6th European CubeSat Symposium 14 – 16 October 2014 Estavayer-le-Lac, Switzerland Book of Abstracts Sponsors: 2 Table of Contents Foreword……………………………………………………………………………………..... 3 Organisational details………………………………………………………………......... 4 Programme........................................................................................ 7 Scientific instruments/sensors on CubeSats........................................... 14 Micropropulsion Systems……………………................................................ 30 CubeSat Launchers and Deployers………………………………....................... 35 Technology Demonstration on CubeSats............................................... 39 Telecommunications, Ground Stations, Ground Station Networks…………. 47 CubeSat Flight Experience, Lessons Learned………….............................. 58 Orbital Dynamics, De-orbiting and Debris Mitigation Techniques............. 67 CubeSat Networks and Constellations, Formation Flying......................... 73 Attitude Determination and Control ……………........................................ 77 Future Technologies on CubeSats....................................................... 87 Posters............................................................................................... 94 3 Foreword When the European CubeSat Symposium was first organised, CubeSats were seen as dominantly educational tools that served for the training of university students. Today, while we are organising the 6th European CubeSat Symposium, we are also congratulating hundreds of CubeSats launched to orbit. Only in 2014, two spectacular launch campaigns have been performed: First, 33 CubeSats were launched in January 2014, and then 24 others in June 2014. A significant number of these CubeSats were developed by Planet Labs for commercial Earth Observation purposes, showing that CubeSats are now used for commercial, scientific and technology demonstration reasons, in addition to being educational tools. Launching of CubeSats from the International Space Station has been another recent pioneering step. In addition to the classical 1, 2U and 3U concepts, we also started seeing designs of bigger nano and micro satellites based on 6U and 12U CubeSat concepts. The CubeSat community is growing fast parallel to all these developments. The 6th European CubeSat Symposium has attracted full attention from the community with more than 100 abstracts submitted from 31 different countries. Von Karman Institute and Swiss Space Systems are proud to support the CubeSat community by coorganising this leading CubeSat event in Europe, for the first time in Switzerland. Von Karman Institute continues to act as the coordinator of the World's most ambitious CubeSat Project QB50, whereas Swiss Space Systems is designing an innovative launcher specifically for small satellites to bring the launch costs to 25% of today's market value. We are very happy to have contributed to this year's CubeSat Symposium where 70 oral presentations will be given in 11 different sessions. 8 industrial companies will be presenting their products and solutions in a parallel industry session and at the industrial exhibit. 19 posters will take place in the poster sessions, waiting for detailed discussions during coffee breaks, lunch and reception. The event is fully booked and we are expecting more than 200 participants. The 6th European CubeSat Symposium has been a great success so far by attracting several sponsors such as the European Space Agency, Tyvak Nano Satellite Systems Inc, Journal of Small Satellites, Swiss Space Systems, ClydeSpace and Aeropole/COREB to sponsor more than 12 participants. Another interesting number is the 9 presentations in the “CubeSat Flight Experience, Lessons Learned” session, which is attracting more and more presentations every year. We wish you a very successful Symposium and look forward to meeting you again next year at the 7th European CubeSat Symposium. Pascal Jaussi Jean Muylaert CEO Director Swiss Space Systems von Karman Institute 4 Organisational details Access to the premises The Symposium takes place at the Théâtre de la Prillaz, in the city of Estavayer-le-Lac in Switzerland. The open address is: Chaussée des Autrichiens 15 CH-1470 Estavayer-le-Lac Switzerland Estavayer-le-Lac is a town on the eastern coast of the Lake of Neuchatel. It has direct train connections to bigger cities such as Yverdon and Fribourg. The closest airport is the Airport of Geneva. The train connections can be checked and tickets can be purchased at http://www.sbb.ch/en/ There will be shuttle services between the Symposium venue and the train station of Estavayer-leLac, as well as between the Symposium venue and Hotel Park Inn Lully. There is a big parking place at the Symposium venue for those who travel by car. 5 Registration The registration desk will be open at the entrance of the Symposium venue from 08.45 to 09.45. However, late arriving participants can still register. Participants will be asked to pay a modest registration fee of 250 € to cover the expenses for lunches and coffee breaks on three days and for drinks and snacks during the reception. Oral presentations, proceedings Speakers will not be allowed to use their own computer during their talk, but must transfer their presentation in PDF or PPT PowerPoint to the Symposium Secretary ([email protected]) by email or by USB flash drive, preferably half a day before the presentation. There will be no printed Symposium proceedings, only the abstracts will be published. The slides of all presentations will be made available after 20 October 2014 on the Symposium website. Posters The size of the area available for poster presentation is 120 x 85 cm. A1 size posters can be exhibited during the Symposium. The accepted participants can bring their own posters or the posters can be printed by Swiss Space Systems in advance (this should be the exception). Poster mounting will be possible on 14 October 2014 from 08.30 until 11.30. Standard materials for poster mounting will be available in the poster area, where the coffee breaks and receptions will be held. Poster authors are expected to be present at that time next to their posters, to be available to answer questions and have discussions with Symposium participants. Industrial exhibits There will be industrial exhibits by the following companies: Blue Canyon Technologies, USA Bright Ascension, UK Clyde Space, UK GomSpace, Denmark GOSMOZ, Switzerland Innovative Solutions in Space, Netherlands Tyvak Nano-Satellite Systems, USA Observatoire de Versailles Saint-Quentin-en-Yvelines (OVSQ), France The industrial exhibits will take place in the poster/coffee/reception area. Lunch breaks The lunch break is between 12.30 and 14.00 every day. Coffee breaks The times for morning and afternoon coffee breaks are indicated in the programme. The participants will also have the possibility to purchase beverages and drinks outside the coffee breaks. Reception On the first day of the Symposium, from 19.00 to 20.30, a reception will take place in the poster/coffee/reception area (kindly sponsored by Aeropole.ch). A goodbye drink will be held at the last day of the Symposium (kindly sponsored by ClydeSpace). 6 International Scientific Committee W. Balogh (UN) R. Walker (ESA) O. Koudelka (Austria) J. Muylaert (Belgium) J. Thoemel (Belgium) J. F. Dalsgaard Nielsen (Denmark) K. Briess (Germany) R. Reinhard (Germany) E. Gill (Netherlands) J. Rotteveel (Netherlands) T. Masson-Zwaan (Netherlands) S.R. Cunha (Portugal) V. Gass (Switzerland) P. Jaussi (Switzerland) V.I. Mayorova (Russia) D. Kataria (United Kingdom) G. Shirville (United Kingdom) T. Morgensen (USA) S. Palo (USA) Symposium Secretaries: C. O. Asma, Swiss Space Systems D. Masutti, von Karman Institute P. Testani, von Karman Institute 7 Programme Tuesday, 14 October 2014 08.45 – 09.45 Registration, Coffee 09.45 – 10.00 Welcome (C. Leu and J. Thoemel) and Opening Speech: Micro, Nano and Small Satellites in the context of the Swiss Space Policy (J. Richard – Swiss Space Office) 10.00 – 10.15 Practical Information (C.O. Asma) Scientific Instruments/Sensors on CubeSats Chair: D. Masutti 10.15 – 10.30 Interfacing with the science unit: Preparing the software side (R. A. de Carvalho et al.) 10.30 – 10.45 The FIRST-S Project : the science case (S. Lacour et al.) 10.45 – 11.00 Antenna development for the Wideband Ionospheric Sounder CubeSat Experiment (WISCER) (G. C. Kirkby and M. J. Angling) 11.00 – 11.15 A compact ion and neutral mass spectrometer for the ExoCube Mission (N. Paschalidis et al.) 11.15 – 11.30 The PIC.A.S.S.O. mission: A PICo-satellite for Atmospheric and Space Science Observations (D. Fussen et al.) 11.30 – 11.45 Solar EUV Probe on QB50/PHOENIX CubeSat (J. C. Juang et al.) 11.45 – 12.00 CubeSat-ready radiation monitor front-end electronics (T. A. Stein) 12.00 – 12.15 Wavelet transform as an efficient and effective tool for electromagnetic emission measurements in space plasma (T. Szewczyk et al.) 12.15 – 12.30 On feasibility of Global Radio Frequency Interference measurement with CubeSats (J. Praks et al.) __________________________________________________________________________________ 12.30 – 14.00 Lunch break __________________________________________________________________________________ 8 Scientific Instruments/Sensors on CubeSats (continued) Chair: A. Ridley 14.00 – 14.15 Doing Science with university Cubesats: Present and future (T. Moretto Jorgensen) 14.15 – 14.30 The micro solar-flare apparatus (MiSolFA) (D. Casadei) 14.30 – 14.45 Mapping the radiation environment in equatorial low earth orbit with CubeSats (E. Del Monte et al.) 14.45 – 15.00 From the low cost to the high benefits. The outreach of small satellites instrumentation (M.D. Michelena ) 15.00 – 15.15 A CubeSat for X-ray polarimetry in astrophysics (P. Soffitta et al.) 15.15 – 15.30 Evaluation of the performances of a spectro imaging detector (CALISTE) to be embedded on board a nanosatellite for Solar Flares studies (H. Triou et al.) __________________________________________________________________________________ 15.30 – 16.00 Coffee break __________________________________________________________________________________ Micropropulsion Subsystems Chair: M. Richard 16.00 – 16.15 A highly miniaturized uPPT thruster for attitude-orbit control (J. Li et al.) 16.15 – 16.30 Solid cool gas micro propulsion system for CubeSat (P. Zhu et al.) 16.30 – 16.45 Solid propellant micro-thruster array for CubeSat (X. Liu et al.) 16.45 – 17.00 Development status of an open capillary pulsed plasma thruster with non-volatile liquid propellant (E. Remírez et al.) CubeSat Launchers and Deployers Chair: M. Richard 17.00 – 17.15 Reliable low-cost accesses to space for CubeSat size payloads (P. C. Steimle et al.) 17.15 – 17.30 On-orbit optimization of CubeSat launch opportunities using an orbital maneuvering vehicle (M. Stender et al.) 17.30 – 17.45 Swiss Space Systems innovative launch concept for small satellites (B. Deper et al.) 9 18.00 – 19.00 Round Table Discussions: Innovation in Space Beat Vonlanthen, President, State of Fribourg Pascal Jaussi, CEO & Founder, Swiss Space Systems Clément Leu, Director of Education & Outreach, Swiss Space Systems __________________________________________________________________________________ 19.00 – 20.30 WELCOME RECEPTION (kindly sponsored by Aeropole.ch) __________________________________________________________________________________ 10 Wednesday, 15 October 2014 Technology Demonstration on CubeSats Chair: A. Denis 08.45 – 09.00 Space object detection on a CubeSat platform (M. Tetlow et al.) 09.00 – 09.15 The Multi-Payload Satellite Service (MPS) for in-orbit technology evaluation (L. León et al.) 09.15 – 09.30 SamSat–QB50 nanosatellite: Burning wires mechanism for antenna system and aerodynamic stabilizer (E. Ustiugov et al.) 09.30 – 09.45 Testing of low-cost GNSS receivers for CubeSat orbit and attitude determination (C. Hollenstein et al.) 09.45 – 10.00 QARMAN: As an Atmospheric Entry Experiment on CubeSat Platform (E. Umit et al.) 10.00 – 10.15 A thermal protection system for a re-entry CubeSat (P. Testani et al.) 10.15 – 10.30 A tool for nano-satellite functional verification: comparison between different inthe-loop simulation configurations (L. Feruglio et al.) __________________________________________________________________________________ 10.30 – 11.00 Coffee break __________________________________________________________________________________ 