and tonomous systems, demand is increasing from ISA, there are questions about how nominal op- consumers and businesses alike and investments erations will be assured, the feasibility of teleop- have grown year-over-year to meet demand. In eration in deep space, and response to anomalies self-driving cars alone, $76B has been invested during robotic operation. from 2014 to 2017 [2]. In the previous Planetary The past decade has seen a revolution in Science Decadal, increased autonomy was identi- the access to space, with low cost launch ve- fied as one of eight core multi-mission technolo- hicles, commercial off-the-shelf technology, and gies required for future missions [3].
    [Show full text]
  • Juliette's CV
    Juliette Becker Department of Geological and Planetary Sciences • Caltech • Pasadena, CA 91125 [email protected] • jcbastronomy.com • @jcbastro Research Interests / Goals My major goal in my research is to understand planet formation through studying the boundary conditions of the processes that allow planetary systems to assemble. Appointments 51 Pegasi b Postdoctoral Fellow, Caltech Sept. 2019 - present Postdoctoral Scholar (funded by Leinweber Fellowship), University of Michigan Summer 2019 Education University of Michigan Ann Arbor, MI M.S. in Astronomy and Astrophysics August 2016 PhD in Astronomy and Astrophysics (advisor: Fred Adams) May 2019 California Institute of Technology Pasadena, CA B.S. Astrophysics with honor and a minor in English September 2010 - June 2014 Awards Ralph B. Baldwin Prize in Astronomy 2021 2019 ProQuest Distinguished Dissertation Award 2020 51 Pegasi b Fellowship 2019 Leinweber Center for Theoretical Physics Graduate Fellowship 2018 University of Michigan Aspire, Advance, Achieve Mentoring Award (Nominee) 2018 DPS Bill Hartmann Student Travel Grant 2017 K2SciCon Student Travel Award 2015, 2019 DDA/AAS Raynor L. Duncombe Prize for Student Research 2015 National Science Foundation Graduate Research Fellowship 2014-2019 Chambliss Astronomy Achievement Student Awards, honorable mention 2014 Golden Ankle Dedication and Leadership Award (Caltech) 2011, 2013, 2014 Richter Scholar, Summer Undergraduate Research Fellow (Caltech) 2013 Celia Peterson Leadership Award (Caltech) 2012, 2013 Alain Porter Memorial Summer Undergraduate Research Fellow (Caltech) 2012 ARCS (Achievement Rewards for College Scientists) Fellowship 2012, 2013, 2014 SCIAC Scholar-Athlete Award 2011, 2012, 2013, 2014 Lingle Merit Award (Caltech) 2011 Peer Reviewed Publications 38 total: 11 first author, 8 second author, h-index = 18, total citations ∼ 895 First Author Publications: 38.
    [Show full text]
  • Exoplanet Detection Yield of a Space-Based Bracewell Interferometer from Small to Medium Satellites
    Exoplanet detection yield of a space-based Bracewell interferometer from small to medium satellites Colin Dandumont,a,* Denis Defrère,a Jens Kammerer,b,c Olivier Absil,d Sascha P. Quanz,e and Jérôme Loicqa aUniversité de Liège, Centre Spatial de Liège, Liège, Belgium bEuropean Southern Observatory, Garching, Germany cAustralian National University, Research School of Astronomy and Astrophysics, Canberra, Australian Capital Territory, Australia dUniversity of Liège, Space Sciences Technologies, Astrophysics Research Institute, Liège, Belgium eETH Zurich, Institute for Particle Physics and Astrophysics, Zurich, Switzerland Abstract. Space-based nulling interferometry is one of the most promising solutions to spec- trally characterize the atmosphere of rocky exoplanets in the mid-infrared (3 to 20 μm). It pro- vides both high angular resolution and starlight mitigation. This observing capability depends on several technologies. A CubeSat (up to 20 kg) or a medium satellite (up to a few hundreds of kg), using a Bracewell architecture on a single spacecraft could be an adequate technological pre- cursor to a larger, flagship mission. Beyond technical challenges, the scientific return of such a small-scale mission needs to be assessed. We explore the exoplanet science cases for various missions (several satellite configurations and sizes). Based on physical parameters (diameter and wavelength) and thanks to a state-of-the-art planet population synthesis tool, the performance and the possible exoplanet detection yield of these configurations are presented. Without con- sidering platform stability constraints, a CubeSat (baseline of b ≃ 1mand pupils diameter of D ≃ 0.1 m) could detect ≃7 Jovian exoplanets, a small satellite (b ≃ 5m∕D ≃ 0.25 m) ≃120 exoplanets, whereas a medium satellite (b ≃ 12.5 m∕D ≃ 0.5 m) could detect ∼250 exoplanets including 51 rocky planets within 20 pc.