11.00 – 11.30 Invited Presentation: CubeSat Missions at Morehead State University - From LEO to Lunar (Dr. Benjamin K. Malphrus, Director of the Space Science Center, Morehead State University) Telecommunications, Ground Stations, Ground Station Networks Chair: A. Denis 11.30 – 11.45 Development of an open source software defined radio (M. Wegerson et al.) 11.45 – 12.00 CubETH COM subsystem (F. Belloni et al.) 12.00 – 12.15 Enhancements of antenna control and an error correction scheme for the CubETH Ground Station (S. Kaufmann et al.) 12.15 – 12.30 SUSat communications system (W.G. Cowley et al.) __________________________________________________________________________________ 12.30 – 14.00 Lunch break __________________________________________________________________________________ 11 Telecommunications, Ground Stations, Ground Station Networks (continued) Chair: M. Joss 14.00 – 14.15 Antenna subsytem of GAMALINK platform (V. Akan and C. Dudak) 14.15 – 14.30 A simple miniaturized printed antenna adaptation for CubeSats and small satellites (S. Kose et al.) 14.30 – 14.45 Development of an x-band transmitter for CubeSats (S. Palo et al.) 14.45 – 15.00 Multi-objective optimization of a high gain, circularly polarized rectangular antenna array in the Ka band for CubeSat class satellites (A. Cuttin et al.) 15.00 – 15.15 KSAT light – a low cost ground station network for Cubesats (B. Eilertsen and M. Krynitz) 15.15 – 15.30 Challenges and solutions for the QB50 telecommunication network (G. March et al.) __________________________________________________________________________________ 15.30 – 16.00 Coffee break __________________________________________________________________________________ CubeSat Flight Experience, Lessons Learned Chair: J. Thoemel 16.00 – 16.15 Lessons learned from four months of UKube-1 in orbit: A software perspective (P. Mendham and M. McCrum) 16.15 – 16.30 The QB50 precursor flight: Lessons learned (J. Elstak et al.) 16.30 – 16.45 QB50 precursor ADCS flight results (L. Visagie et al.) 16.45 – 17.00 A worldwide survey on the regulatory and economical aspects of nano-satellites (S. Cabrera et al.) 17.00 – 17.15 LituanicaSAT-1: lessons learned from the first Lithuanian cubesat mission (L. Maciulis et al.) 17.15 – 17.30 Lessons learned from developing and producing structure and mechanical systems for ESTCube-1 (P. Liias et al.) 17.30 – 17.45 Legal Aspects on CubeSats and Space Debris Issues (N. Antoni) 17.45 – 18.00 E-st@r-I lessons learned and their application (G. Obiols-Rabasa et al.) 12 Thursday, 16 October 2014 Orbital Dynamics, De-Orbiting and Debris Mitigation Techniques Chair: S. Palo 08.30 – 08.45 The Aerospace Blockset for Xcos (P. Zagórski) 08.45 – 09.00 LitSat-1 decay analysis (V.Tomkus et al.) 09.00 – 09.15 In orbit testing of a de-orbiting sail on the Cubesat URSA MAIOR (M. Valdatta et al.) 09.15 – 09.30 A tether-based aerodynamic de-orbiting system (O. Vallet and C.O. Asma) 09.30 – 09.45 De-risking active debris removal with CubeSat in-orbit demonstrations (M. Richard et al.) CubeSat Networks and Constellations, Formation Flying Chair: S. Palo 09.45 – 10.00 Space-based ad hoc network: a solution for multiple satellite TT&C problem in QB50 project (P .Liu et al.) 10.00 – 10.15 TW-1: A Cubesat constellation for space networking experiments (S. Wu et al.) 10.15 – 10.30 Status of the QB50 Project (J. Thoemel et al.) __________________________________________________________________________________ 10.30 – 11.00 Coffee break __________________________________________________________________________________ 11.00 – 11.30 Invited Presentation: Market Evolution and Commercialization of CubeSats (Dr. Marco Villa, President and COO of Tyvak Nano-Satellite Systems, Inc.) Attitude Determination and Control Subsystem Chair: J. Praks 11.30 – 11.45 Aalto-1 nanosatellite attitude determination and control system end-to-end testing (T. Tikka et al.) 11.45 – 12.00 Star tracker cost reduction for small satellites (T. Delabie et al.) 12.00 – 12.15 ZA-AeroSat: A QB50 CubeSat demonstrator for multidisciplinary technology and scientific research (M. Kearney and W.H. Steyn) 12.15 – 12.30 Attitude control simulation using variable speed CMG for 3U CubeSat (H. Kim et al.) __________________________________________________________________________________ 12.30 – 14.00 Lunch break __________________________________________________________________________________ 13 Attitude Determination and Control Subsystem (continued) Chair: R. Atem de Carvalho 14.00 – 14.15 The piNAV-L1 – The World’s first ultra low power CubeSat GNSS receiver (J. Laifr) 14.15 – 14.30 In-house magnetic field simulator for Cubesats (M. Balan et al.) 14.30 – 14.45 Active magnetic attitude control algorithms for CXBN-2 CubeSat (M. Ovchinnikov et al.) 14.45 – 15.00 Characterisation of hysteretic dampers for passive attitude control of Cubesats (D. Ivanov et al.) 15.00 – 15.15 A constrained attitude control method for Aoxiang-Sat (R.Liu et al.) __________________________________________________________________________________ 15.30 – 16.00 Coffee break __________________________________________________________________________________ Future Technologies on CubeSats Chair: M. Tetlow 16.00 – 16.15 Characterization and design of solid state hinges for deployable Cubesat structures (E. Ziade et al.) 16.15 – 16.30 Autonomous command and data handling system for a 3U CubeSat (L. Feruglio et al.) 16.30 – 16.45 Early orbit phase of deployment mission of inflatable membrane structure of nanosatellite ''SPROUT'' (K. Mita et al.) 16.45 – 17.00 Implementation of an on-board computer & a modem into a single subsystem for CubeSat (M.E. Bas et al.) 17.00 – 17.15 BIRDY: An interplanetary CubeSat to collect radiation data on the way to Mars with a precursor flight around the Earth in GTO (B. Segret et al.) 17.15 – 17.30 Target Shape Identification for Nanosatellites using Monocular Point Cloud Techniques (Mark Post and Xiu-Tian Yan) 17.30 – 17.45 Closing remarks (P. Jaussi & J. Muylaert) __________________________________________________________________________________ 17.45 – 19.00 GOODBYE DRINK (kindly offered by Clyde Space) __________________________________________________________________________________ 14 Scientific Instruments/Sensors on CubeSats 15 Interfacing with the Science Unit: Preparing the Software Side R. A. de Carvalho1, H. S. Ferreira1, R. F. Toledo1, C. S. Cordeiro1 and Moura L.G.L.1 1 Instituto Federal Fluminense, Campos dos Goytacazes (Rio de Janeiro), Brazil All QB50's satellites will carry and operate one of the three different sensors for in-situ measurements defined by the mission coordination. The development of these sensors is in parallel with the development of the satellites that will transport them, through “contracts” established in proper Interface Control Documents (ICDs), in such a way that satellite developers can prepare their spacecraft to receive and operate the sensors. The aim of this paper is to present the environment created by 14-BISat Team to test the software that will control the Fipex (Flux-Φ-Probe Experiment) through its scripts, store the collected data, and forward this data through GAMALINK, the S-Band Software Defined Radio onboard of 14-BISat. In order to provide a realistic simulation of the Fipex functioning, while aiming at the quality of the code, a set of elements was used to form an integrated software development environment: (i) a tool for modelling and simulating Finite State Machines (FSM), (ii) an Integrated Development Environment for micro-controllers, (iii) a C programming language Test Harness, and (iv) the simulation of Fipex interfaces using a MSP430 Launchpad. The proposed environment provides an integrated process for testing the software on top of the target sensor interface definitions: draw the FSM that represents the sensor behaviour; create test cases for regular and problematic behaviour; automatically generate the tests skeletons for the test cases - with their expected results; and run and check the results. Aiming at supporting this test process, it was developed: a plug-in to generate the automated tests skeletons, hooks for configuring all the tools to work in an integrated way, a library to simulate I/O problems, and a simulation of the Fipex command and response mechanisms for the micro-controller. The proposed process and its supporting environment are capable of testing the software up to the limits that the absence of the (real) hardware allows. Moreover, this set of practices and tools can be generalized to the development of other embedded softwares. 16 The FIRST-S Project: the science case S. Lacour1, V. Lapeyrere1, L. Gauchet1, S. Arroud1, G. Ronnan1, and G. Perrin1 1 Laboratoire d'Etudes Spatiales et d'Instrumentation en Astrophysique (LESIA), Observatoire de Paris, France The FIRST-S project is an astronomical project in the context of exoplanet detection. The goal is to measure the amount of exozodiacal light scattered by dust around bright nearby stars. The level of zodiacal light is a problem since it can hamper planetary detection in extrasolar systems. In the near infrared, the thermal emission of the exozodiacal dust has already been observed from the ground. It is typically 1% of the stellar flux. But the question of the level of scattered light by the dust in the habitable zone is still a mystery. At 1 AU of the star, it may be several thousands times fainter. Still, integrated over the exoplanetary system, it may be several thousand times brighter than the flux emitted by the planets. This is why it needs a dedicated project. The problem from the ground is not the angular resolution. A 8meter telescope theoretically reach an angular resolution equivalent to 0.12 AU at visible wavelength (for a star at 10pc). The problem is the dynamic range, which is limited by the atmosphere, even with an active optics system. Our goal is therefore to reach high dynamic range from space, at moderate resolution. To do so, the FIRST-S CubeSat will be a 30 cm stellar interferometer, with broadband nulling capabilities of the order of 10^3. It is currently under development. 17 Antenna development for the Wideband Ionospheric Sounder CubeSat Experiment (WISCER) G. C. Kirkby, M. J. Angling Space Environment and Radio Engineering group, University of Birmingham, UK There are a wide range of potential uses for a space based foliage penetrating (FOPEN) synthetic aperture radar (SAR) system; however there are significant obstacles which must be dealt with in order to develop an operational system. One of these is the impact of the ionosphere on the system. Consequently, the Wideband Ionospheric Sounder CubeSat Experiment (WISCER) is being developed to measure the impact of the ionosphere on a wideband radar-like signal. . WISCER comprises a wideband (approximately 100 MHz) beacon operating at a centre frequency of approximately 475 MHz. In combination with a ground station the system will measure the channel impulse response (CIR) for the post sunset equatorial ionosphere. The post sunset equatorial ionosphere is of particular interest due to the existence of small scale ionospheric structures that can cause scintillation of the trans-ionospheric signal. It is this scintillation that results in degradation of SAR performance (i.e. loss of contrast in SAR images). It is necessary for the WISCER antenna to be efficient and to have some gain in the forward direction due to the constrained power of the CubeSat. Furthermore, the antenna gain pattern should be well behaved within the main antenna lobe and across the required bandwidth. This is necessary to ensure that the ionospheric effects on the received signal are not obscured by the antenna characteristics. These requirements lead to relatively large antenna designs which present difficulties for deployment and for the CubeSat attitude control system (ACS). Two antenna designs have progressed through initial design stages. The first is an inflatable conical helix antenna. The antenna arms are printed on to the outer layer of the rigidising balloon. The second is a mechanically deployed crossed-Moxon antenna with a re-purposed de-orbit sail acting as a ground plane. This paper will present an overview of the two antenna designs and their electrical performance. Furthermore, results from orbital disturbance simulations that bound the required authority of the CubeSat ACS will be presented. 18 A Compact Ion and Neutral Mass Spectrometer for the ExoCube Mission N. Paschalidis1, S. Jones1, M. Rodriguez1, E. Sittler1, D. Chornay2, P. Uribe1, T. Cameron1, G. Nanan1, G. Suarez1, J. Dumonthier1, J. Noto3, L. Waldrop4, C. Taylor5, D. Gardner6, S. Nosal6, E. Mierkiewicz7 1 NASA / Goddard Space Flight Center (GSFC) , Greenbelt MD 20971, USA 2 University of Maryland, College Park, MD, US 3 Scientific Solutions Inc., MA, USA 4 University of Illinois at Urbana-Champaign 5 California Polytechnic State University, San Luis Obispo 6 University of Wisconsin-Madison 7 Embry-Riddle Aeronautical University, Daytona Beach, FL Demand is high for in situ measurements of atmospheric neutral and ion composition and density, not only for studies of the dynamic ionosphere-theremosphere-mesosphere system but simply to define the steady state background atmospheric conditions. The ExoCube mission is designed to acquire global knowledge of in-situ densities of [H], [He], [O] and [H+], [He+], [O+] in the upper ionosphere and lower exosphere in combination with incoherent scatter radar ground stations distributed in the north polar region . The Heliophysic Division of GSFC has developed a compact Ion and Neutral Mass Spectrometer (INMS) for in situ measurements of ions and neutrals H, He, N, O, N2, O2 with M/dM of approximately 10 at an incoming energy range of 0-50eV, indented for ExoCube and other missions. The INMS is based on front end optics, post acceleration, gated time of flight, ESA and CEM or MCP detectors. The compact sensor has a dual symmetric configuration with the ion and neutral sensor heads on opposite sides and with full electronics in the middle. The neutral front end optics includes thermionic emission ionization and ion blocking grids, and the ion front end optics includes spacecraft potential compensation grids. The electronics include front end, fast gating, HVPS, ionizer, TOF binning and full bi directional C&DH digital electronics. The data package includes 400 mass bins each for ions and neutrals and key housekeeping data for instrument health and calibration. The data sampling can be commanded as fast as 10 msec per frame (corresponding to ~80 m spatial separation) in burst mode, and has significant onboard storage capability and data compression scheme. Experimental data from instrument testing with both ions and neutrals will be presented. The instrument is successfully integrated in the CubeSat and passed vibration, thermal and shock testing. The ExoCube mission is scheduled to fly in Nov 2014 in a 445 x 670 km polar orbit with the INMS aperture oriented in the ram direction. This miniaturized instrument (1.5U), weighing only 560 gr and requiring peak power of 1.6W, will provide the first in situ measurement of exospheric hydrogen and will measure in situ atomic oxygen for the first time in decades. 19 The PIC.A.S.S.O. mission: A PICo-satellite for Atmospheric and Space Science Observations D. Fussen, D. Pieroux, S. Ranvier, J. De Keyser and P. Cardoen Belgian Institute for Space Aeronomy, Brussels, Belgium PIC.A.S.S.O. is a joint project led by the Belgian Institute for Space Aeronomy (BISA) in collaboration with the Royal Observatory of Belgium (ROB). A triple-unit CubeSat targeting the QB50 flight will be developed to embark two scientific experiments dedicated to the study of the ozone distribution in the stratosphere, the temperature profile up to the mesosphere and the electron density in the ionosphere. PICASSO falls thus within the category of CubeSats dedicated to specific scientific missions or to technologic demonstrations, the so-called in-orbit demonstration (IOD) CubeSats. Our goal in participating in a CubeSat mission is primarily to carry out actual scientific experiments, not to develop innovative technologies, to demonstrate new concepts or to educate students. To achieve that goal, PICASSO will embark two experiments: 1. VISION, a visible and near-infrared hyper-spectral imager 2. SLP, a Sweeping Langmuir probe; BISA, which is responsible for both instruments, will delegate the realisation of VISION to the VTT Company (Finland) and will internally develop SLP. For the sake of efficiency and risk reduction, it has also been decided to entrust a CubeSat Industrial Partner (Clyde Space, UK) with the development and the tests of the PICASSO platform from readily available commercial-of-the-shelf (COTS) components. This partner will also be in charge of integrating the instruments and preparing the mission. Optionally, it could be asked to operate the mission too. PIC. A.S.S.O. offers an opportunity to assess the relevance of the CubeSat technology for atmospheric soundings and in-situ measurements at a reduced cost, 20 Solar EUV Probe on QB50/PHOENIX CubeSat J. C. Juang1, A. Chen2, C. W. Chao2, J. Vannitsen3, and J. J. Miau3 1 Department of Electrical Engineering, National Cheng Kung University, Tainan, Taiwan Institute of Space and Plasma Sciences, National Cheng Kung University, Tainan, Taiwan 3 Department of Aeronautics and Astronautics, National Cheng Kung University, Tainan, Taiwan 2 The scientific objective of the QB50 is to study the temporal and spatial variations of ions, neutral particles, electrons, and atomic oxygen in the lower thermosphere with a string of CubeSats carrying sensors for in-situ measurements. Currently, sensors that will be deployed include Ion and Neutral Mass Spectrometer (INMS), Flux--Probe (FIPEX), and multi-needle Langmuir Probe (m-NLP). The most important energy source for the thermosphere is known to be the EUV and X-ray solar radiation. Indeed, solar EUV radiation plays an important role in the ionization process. Therefore, in measuring the contents of ions, neutral particles, and electrons, it is equally important to assess solar EUV radiation intensity. As a participant of the QB50, the PHOENIX CubeSat which is under developed at National Cheng Kung University (NCKU), Taiwan, is designed to carry a solar EUV sensor to in-situ measure the solar EUV radiation intensity with the aim of maximizing the science return of the mission for a better characterization of the cause-effect relationship. The solar EUV probe measures the photoelectron current emitted from the electrodes into ambient plasma. The electrode is biased to negative voltage with respect to the satellite frame and the current is amplified and filtered before being converted into digital formats. In the implementation, two electrodes with different metal coating are utilized and the current difference between the two probes. The solar EUV instrument has been tested in ionospheric conditions in the NCKU Space Plasma Chamber. An integration test campaign has also been conducted to check the functionality and performance of the sensor. 21 CubeSat-ready Radiation Monitor Front-End Electronics T. A. Stein1,2 1 Department of Physics, Norwegian University of Science and Technology (NTNU), 7491 Trondheim, Norway 2 Integrated Detector Electronics AS (IDEAS), Martin Linges Vei 25, 1364 Fornebu, Norway The requirements for CubeSats heavily restrict the payload in terms of mass, volume, and power. In this work we present radiation monitor front-end electronics that meet the requirements for CubeSats. The electronics design uses an application specific integrated circuit (ASIC) with multiple channels of charge sensitive amplifiers and charge discriminators for pulse height spectroscopy and counting. The ASIC provides a low-mass and low-volume solution for the entire front-end electronics on a monolithic silicon die. The ASIC and the embedded system are optimised for space operations such as lowest possible power consumption. In order to meet the CubeSat specifications, we adapted the voltage supply and signal interface between the ASIC and on-board computer. The ASIC-based design allows the spectroscopic counting of electrons and protons. The low mass and small size makes the device ideal for CubeSats. Furthermore, the in-flight operation of the instrument in CubeSats will be useful for further instrument developments that require flight heritage. Emphasis is put into the generalisation of the device to meet the needs of the CubeSat community. NTNU is currently developing a double CubeSat called NUTS aiming for launch in 2016. In view of future CubeSat and small satellite missions the above front-end electronics were conceived within the NUTS project in collaboration with IDEAS. The first flight of the CubeSat-ready Radiation Monitor Electronics is proposed for the Norwegian satellite NORSAT-2. This mission is set for launch in 2018 and is currently in its planning phase. The small satellite NORSAT-2 is going to carry several instruments predominantly made by Norwegian institutions with opportunities for university students. We have conducted initial tests of the ASIC and the results are very encouraging for its use towards a radiation monitor for the NORSAT-2 mission. We are analysing the implementation of the radiation monitor with the FPGA, the microcontroller and the radiation detectors and the power system. These components allow relevant studies in fields such as space weather or high-energy physics. We plan to use the device for the monitoring of electron and proton radiation as well as energy spectroscopy. 22 Wavelet transform as an efficient and effective tool for electromagnetic emission measurements in space plasma Tomasz Szewczyk, Hanna Rothkaehl, Marek Morawski Space Research Centre, Polish Academy of Sciences, Warsaw, Poland Wavelet transform is successfully used in various areas of data analysis and compression (e.g. JPEG2000 image compression standard). Application of wavelets in analysis of the electromagnetic emission observed by space borne instruments is currently investigated in Space Research Centre PAS. Wavelet transform might be especially useful in: Real-time filtration of data and detection of particularly interesting scientific activity. Analysis both in time and frequency domain, and reconfiguration of instrument to focus on certain scientific aspects of measured data. Compression of gathered data allowing better utilization of communication bandwidth. Implementation of new algorithms used in Earth orbiting frequency analyzers will allow better understanding of on-going phenomena in ionosphere and magnetosphere. Process of hardware implementation of wavelet transform toolset consists of the following steps: Error analysis (in Matlab environment) of data/wavelet coefficient number representation. This aspect is particularly important, since hardware implementation of wavelet transform has to be robust, yet with small hardware footprint. Verification of model using hardware VHDL implementation of wavelet transform in Xilinx Spartan3 FPGA. To provide reliable source of test data, signals gathered by Demeter satellite are used. Hardware implementation of filtration and compression algorithms that were previously tested in Matlab environment. Wavelet processing toolkit is currently developed as one of scientific modes for High Frequency Analyzer (HFA) instrument which will be placed on-board RESONANCE (constellation of four satellites) mission whose aim is to perform 4-point measurements of Earth’s plasma. This mode is new feature in electromagnetic wave analyzers developed at Space Research Centre. Further plans include implementing wavelet transform algorithms on-board of upcoming CubeSat missions (e.g. TwinCube). Due to CubeSat restrictions regarding computational power, energy and communication bandwidth, algorithms using wavelet transform might find good application in this field. Although our wavelet processing toolkit is developed for particular use on-board of electromagnetic plasma waves analyzers, whole toolset might be applied to other types of scientific measurements where time-frequency analysis and lossy data compression is required. 