    [Show full text]
  • Two-Stage Attitude Control for Direct Imaging of Exoplanets with a Cubesat Telescope
    Two-Stage Attitude Control for Direct Imaging of Exoplanets with a CubeSat Telescope Connor Beierlea, Andrew Nortonb, Bruce Macintoshb, and Simone D'Amicoa aSpace Rendezvous Laboratory, Stanford University, Stanford, CA bKavli Institute for Particle Astrophysics and Cosmology, Stanford University, Stanford, CA ABSTRACT This work outlines the design and development of a prototype CubeSat space telescope to directly image exo- planets and/or exozodiacal dust. This prototype represents the optical payload of the miniaturized distributed occulter/telescope (mDOT), a starshade technology demonstration mission combining a 2 meter scale microsatel- lite occulter and a 6U CubeSat telescope. Science requirements for the mDOT experiment are presented and translated into engineering requirements for the attitude determination and control subsystem (ADCS). The ADCS will utilize a triad of reaction wheels for coarse pointing and a tip tilt mirror for fine image stabilization down to the sub-arcsecond level. A two-stage attitude control architecture is presented to achieve precise point- ing necessary for stable acquisition of diffraction limited imagery. A multiplicative extended Kalman filter is utilized to estimate the inertial attitude of the vehicle and provide input into the aforementioned controller. A hardware-in-the-loop optical stimulator is used to stimulate the payload with scenes highly representative of the space environment from a radiometric and geometric stand point. Scenes rendered to the optical stimulator are synthesized in closed-loop based off a high-fidelity numerical simulation of the underlying disturbances, orbital and attitude dynamics. Performance of the two-stage attitude control loop is quantified and demonstrates the ability to achieve sub-arcsecond pointing using a telescope payload prototype.
    [Show full text]
  • Small Satellite Earth-To-Moon Direct Transfer Trajectories Using the CR3BP
    Scholars' Mine Masters Theses Student Theses and Dissertations Fall 2019 Small satellite earth-to-moon direct transfer trajectories using the CR3BP Garrett Levi McMillan Follow this and additional works at: https://scholarsmine.mst.edu/masters_theses Part of the Aerospace Engineering Commons Department: Recommended Citation McMillan, Garrett Levi, "Small satellite earth-to-moon direct transfer trajectories using the CR3BP" (2019). Masters Theses. 7920. https://scholarsmine.mst.edu/masters_theses/7920 This thesis is brought to you by Scholars' Mine, a service of the Missouri S&T Library and Learning Resources. This work is protected by U. S. Copyright Law. Unauthorized use including reproduction for redistribution requires the permission of the copyright holder. For more information, please contact [email protected]. SMALL SATELLITE EARTH-TO-MOON DIRECT TRANSFER TRAJECTORIES USING THE CR3BP by GARRETT LEVI MCMILLAN A THESIS Presented to the Graduate Faculty of the MISSOURI UNIVERSITY OF SCIENCE AND TECHNOLOGY In Partial Fulfillment of the Requirements for the Degree MASTER OF SCIENCE in AEROSPACE ENGINEERING 2019 Approved by: Dr. Henry Pernicka, Advisor Dr. David Riggins Dr. Serhat Hosder Copyright 2019 GARRETT LEVI MCMILLAN All Rights Reserved iii ABSTRACT The CubeSat/small satellite field is one of the fastest growing means of space exploration, with applications continuing to expand for component development, commu- nication, and scientific research. This thesis study focuses on establishing suitable small satellite Earth-to-Moon direct-transfer trajectories, providing a baseline understanding of their propulsive demands, determining currently available off-the-shelf propulsive technol- ogy capable of meeting these demands, as well as demonstrating the effectiveness of the Circular Restricted Three Body Problem (CR3BP) for preliminary mission design.
    [Show full text]
  • Changes to the Database for May 1, 2021 Release This Version of the Database Includes Launches Through April 30, 2021
    Changes to the Database for May 1, 2021 Release This version of the Database includes launches through April 30, 2021. There are currently 4,084 active satellites in the database. The changes to this version of the database include: • The addition of 836 satellites • The deletion of 124 satellites • The addition of and corrections to some satellite data Satellites Deleted from Database for May 1, 2021 Release Quetzal-1 – 1998-057RK ChubuSat 1 – 2014-070C Lacrosse/Onyx 3 (USA 133) – 1997-064A TSUBAME – 2014-070E Diwata-1 – 1998-067HT GRIFEX – 2015-003D HaloSat – 1998-067NX Tianwang 1C – 2015-051B UiTMSAT-1 – 1998-067PD Fox-1A – 2015-058D Maya-1 -- 1998-067PE ChubuSat 2 – 2016-012B Tanyusha No. 3 – 1998-067PJ ChubuSat 3 – 2016-012C Tanyusha No. 4 – 1998-067PK AIST-2D – 2016-026B Catsat-2 -- 1998-067PV ÑuSat-1 – 2016-033B Delphini – 1998-067PW ÑuSat-2 – 2016-033C Catsat-1 – 1998-067PZ Dove 2p-6 – 2016-040H IOD-1 GEMS – 1998-067QK Dove 2p-10 – 2016-040P SWIATOWID – 1998-067QM Dove 2p-12 – 2016-040R NARSSCUBE-1 – 1998-067QX Beesat-4 – 2016-040W TechEdSat-10 – 1998-067RQ Dove 3p-51 – 2017-008E Radsat-U – 1998-067RF Dove 3p-79 – 2017-008AN ABS-7 – 1999-046A Dove 3p-86 – 2017-008AP Nimiq-2 – 2002-062A Dove 3p-35 – 2017-008AT DirecTV-7S – 2004-016A Dove 3p-68 – 2017-008BH Apstar-6 – 2005-012A Dove 3p-14 – 2017-008BS Sinah-1 – 2005-043D Dove 3p-20 – 2017-008C MTSAT-2 – 2006-004A Dove 3p-77 – 2017-008CF INSAT-4CR – 2007-037A Dove 3p-47 – 2017-008CN Yubileiny – 2008-025A Dove 3p-81 – 2017-008CZ AIST-2 – 2013-015D Dove 3p-87 – 2017-008DA Yaogan-18
    [Show full text]