23 On feasibility of Global Radio Frequency Interference measurement with CubeSats J. Praks1, M. Vaaja1, J. Seppänen1, R. Modrzewski1, A. Hakkarainen1, S. Ben Cheikh1 and J. Lahtinen2 1 Aalto University, School of Electrical Engineering, Helsinki, Finland 2 Harp Technologies Ltd, Espoo, Finland In this paper we discuss the idea of using CubeSats for Radio Frequency Interference (RFI) mapping on a global scale, to provide up-to-date information for better satellite mission design. The available radio frequency spectrum is a finite natural resource which is utilized more extensively every year. Among other areas, radio frequency spectrum plays a key role in space technology and microwave remote sensing, as it provides means for communication and sensing over large distances. Despite strict international coordination, increasing deliberate or accidental transmissions on unwanted frequencies create a problem for remote sensing satellites and satellite communication. This problem needs attention on the global level. A good example of RFI-caused difficulty for an Earth Observation instrument is the SMOS (Soil Moisture and Ocean Salinity, European Space Agency) mission which is severely hampered by radio transmissions operating illegally at the protected frequency band of 1.4 GHz all over the world. In the future, potential RFI problems should be better accounted for from the early planning phase of missions. For this, the global RFI statistics and preferably global maps are required. CubeSat provides cost-effective means for quick development of short precursor or technology demonstration missions in LEO orbit. We propose that the platform can also be utilized for global RFI mapping. However, size limitations of the platform set limits on the applicable frequency range, radiometric accuracy and spatial resolution. In this work we provide trade-off calculations to identify the limiting constraints and frequency ranges where RFI can cause problems for future missions. We show that a precursor mission with CubeSats can provide valuable information for a larger mission to tackle the RFI problem in the early design phase and provide information on RFI at the global scale. 24 Doing Science with University Cubesats: Present and Future T. Moretto Jorgensen National Science Foundation, Arlington, Virginia, USA When the US National Science Foundation (NSF) began exploring the use of cubesats to conduct space weather research in 2007 few people believed the miniature satellites would prove to be a useful scientific tool. However, during the last five years, the NSF cubesat program has seen the highly successful implementation of creative and innovative missions that carry out important science experiments. Currently, the program supports 11 projects and has had 6 missions operating in space. The assortment of scientific investigations being pursued and proposed spans all across solar, space physics, space weather, and atmospheric research. Already, several projects in the program have delivered first-of-their-kind observations and findings that have formed the basis for high profile engineering and science publications. Inarguably, the results from the program have now established beyond doubt the scientific value of cubesats and have proven them as a viable option for space missions that should be taken seriously. Based on examples and lessons learned from current projects the presentation will document and explore the prolific scientific promise of CubeSat missions. 25 The Micro Solar-Flare Apparatus (MiSolFA) Diego Casadei Fachhochschule Nordwestschweiz (FHNW), Bahnhofstrasse 6, 5210 Windisch, Switzerland Solar flares are the most powerful events in the solar system and the brightest sources of X-rays, often associated with emission of particles reaching the Earth and causing geomagnetic storms, giving problems to communication, airplanes and even black-outs. X-rays emitted by accelerated electrons are the most direct probe of solar flare phenomena. The Micro Solar-Flare Apparatus (MiSolFA) is a proposed compact X-ray detector which will address the two biggest issues in solar flare modeling. Dynamic range limitations prevent simultaneous spectroscopy with a single instrument of all X-ray emitting regions of a flare. In addition, most X-ray observations so far are inconsistent with the high anisotropy predicted by the models usually adopted for solar flares. Operated at the same time as the STIX instrument of the ESA Solar Orbiter mission, at the next solar maximum (2020), they will have the unique opportunity to look at the same flare from two different directions: Solar Orbiter gets very close to the Sun with significant orbital inclination; MiSolFA is in a near-Earth orbit. To solve the crosscalibration problems affecting all previous attempts to combine data from different satellites, MiSolFA will adopt the same photon detectors as STIX, precisely quantifying the anisotropy of the X-ray emission for the first time. By selecting flares whose footprints (the brightest X-ray sources, at the chromosphere) are occulted by the solar limb for one of the two detectors, the other will be able to study the much fainter coronal emission, obtaining for the first time simultaneous observations of all interesting regions. MiSolFA shall operate on board of a very small satellite, with several launch opportunities, and will rely on moiré imaging techniques. 26 Mapping the radiation environment in Equatorial Low Earth Orbit with CubeSats E. Del Monte1, M. Feroci1, Guido Parissenti2 on behalf of a larger collaboration 1 Istituto Nazionale di Astrofisica (INAF) - Istituto di Astrofisica e Planetologia Spaziali (IAPS), Roma (Italy) 2 Department of Energy - Politecnico di Milano, Milano (Italy) Satellites in orbit around the Earth operate in a harsh particle environment. Thanks to past and recent experiments, datasets and models of the proton and electron fluxes are available but with uneven coverage, leaving some regions of interest for science-oriented satellites unexplored. Few data are available about the radiation environment in Equatorial Low-Earth Orbits, with inclination below about 20 deg, where a number of astronomy missions require to operate. As an example, a low-energy and highly directional population of protons have been recently discovered. The currently available database leaves large uncertainties when developing science missions for these orbits, with respect to both radiation damage and experiment background issues. In the last years, compact, light and standard yet adequately sensitive particle monitors for satellite-borne applications have been developed. CubeSats require low resources (in terms of mass and power) and are relatively inexpensive, thus perfectly suited to carry in orbit such particle monitors and map the radiation environment in the orbits of interest. In this presentation we analyse the CubeSat mission profiles required to collect the required data about the radiation environment in Equatorial Low-Earth Orbits. 27 From the low cost to the high benefits The outreach of small satellites instrumentation Marina Diaz Michelena National Institute for Aerospace Technology (INTA) Madrid, Spain One of the technological challenges of the present century is to place laboratories and observatories with global coverage in the Space. Constellations of small satellites are potential platforms for such worldwide observatories as long as the payloads can stand the extreme conditions of the Space: wide temperature ranges, vacuum, and radiation, and have low mass and power consumption. But this idea is only feasible if the cost of the payloads is not excessive. Since the 1990s, motivated by the decrease in budgets in most of the world’s space agencies, the use of Commercial Off the Shelf (COTS) has provided miniature devices with higher functionality, lower power consumption, and lower cost than traditional high reliability (hi-rel) and radiation hardened (rad-hard) components often used for flight. At the National Institute of Aerospace Technology (INTA) of Spain, we developed and qualified six COTS-based compact miniaturized magnetometers built with different magnetic technologies: Anisotropic MagnetoResistance (AMR), Giant MagnetoResistance (GMR) and MagnetoImpedance (MI). These instruments are currently on several quasipolar Low Earth Orbits (LEO) onboard INTA platforms: NANOSAT-01 (19 kg mass launched in 2004) NANOSAT-1B (23.9 Kg mass launched in 2009) OPTOS (3.8 kg mass launched in 2013) providing useful information for multiple purposes (Attitude Control System, COTS degradation monitoring, Space weather, etc). After more than ten years of experience we can state that the use of COTS in small plaftorms is very profitable. In this work we explain the resulting outreach of these developments, covering the implementation of these miniaturized magnetometers on drones for geophysical prospections to the planetary exploration on board landers and rovers. 28 A CubeSat for X-ray Polarimetry in Astrophysics P. Soffitta1, E. Del Monte1, S. Fabiani2, F. Muleri1 and Guido Parissenti3 1 Istituto di Astrofisica e Planetologia Spaziali/INAF, Rome, Italy 2 INFN Sezione di Trieste, Padriciano (Trieste), Italy 3 Department of Energy - Politecnico di Milano, Milano, Italy While the sun was the first non-terrestrial X-ray source discovered back in 1948, many aspects of solar physics needs to be understood. One of this is the high energy emission following magnetic reconnection events in the solar corona generating solar flares. In particular the expected X-ray polarization from the impact of beamed electrons in the chromosphere must still be detected. Only upper limit are available so-far derived from large instruments like RHESSI and SPR-N on Coronas F. Celestial non solar X-ray sources first discovered in 1962 are also expected to be polarized in X-ray at least of some extent providing information on the emission mechanisms, geometries and answering questions of fundamental physics. Those include the Crab Nebula, for which the only positive measurement results so far back in the ’70 and eventually micro-quasars harbouring a black-hole surrounded by an accretion disk. One characteristics of a polarization measurement in X-rays is that it requires a large amount of photons to measure the few % expected. Sufficient amount of photons can be collected in case of a bright source like the Sun or with very long integration time as in case of those much fainter celestial non-solar X-ray sources. For more than ten years, we exploits efficiently the photoelectric effect in gas to derive the polarization of the incoming X-ray beam with a small, light and low-power device, called Gas Pixel Detector, based on the use of a finely pixelated ASIC-CMOS chip that collects the charge amplified by a Gas Electron Multiplier. In this talk we present how such device allows for designing instruments capable of sensitive measurements and meaningful results in the frame of the resources available by the class of nanosatellite CubeSat. 29 Evaluation of the performances of a spectro imaging detector (CALISTE) to be embedded on board a nanosatellite for Solar Flares studies H. Triou1, A. Meuris1, O. Limousin1, L. Gosset2 et al. 1 CEA Saclay, DSM/IRFU/service d'Astrophysique, 91191, Gif-sur-Yvette, France 2 EIDD, Université Paris Diderot, Paris, France Solar flares (with CMEs) are the most violent phenomena in the solar system. Although general characteristics of solar flare can be derived, each solar flare has unique characteristics: different spectral indices for energy spectra can be found and the photon flux can be more or less important. After an analysis of solar flares in X-rays we detail the constraints associated with the use of for the CALISTE detector, which is an innovative and miniature sensor developed by CEA, for solar flares studies. We present an analytical model that we realized in order to simulate the response of the instrument. Many parameters have been analyzed to optimize the detector that will be embedded on board a Nanosatellite (CubeSat type). The goal is to define a perfect counter and spectrometer which means that the detector has to count the number of photons and determine their energies in order to reconstruct the photon spectrum of the incident solar flare. This sensor is composed of 256 pixels so that it is possible to switch on or off some of them according to the photons flux, in order not to saturate electronics of the detector. A low level threshold can also be adjusted according to the incident photons flux. Another important point will be the question of adding filters in front of the sensor or not. The analysis of the response of the detector when varying these parameters allowed us determines the number of counts that the detector’s electronics will be able to analyze perfectly. Moreover, knowing the reduction of the number of counts obtained, we will be able to deduce the incident photons spectrum in order to study it. Finally we propose an optimal configuration of sensors which will be integrated to the nanosatellite to observe the largest number of solar flares of different intensities as possible in order to study in a quantitative way the solar flares phenomenon. In addition, the constraints associated with the accommodation of our detectors on a nanosatellite are presented (type of orbit, volume of science data to be downloaded via telemetry, power, mass, temperature requirements and so on …) and a nanosatellite configuration (6U CubeSat) is proposed to meet these requirements. 30 Micropropulsion Systems 31 A Highly Miniaturized uPPT Thruster for Attitude-orbit Control Junquan Li1, Steve Greenland1, Mark Post2, Michele Coletti3 1 2 Clyde Space Ltd. West of Scotland Science Park, Glasgow G20 0SP UK Mars Space Ltd, Unit 61, Basepoint B.C., Andersons Road, S014 5FE, Southampton, UK 3 University of Strathclyde, 16 Richmond St, Glasgow, G1 1XQ, UK. The successful miniaturization of spacecraft subsystems makes nanosatellites suitable candidates for many scientific missions, and several miniaturized electric propulsion systems on CubeSats have been studied. A Cubesat employing a Pulsed Plasma Thruster module is currently under development by Clyde Space Ltd, Mars Space Ltd and the University of Southampton under contract to ESA and is now entering final qualification testing. Pulsed Plasma Thrusters have been used in satellite attitude control studies of nadir pointing, and satellite rendezvous, docking and formation flying. This paper considers the use of the PPTCUP Pulsed Plasma Thruster in a range of different operational cases that are considered key to the success of many future nanosatellite missions, including moderate low thrust orbit inclination and altitude changes, deorbiting a satellite at the end of life, maintaining “a string of pearls” constellation, on-orbit servicing and inspection of a mother satellite, and life extension of an ISS-deployed nanosatellite. PPTCUP uses a very fast electric discharge to ablate a tiny amount of a solid propellant bar, which is then ionized and expelled at high velocity to generate thrust. To generate such a discharge, the thruster charges a high performance capacitor bank for up to a second before discharging it in few microseconds. Based on a current generation system with a mean power input of 2 W, a 40 uN thrust pulse (with a 20 N peak force) can be achieved 1 million times in succession. In order to evaluate the PPTCUP thruster performance, a simulation model has been developed and applied to the identified scenarios, leading to suggestions for baseline control laws suited for the mission. Where necessary, refinement of the design point has been performed to provide a roadmap for future PPTCUP development. We assume a nanosatellite that has a maximum mass of 4 kg at 320-380 km. Drag force and yearly velocity increments are estimated as functions of altitude, drag cross-section and solar activity. Assuming an analysis of a 3U Cubesat frame with PPTCUP, a control approach based on advanced control methods will be used to handle different operational cases. This work finds immediate application for the PPTCUP for challenges such as drag compensation, de-orbiting, and rendezvous and docking manoeuvres, and makes recommendations for future targeting of performance to further improve the capability of PPTCUP equipped satellites. In particular it is noted that advanced control design would improve the coverage of this class of thruster. 32 Solid Cool Gas Micro Propulsion System for CubeSat Peng Zhu, Xiang Zhang, Ruiqi Shen, Yinghua Ye, Zhenhua Liang Nanjing University of Science and Technology, Nanjing, China This article studies the solid cool gas micro propulsion system suitable for CubeSats. The system includes the gas generators, pressure sensor, valve and nozzle. Among them, the gas generators are composed of igniter, gas generating agents and filter. The characterization of gas generator indicates that 100g gas generating agents can produce approximately 66 normal liters of pure gas, and the temperature of the gas squirting from the gas generator is about 53°C. The performance of solid cool gas propulsion system was characterized by using ballistic pendulum. Results showed that the micro propulsion system is suitable for the attitude control and orbit transfer of CubeSats. 33 Solid propellant micro-thruster array for CubeSat Xuhui Liu, Yanming Wei, Jun Chen, Yan Shen, Xudong Wang, Jun Long Institute of Control Engineering, Beijing, China Solid propellant micro-thruster array has attracted widespread attention since the late 1990s. It can provide micro impulses and impulse moments for precise orbit correction and attitude adjustment. What’s more, it can provide combination among single thrusters for wide-range maneuverability. In order to apply solid propellant micro-thruster array to CubeSats, allocation algorithm, ignition system, design and testing of array’s principle prototype and space mission analysis, have been mainly studied in this paper. Correlation functions of thruster impulse and moment distribution in CubeSat coordinate system were established, that formed the mathematical model of thruster allocation. Then, performance features of solid propellant micro-thruster array were analyzed and the dynamical models of attitude and orbit control were established, respectively. 34 Development Status of an Open Capillary Pulsed Plasma Thruster with Non-Volatile Liquid Propellant E. Remírez(1), R. Martín(1), S. Barral(2), J. Kurzyna(2), A. Szelecka(2), H. Rachubinski(2), J. Miedzik(2), P. Ortiz(3), J. Alonso(3), S. Botinelli(4), Y. Mabillard(4), P. Rangsten(5), A. Zaldivar(5), C.R. Koppel(6) (1) (2) JMP Ingenieros, 26371 Sotés (La Rioja) Spain Institute of Plasma Physics and Laser Microfusion (IPPLM), 01497 Warsaw, Poland (3) Najera Aerospace (NASP), 26371 Sotés (La Rioja) Spain (4) Mecartex, 6933 Muzzano, Switzerland (5) Nanospace, Uppsala Science Park, SE-751 83 Uppsala, Sweden (6) KopooS Consulting Ind., 75008 Paris, France The desire to reduce development and launcher costs and the narrow focus of many payloads has in recent years driven the development of very small platforms in the kg range. Such spacecrafts have benefited from the wider availability of enabling technologies (micro/nano-fabrication), but remain hindered by the lack of sufficiently compact and lightweight micro-propulsion systems. Low thrust propulsion systems have at the same time also become a critical component in a number of scientific missions that require fine positioning, such as space-based telescope interferometers, imaging arrays and formation flying missions . Due to their simplicity and scalability, Pulsed Plasma Thrusters (PPT) are increasingly considered for small delta-V missions on nano-spacecrafts. The goal of the L-μPPT project is the development and assessment of a novel PPT technology based on an open capillary design and on a non-volatile liquid propellant, which in comparison to conventional solidpropellant (PTFE) PPTs is expected to offer significantly larger total impulse and lower impulse bit variability throughout the thruster lifetime. Another intrinsic advantage of liquid propellant is the possibility to balance propellant requirements between several thrusters with a common tank, which in practice is expected to enable to a twofold increase in propellant utilization. The many issues associated with the use of water as liquid propellant and current lack of compelling solution to address them has motivated the L-μPPT project to adopt a non-volatile liquid that can be easily used and stored over a wide temperature range. A novel type of Pulsed Plasma Thruster (PPT) based on an open capillary design and on a non-volatile liquid propellant is currently under development within the Liquid Micro Pulsed Plasma Thruster FP7 project (LμPPT). Functional results from first prototype testing provide an Ibit 25 µNs @ 700V and 46 µNs @ 1000V, presenting a Ibit/E ratio beyond 40 µN/W. Its design is expected to improve over PTFE-based PPTs by providing significant increase in total impulse, increased propellant utilization, lower impulse bit variability and the possibility to balance propellant requirements between several thrusters with a common tank. 35 CubeSat Launchers and Deployers 36 Reliable Low-cost Access To Space For CubeSat Size Payloads P. C. Steimle1, C. Kuehnel2 and R. Pournelle3 1 2 Airbus DS GmbH, Bremen, Germany Astrium North America Inc., Houston, Texas, United States of America 3 NanoRacks LLC, Houston, Texas, United States of America In recent years the commercial use of space has seen significant dynamics, especially in the field of small satellites, as more and more countries get involved in space business. But the growing small payload market is unlikely supported by the launcher systems and mission concepts currently available which creates a bottleneck situation that could slow down market growth significantly. One important implication of the small payload dilemma is the difficulty to access the optimal orbit for the mission at acceptable system and launch cost. The common practice of sharing the launch with other small satellites often leads to a compromise between the cost effective launch and the perfect satisfaction of payload mission requirements. This is especially true for the majority of technology demonstration missions. The commercial utilisation of the International Space Station (ISS) for smallsize payloads driven by the U.S. company NanoRacks LLC is one opportunity to overcome this small payload dilemma. Two concepts are offered to the market: One is the External Payload Platform (EPP) designed and manufactured by Astrium North America and Airbus Defence and Space for unpressurised CubeSat size payloads which will be launched to the ISS and installed on the Japanese Experiment Module External Facility (JEM-EF) by the end of 2014. The other is the well-known CubeSat Dispenser (CSD) which deploys CubeSats from the ISS on a regular basis. The two concepts and their opportunities and constraints are presented focussing on the needs of small payloads. The EPP design allows the fully robotic installation and operation of payloads. In the nominal mission scenario payload items are installed not later than one year after the signature of the contract, stay in operation outside of the International Space Station for 15 weeks, and can be returned to the customer thereafter. Payload items are transported among the pressurised cargo usually delivered to the station with various supply vehicles. Due to the high frequency of lights and the flexibility of the vehicle manifests the risk of a delay in the payload readiness can be mitigated by delaying to the next flight opportunity. The mission is extra-ordinarily fast and of low cost in comparison to traditional activities conducted on-board the ISS and can fit into short-term funding cycles available on national and multi-national levels. This fast turnaround can also help payload developers maintain support for their programs by providing tangible in-space testing. The standard payload size is a multiple of a 4U CubeSat. Every payload can extensively use all ISS resources required: mass is not limited, power only limited by the payload heat radiation capability, the data link is a USB 2.0 standard bus enabling a real-time and private data link to the payload operator's work station. The new EPP transforms the station into a true laboratory in space with the capability to support research and development in various fields as well as in-orbit demonstration and verification. The CSD also provides reliable access to space through regular flights to ISS. The CSD can deploy satellites ranging from 1U to 6U including the 2Ux3U form factor. Currently, 2-3 CubeSat missions, deploying 30 – 40 per mission are performed each year. The EPP and the CSD both are operated in the frame of end-to-end services dedicated to be of low cost and while introducing a new level of technical and programmatic reliability to small payload missions to support current market dynamics. 37 On-Orbit Optimization of CubeSat Launch Opportunities using an Orbital Maneuvering Vehicle M. Stender1, J. Maly2, C. Loghry3, C. Pearson1, E. Anderson2 1 Moog, Inc. Space and Defense, Advanced Missions and Science, Golden, CO, USA 2 Moog CSA, Mountain View, CA, USA 3 Moog In-Space Propulsion, Chatsworth, CA, USA As the capability of CubeSats increases, one limiting factor remains – non-ideal drop-off orbits. Although secondary payload opportunities are becoming more available, CubeSats are still accepting less than optimal orbits in order to access space. In the case of constellations, commercial and government entities are now recognizing their potential, but still need a way to quickly and economically adjust the orbits of these valuable secondary payloads. The mobility of individual CubeSats and smallsats is inherently constrained by the limited volume available for a propulsion system. However, further factors also limit them, such as the cost of a miniaturized system (assuming technology is available), the perceived hazards, and the time required for a large delta-V maneuver (in the case of EP). By utilizing a single orbital maneuvering vehicle (OMV), a number of these challenges can be overcome and the burden of a propulsion system is not imposed on a CubeSat. Moog’s family of OMVs is uniquely suited to this task due to a range of modular options that build on the proven ESPA structure. Previous missions, such as LCROSS and the upcoming launch of DSX, have taken advantage of such modularity to easily integrate avionics, solar panels, and even the upper stage of a launch vehicle. New designs for CubeSat and small sat deployment mechanisms also provide secondary payloads with a wider range of options for staggered deployment in one or multiple orbits. An example OMV configuration and a representative CubeSat constellation deployment timeline will be presented to illustrate how a secondary payload can share a launch and still achieve their desired mission parameters. 38 Swiss Space Systems Innovative Launch Concept for Small Satellites B. Deper, P. Jaussi and B. Vuitel Swiss Space Systems Holding SA, Payerne, Switzerland Swiss Space Systems (S3) is a young company with the objective of providing a reusable, flexible, safe and efficient launch system for small satellites. The Swiss Space Systems launch model comprises of an Airbus A300 aircraft (first stage), a sub-orbital shuttle “SOAR” (2nd stage) and the third stage spacecraft with the satellites inside. The S3 launch concept uses the Airbus A300, an aircraft already certified for zero gravity flights, to take the SOAR shuttle up to 10 km on its back; the shuttle will be launched from there. The shuttle will then ascend up to an altitude of 80km, the height at which the upper stage will be launched in order to put the satellites into orbit. Once this operation is completed, the shuttle will return to earth by gliding towards its launch airport, where it will be taken care of by the maintenance teams who will prepare it for a new launch. The system developed by S3 has many safety advantages: the launch can be terminated and the shuttle can return to Earth at any time during the process. With first and second stages that are regularly reused and a fuel consumption that is much lower than at present, Swiss Space Systems will be able to offer satellite launches at approximately four times less than current market prices. Any large airport is suitable to act as a “space port” and there is no need to erect a launch site from scratch. The company mission is to give access to space. S3 wants to make space accessible through fast and recurrent access opportunities facilitating particularly science and in-orbit delivery. The company objective is to develop, manufacture, certify and operate unmanned suborbital space planes for small satellite deployment. The range of satellites to be launched goes up to 250 kg small satellites. The start of the test flights is planned for 2017, the first commercial flights in 2018. In order to achieve this goal, S3 relies on the support of a worldwide network of internationally renowned partners and advisors, who all support S3 and trust our vision. 39 Technology Demonstration on CubeSats 40 Space Object Detection on a CubeSat platform M. Tetlow1, P. Veitch2 and T. Chin2 1 2 Inovor Technologies, Adelaide, Australia The University of Adelaide, Adelaide, Australia Space Situational Awareness (SSA) is of key interest to Australia, as stated in defence and civilian policy documents. Considerable investment has been made in ground based systems to detect space objects. These systems can detect and track objects with high accuracy. As with all ground based platforms, depending on the orbit of the unknown object, considerable time may elapse between observation opportunities, and in some cases, the object may never be observable from a particular location on the surface of the Earth. A low cost space based detection system of ~5 nano satellites would complement these ground based systems by providing much wider detection coverage. The concept of operations (CONOPS) is for a small evenly-distributed constellation of ~5 CubeSats to conducting SSA observations. The SSAsat will capture an image and compare it to the star chart onboard. Using a subset of identified stars, it will estimate the attitude of the space craft and then remove all known stars from the image, based on the star chart. The remaining objects will then be compared to the catalog of known space objects in the NORAD catalogue. If any objects are neither in the star chart nor the NORAD catalogue, they will be identified as unknown. The SSAsat will then attempt to capture more images of the object to estimate its orbit. Information about unknown objects will be handed over to other CubeSats in the constellation to provide the best chance to tracking. With over 80% of the space investment being in the GEO and MEO belts, these will be the target orbits. This paper presents a nano-satellite based imaging system that can conduct space situational awareness monitoring in the Medium Earth Orbit and Geostationary Earth Obit belts from Low Earth Orbit. A systems analysis and configuration design of the nano-satellite is presented, showing how the imager will be integrated into the nano-satellite. Proposed COTS and custom designed hardware is presented along with relevant budgets, showing the feasibility of the design. A robust algorithm for detecting false stars is also presented to support attitude estimation as well as detecting unknown space objects. 41 The Multi-Payload Satellite Service (MPS) for in-orbit technology evaluation L. León1, J. M. Quero2, J. M. Moreno1 1 2 Solar MEMS Technologies S.L., Seville (Spain) Department of Electronic Engineering, University of Seville (Spain) According to ESA criteria, in-flight performance is the highest level of qualification for space products. For this reason, there is an increasing demand for in-flight services to accommodate new devices and systems for their evaluation and validation. The Multi-Payload Satellite (MPS) is a service, offered by Solar MEMS, to evaluate new technologies under a low-cost CubeSat mission. This service provides a complete support for every mission step, leaving to the technology developers only the design and manufacturing of their own payloads. MPS includes the CubeSat platform assembly, payload integration, operational tests, launch, in-orbit evaluation and test reports. The mission budget is shared between several onboard payloads, thus reducing the service cost for each one under a similar idea than the multi-project wafer (MPW) in microelectronics. MPS also includes consulting services and design assistance if required, in order to offer the flight opportunities to any manufacturer, even without previous knowledge about a space mission. The suitability of CubeSats as platforms for payloads experimentation is proven with the first mission CEPHEUS. CEPHEUS is a 3U CubeSat with five different payloads for in-flight experimentation, developed by various companies and full integrated by Solar MEMS and the University of Seville. The payloads consist on a fuel cell with an interface control unit, a miniaturized Star Tracker, a high quality radio transceiver, a high accurate MEMS sun sensor and an advanced attitude control software. During this mission, payload integration procedures have been standardized, optimizing the mission in terms of design time and costs. This project is the starting point of the MPS service and is scheduled for launch in the first half of 2016. MPS offers the opportunity to reach the highest competitiveness level for a CubeSat product, which is the in-flight validated. The integration of payloads in a proven quality platform, based in a rapid development approach, provides a flexible solution to gain heritage and dramatically reduces the mission time, cost and complexity, opening new opportunities and markets. 42 SamSat–QB50 nanosatellite. Burning wires mechanism for antenna system and aerodynamic stabilizer E. Ustiugov1, A. Nikitin1, S. Shafran1 1 Samara State Aerospace University, Samara, Russia SamSat-QB50 CubeSat contains two deployment systems: antenna system and aerodynamic stabilizer. Antenna deployment system (AntS) is part of communication system based on COTS transceiver. AntS has four spring rods with are produce the force for deploy. This spring rods are twisted like helix inside of the special space in AntS. This space are blocked by the door with are locked by the burning wire. Aerodynamic stabilizer (AeroS) is the part of ADCS based on using aerodynamic force and magnetic field. AeroS has a bottom plate, rods and balloon with are produce the force for deploy. Before transformation bottom plate is locked by the burning wire. Both of two systems deploy separately and after command from OBC. It means two controllers are needed for each if this systems, but because the designs are in-house, only one controller is used. Commonly AntS controller is designed for four controllers and four burning mechanism. Four is staff and four is reserved but the controller can handle more than eight commands. We transfer functions of AeroS controller to AntS controller. Command to deploy AntS arrives at AntS controller and switches on the burning wire mechanism. Command to deploy AeroS arrives at AntS controller and is transferred to the burning wire mechanism of AeroS. This principle allows designing simpler deployment systems with less number of components and better reliability. Laboratory tests show the normal and stable functioning of deployment mechanisms of both systems. 43 Testing of low-cost GNSS receivers for CubeSat orbit and attitude determination C. Hollenstein1, B. Männel1, E. Serantoni1, L. Scherer1, M. Rothacher1 and Ph. Kehl2 1 Geodesy and Geodynamics Lab, ETH Zurich, Switzerland 2 u-blox AG, Thalwil, Switzerland In the cooperative Swiss CubeSat project ‘CubETH’ - involving ETH Zurich, the Swiss Space Center, several universities of Applied Sciences, and Swiss companies - the main science goals are precise orbit determination and attitude determination of a (1-unit) CubeSat using single-frequency GNSS receivers. For this purpose, CubETH will be equipped with u-blox multi-GNSS receivers - low-cost, single-frequency COTS receivers for embedded solutions, providing navigation solutions as well as raw code and phase measurements, characterized by good performance and very small size, weight and power consumption and, therefore, predestined for CubeSat missions. However, they are not space-qualified. Therefore, in the first phase of the project, numerous tests have been performed in order to study the behaviour of the receivers in the intended space environment and to evaluate their usability for space applications. In this presentation we focus on the receiver tests carried out - in particular radiation, temperature, vacuum and GNSS simulator tests - shortly describing test setups and procedures and presenting current results and conclusions drawn from these tests. Apart from types and frequencies of radiation effects that have to be expected in the orbit, the results of the radiation tests show a remarkable autonomous error detection performance and a generally good recovering capability of the receivers. In the temperature vacuum cycling tests, we were mainly interested in the physical resistance of the nonspace-qualified receiver components against vacuum and the exposure to extreme temperature conditions as well as the behaviour of the internal clock under these extreme conditions and its effects on the measuring performance of the receiver. GNSS simulator tests revealed valuable information on the receiver’s performance in tracking and measuring GNSS under space conditions and its impact on the scientific tasks. The ‘untuned’ internal u-blox navigation solutions (code solution) of a simulated LEO orbit with a height of 450 km revealed accuracies of about 3-4 m in position and <10 cm/s in velocity. The results of the tests carried out up to now support the conclusion that the u-blox receivers - although not fully resistant to effects due to space environment - are usable for space applications in LEO orbits as planned in the project, if the concept includes latch-up protection and redundant receivers. 44 QARMAN: As an Atmospheric Entry Experiment on CubeSat Platform M.E. Umit, V. Van der Haegen, G. Bailet, I. Sakraker, T. Scholz, P. Testani von Karman Institute for Fluid Dynamics, Rhode-Saint-Genèse (Brussels), Belgium QARMAN, QubeSat for Aerothermodynamic Research and Measurements on AblatioN, is a triple unit (3U) CubeSat that will perform an experiment on Earth atmospheric entry. QARMAN has three payloads, which will operate on different time slots of the mission. The first payload “Semi-controlled differential-drag-based manoeuvres” experiment will be conducted after commissioning and de-tumbling phase. The aim is to control the surface exposed to the residual atmosphere, changing the magnitude of the atmospheric drag and therefore creating a (differential) force, between one spacecraft (chaser) and either another spacecraft or a desired target point. The main QARMAN payload is the usage of a CubeSat platform as “Atmospheric Entry Demonstrator”. Spacecraft descending towards a planet with an atmosphere experience very harsh environment as extreme aerodynamic heating and exothermic chemical reactions occur due to the gas surface interaction at hypersonic free stream velocities. Such vehicles have special shields to survive these harsh conditions, so will QARMAN. If this mission is successful, different entry vehicle configurations can be tested on board at very low costs for scientific exploration and qualification of future missions in order to provide valuable real flight data. To collect real flight data the challenging physics of atmospheric entry to be investigated are downselected to make scientifically valuable measurements respecting the constraints of CubeSat platforms. Thermal Protection System (TPS) ablation, efficiency, and environment; attitude stability; rarefied flow conditions; off stagnation temperature evolution and finally aerothermodynamic environment will be measured on QARMAN using COTS spectrometer, photodiode, temperature, pressure sensors. The feasibility study of an effective TPS that could fit within the external dimensions of a 3U standard CubeSat is one of the challenging parts of this project. It has to manage the thermal environment until the targeted altitude, by keeping the payload bay in a suitable temperature. QARMAN mission aims to provide an Earth entry flight data set for a given entry trajectory. This requires an accurate de-orbiting system for QARMAN to reach 7.7 km/s at 120 km altitude. Thus, the third payload of QARMAN is called “Aerodynamic Stability and De-Orbiting System (AeroSDS)”. The AeroSDS will demonstrate the feasibility of a passive system providing aerodynamic stability for a CubeSat below 350 km of altitude. 45 A Thermal Protection System for a Re-Entry CubeSat P. Testani, M.E. Umit, V. Van der Haegen, T. Scholz, I. Sakraker, G. Baillet von Karman Institute for Fluid Dynamics, Rhode-Saint-Genèse (Brussels), Belgium QARMAN (Qubesat for Aerothermodynamic Research and Measurements on AblatioN) is a 3U CubeSat designed to collect scientific data during re-entry to Earth atmosphere. The thermal design of the QARMAN CubeSat, with special attention to the re-entry phase, is a major topic. In fact during the atmospheric re-entry, the CubeSat will interact with the atmosphere at hypersonic velocity and, due to aerodynamic heating and exothermic chemical reactions, it will face temperatures which can go over 2000 K. Protecting the CubeSat components from those heat fluxes is one of the most critical aspects of the mission: designing a TPS capable to protect the satellite within the standard dimensions of a 3U CubeSat, is a challenging and delicate task. After a preliminary study, the QARMAN team efforts were oriented to protect only those components necessary to complete the re-entry phase of the mission, designing a “Survival Unit” capable to keep the electronic components within the operative limits for the entire re-entry phase. Nevertheless this design shall be thermally compatible with the orbital thermal environment as well. The design solution presented shows the implementation of the Survival Unit, where only the components supposed to survive the re-entry phase are placed. For this design solution different thermal analyses have been performed. The cases run embrace the hot and cold worst cases for orbital phases and the worst case scenario for the re-entry phase. 46 A tool for nano-satellite functional verification: comparison between different in-the-loop simulation configurations L. Feruglio1, R. Mozzillo1, S.Corpino1 and F. Stesina1 1 Politecnico di Torino, IT This paper describes the simulator technology and the verification campaign for the e-st@r CubeSats family, developed at Politecnico di Torino. The satellites’ behavior has been investigated using a Model and Simulation Based Approach. One of the critical issue in the verification and validation of any space vehicle is the impossibility to fully test some features due to the particular and often un-reproducible environment in which it will operate. Simulations result as one of the best means for testing space system capabilities as it may help to overcome the abovementioned problem. In order to perform different simulation configurations for e-st@r CubeSats, an in-house simulator (named StarSim) has been developed. It is a unique infrastructure, modular and versatile, capable of supporting any desired configuration of the system under test, ranging from full algorithm in the loop simulations (AIL), and gradually inserting satellite hardware, until a complete hardware in the loop (HIL) simulation is performed. When a verification campaign is led on a real object, pure AIL computer based simulations (in which all the equipment and mission conditions are reproduced by virtual models) are not sufficient to test the actual software and hardware to a high degree of confidence since real systems can exhibit random and unpredictable dynamics difficult to be perfectly modeled (i.e. communication delays, uncertainties, and so on). For these reasons, Software In The Loop (SIL), Controller In The Loop (CIL) and HIL simulations were planned. SIL simulations foresee that algorithms are written in the final programming language and executed on ground hardware. In CIL simulations, the software runs on the flight processor while other system’s element are still kept virtual. In HIL simulation, the real hardware (i.e. sensors, actuators, and power sources) are included in the loop. In this paper, after the details of the simulator architecture and its characteristics are described, an exhaustive comparison between AIL and HIL simulations is presented, highlighting main differences and singularities: similar trends of the sensible system’s variables are reached but not identical performances (i.e. absolute and average pointing error and stability, attitude determination accuracy, battery charging and discharging duration) arose analyzing the values. Moreover, it is demonstrated how the technology here presented can effectively support and improve the verification and validation activities for a nano-satellite, by increasing the confidence level on the mission objectives achievement. 47 Telecommunications, Ground Stations, Ground Station Networks 48 Development of an Open Source Software Defined Radio M. Wegerson1, J. Straub2, S. Noghanian1, R. Marsh2 1 Department of Electrical Engineering, University of North Dakota, USA 2 Department of Computer Science, University of North Dakota, USA The Open Prototype for Educational Nano-satellites (OPEN) is a CubeSat design being developed by a faculty-mentored student group at the University of North Dakota. Its primary goal is to create a lowcost, dependable satellite framework that can be utilized for a variety of missions. When completed, this design will be available to universities around the world allowing them to focus on research and development of the primary mission payload and less on designing the satellite’s supporting subsystems. In aliment with this goal, a software-defined radio (SDR) unit is being implemented for the satellite’s primary radio. This should facilitate greater versatility in space-ground and ground-space communications. The novelty of this SDR design is that it is based off of the use of the Raspberry Pi micro-computer as the primary transmitter and a USB FM Radio receiver containing the Realtek RTL2832U chip as the primary receiver. Through the use of open source software, the Raspberry Pi has the ability to transmit FM signals ranging from 1 MHz to 250 MHz. In addition, a USB Radio receiver allows for reception of frequencies from 24 MHz to 1766 MHz. Current work to date includes working with the software that allows the Raspberry Pi to transmit and working with GNU Radio to set up a working SDR receiver with the USB Dongle. Work began several months ago with setting up the USB TV tuner for reception of FM radio signals. Although there was some initial challenges with interfacing the USB device with GNU Radio, we were successful at receiving basic FM signals in November 2013 and have since been working towards improving the GNU Radio flow chart with the addition of several dynamic filters and data management systems. Work towards the transmitter has focused mainly on developing the Raspberry Pi into a functioning transmitter. For this we are using two open-source programs to modulate and transmit the data: minimodem for modulation and PiFM for transmission. Minimodem is a program that converts binary data into a modulated audio signal using AFSK (audio frequency shift keying) and outputs a .wav file. This file is then in turn transmitted by PiFm via GPIO pin 4. After the audio file has been received, it is decoded by minimodem back into its original format. Several issues we have faced is PiFm dependence on the operating system. Slight changes and updates to the operating system that alter the way programs interface with the Raspberry Pi sub-systems drastically affect the usability of PiFm. Currently, we are using Arch Linux as the control OS and have been successful at transmitting data at 300 and 1200 baud. Due to limitations on the Raspberry Pi’s transmitting abilities, the square wave is generated for the FM output. To counter the odd harmonics that are generated, we have designed a low-pass filter on the transmitter side to remove these unwanted transmissions. Currently, we have a filter tuned for 144.39 MHz but we are actively researching a method for a variable filter design to allow for a greater range of transmittable frequencies. In addition, we also have been working on developing improved, low-cost antenna and amplifier designs to improve the power of the transmitted signal. 49 CubETH COM subsystem F. Belloni1, A. Ivanov1,L. Van Box Som1, G. Laupre1, V. Richoz1 1 École polytechnique fédérale de Lausanne, Lausanne, Switzerland CubETH is a joint project of Swiss Federal Technical schools (ETHZ and EPFL) with the PI form ETHZ and supported by Universities of Applied Science. The main objective is to build a satellite scheduled for launch in 2016. The CubETH spacecraft will be capable of calculating its own position in space with unprecedented precision thus paving the way for nano-satellite constellations with inter-satellite communication capabilities. Compared to the Swisscube, the first Swiss satellite, the amount of data generated is considerably increased and new fastest communication boards have been designed. The old design approach using analog discrete components has been replaced with digital IC design. This allowed to simplify the PCB design thanks to the reduced RF electronics, to reduce the PCB used surface thanks to the smaller amount of components. This can permit to design a fully redundant communication system on a single CubeSat PCB board. In addition to improved reliability, we implement error correction. For uplink a BCH decoding and downlink Reed–Solomon and convolutional encoding. Due to the low processing power available a special attention to this task is required. The goal is to have a hardware that can communicate at data rate higher than 9.6 kbps, with the power consumption in Rx mode lower than 100 mW and a with a sensibility better than -110 dBm. 50 Enhancements of antenna control and an error correction scheme for the CubETH Ground Station S. Kaufmann1, R. Müller1, M. Joss1, M. Klaper2 1 Lucerne University of Applied Sciences and Arts (HSLU), Dpt. Electrical Engineering, Horw (Lucerne), Switzerland 2 Lucerne University of Applied Sciences and Arts (HSLU), Dpt. Computer Science, Horw (Lucerne), Switzerland CubETH, a scientific pico-satellite, is currently under development. Its main mission goal is to measure its position in space and exact attitude with a high degree of accuracy, using commercial off-the-shelf (COTS) GNSS receivers. One of the tasks of HSLU is to implement the ground station. As it is the case in almost every satellite project, the downlink is of high mission priority. This lies in the nature of not having sufficient power onboard to transmit information at high power levels. Also there are limited opportunities for high-gain antennas. Naturally, this results in receiving very low power levels down on earth. The same is the case with CubETH. Thus, back on ground, the incoming signal needs to be received with as much gain as possible. Therefore, four 22 element UHF Yagi antennas are stacked to get a high antenna gain. However, with high gain, the antenna system needs to point exactly towards the angle of the incoming signal. During the pass of the satellite, the antenna system needs to be continuously updated in azimuth and elevation angles by means of closed-loop control. In order to generate an error signal for controlling the movement of the antenna system, the concept of beam splitting and radar monopulse technique is used. The downlink antenna array is excited out of phase so that the main beam of the radiation pattern can be split. Combined with the sum signal of all four UHF antennas, a meaningful error signal can be provided. The results show, that it is possible to operate the 435 MHz antenna movers in a closed loop control. On the other hand, a professional space link conforming to ECSS/CCSDS standards brings some important advantages. The main one is the forward error correction feature. The CubETH space link features a binary BCH block code for the uplink and a concatenated coding system for the downlink. The concatenated coding system uses the Reed-Solomon block code as outer and a ¾-rate convolutional code as inner code. This well performing and reliable coding system has evolved over time to its best. A good example of its convincing capabilities can be given by looking at the voyager spacecrafts, which are yet the furthermost travelling objects engineered by mankind. They use a similar coding system to the CubETH. The mentioned coding system is implemented in the CubETH TMTC modem, which is a software only solution. Together with the soundcard of a PC, it is possible to link to transceivers very universally and ham-friendly via an audio FSK interface signal. By the presented two measures the net data rate can be improved. 51 SUSat Communications System W.G. Cowley1, H. Soetiyono1, R. Luppino1, T. Kemp1, J. Kasparian1 and F. Ishola2 1 Institute for Telecommunications Research, University of South Australia, Mawson Lakes, Australia 2 International Space University (ISU), Strasbourg SUSat is a two-unit CubeSat designed for the QB50 project by the University of Adelaide and the University of South Australia. At UniSA, the Institute for Telecommunications Research (ITR) is responsible for the SUSat communication system, including ground station. SUSat will use the 70 cm and 2m amateur radio bands for communications with ground stations and other QB50 CubeSats. This paper describes a custom communications payload design for SUSat. To meet demanding power and mass constraints in the CubeSat the baseline design is based on the use of a COTS FSK/ MSK RF IC. An additional power amplifier provides over 20dBm RF power. The design has several novel features, including: the addition of a balanced modulator to allow BPSK transmissions, a new layer-2 protocol called SKLEP to avoid the use of AX-25, channel coding options to reduce bit errors, plus flexible data rates and transmit/ receive duty cycles, plus GPS-synchronised frame timing to improve efficiency. The SUSat CubeSat also includes a custom module for the UHF and VHF antennas. The ground station will use a software defined radio (SDR) approach. The paper provides an overview of the SUSat communications system design and describes current status and test results. 52 Antenna Subsytem of GAMALINK Platform V. Akan, C. Dudak TUBITAK Space Technologies Research Institute, Turkiye Nowadays, there is a remarkable interest to CubeSats as they offer cheap and easy platforms for research, technology demonstration, scientific and educational space applications. Usual functions like attitude determination and control, uplink and downlink telecommunications, and power subsystem are performed in a Cubesat. GAMALINK is a platform that adapts the terrestrial communication and attitude determination technologies into space applications based on Software Defined Radio (SDR) hardware. The main goal of the platform is combining and integrating the miniaturized modules which will perform for mobile adhoc networking, attitude determination, GPS signal receiving, intersatellite and ground station communication from the existing terrestrial technology. The entire design has been made taking into account the CubeSat constraints and the space environment. On GAMALINK platform, there exists different designs leading the developed modules, relating fields of RF electronics, antenna, acquisition and signal processing. In order to save transmission power, beamforming will also be used by combining RF electronics and antenna modules for communication. Since most of CubeSats use amateur UHF band (about 437 MHz) for their communication, it provides very limited bandwidth. To increase the communication bandwidth, ISM S-Band has been chosen for high-speed data transmission and related communication. This communication is not only applicable between CubeSat and ground station but also among CubeSats in a network. For beamforming capability 3 S-band Antenna element array is used. Each S-Band Antenna has 24mm x 24mm x 3.2mm maximum dimension to fit onto 2U surfaces. Moreover, for receiving GPS signal there is one antenna whose dimension is 28mm x 28mm x 3.2mm on each lateral panel. Since major intended challenge of GAMALINK is fitting the modules into Cubesat, miniaturization techniques have been utilized for S-Band and GPS antennas. 53 A Simple Miniaturized Printed Antenna Adaptation for CubeSats and Small Satellites S. Kose, V. Akan, C. Dudak, E. Oncu TUBITAK Space Technologies Research Institute, Turkiye Today small satellites and CubeSats are very popular since they provide fast and cheap platforms for technology demonstration, experimental research, educational purpose, etc. However there are some restrictions like physical limitations. To overcome this difficulty subsytems and modules should be as small as possible. This case is also valid for antennas which are initial/final elements of RF communication systems. In the literature, there are five general antenna miniaturization techniques: Geometrical Shaping (slot loading, bending and folding, meandering, and etc.), Material Loading (using with dielectric and magnetic material), Lumped element loading, Optimization Methods (Genetic Algorithm, Particle Swarm Optimization, and etc.), Miniaturization using artificial engineered electromagnetic metamaterials. In this manuscript, a miniaturized microstrip antenna via geometrical shaping has been analysed to use on CubeSats and Small Satellites. The analyzed circularly polarized antenna has been simulated on a full-wave electromagnetic simulator and then a prototype has been manufactured on Rogers TMM6 substrate with a relative permittivity of 6.0 and a thickness of 5.08mm and a loss tangent of 0.0023 and tested. The simulation and test results are in good agreement. The achived antenna size is 30mm x 30mm. Measurements and simulations have been realized on a 100mm x 100mm ground plane to model 1U CubeSat surface. 10-dB return loss bandwidth and peak gain have been measured to be approximately 100 MHz and 7dBic at the operating frequency through S-Band, respectively. 54 Development of an X-Band Transmitter for CubeSats S. Palo1, D. O’Connor2, E. DeVito2, R. Kohnert2, S. Altunc3 and G. Crum3 1 Department of Aerospace Engineering Sciences, University of Colorado, Boulder, CO USA Laboratory for Atmospheric and Space Physics, University of Colorado, Boulder, CO USA 3 Goddard Space Flight Center, NASA, Greenbelt, MD USA 2 CubeSats have developed rapidly over the past decade with the advent of a containerized deployer system and ever increasing launch opportunities. These satellites have moved from an educational tool to teach students about engineering challenges associated with satellite design, to systems that are conducting cutting edge earth, space and solar science. Early variants of the CubeSat had limited functionality and lacked sophisticated attitude control, deployable solar arrays and propulsion. This is no longer the case and as CubeSats mature, such systems are becoming commercially available. The result is a small satellite with sufficient power and pointing capabilities to support a high rate communication system. Communications systems have matured along with other CubeSat subsystems. Originally developed from amateur radio systems, CubeSats have generally operated in the VHF and UHF bands at data rates below 10kbps. More recently higher rate UHF systems have been developed, however these systems require a large collecting area on the ground to close the communications link at 3Mbps. Efforts to develop systems that operate with similar throughput at S-Band (2-4 GHz) and C-Band (4-8 GHz) have also recently evolved. In this paper we outline an effort to develop a high rate CubeSat communication system that is compatible with the NASA Near Earth Network and can be accommodated by a CubeSat. The system will include a 200kbps S-Band receiver and a 12.5Mbps X-Band transmitter. This paper will focus on our design approach and initial results associated with the 12.5Mbps X-Band transmitter. 55 Multi-objective optimization of a high gain, circularly polarized rectangular antenna array in the Ka band for CubeSat class satellites Alessandro Cuttin1, Livio Tenze2, Roberto Vescovo1 1 Università degli Studi di Trieste, Dipartimento di Ingegneria e Architettura 2 Esteco S.p.A., Area Science Park Over the last decade, more than one hundred CubeSats have been launched, and this number will double very soon. However, the increasing number of launched satellites is not yet followed by an improvement in the communication technology they use: to date, the majority of orbiting CubeSats transmits their data using frequencies allocated in the radio amateur service. A reasonable explanation for this scenario is that most organizations face their very first experience in the space sector and, therefore, prefer to use more reliable and simple solutions. Communication systems featuring faster data rates are generally employed after the first mission. If this trend does not change in favor of more advanced technologies, this class of satellites will not be considered a viable solution for commercial purposes, and thus relegated to the role of educational tool or technology demonstrator. The transition to higher frequencies, like those in the Ka band, will enable the design of small and directive antennas, and will make faster data rates attainable -- up to 100 Mbps. In the nanosatellites development, an antenna can be very demanding in terms of mass and real estate; efficient radiators such as horn antennas or parabolic reflectors in most cases are not viable solutions because of their mass and surface requirements. An ideal antenna should be thin, flat, small, light and designed to be mounted on the outer surface of the spacecraft. In this context, a microstrip array antenna is a convenient solution in terms of size, mass, mounting and cost. The proposed antenna will be circularly polarized and will have a uniform polarization over a wider bandwidth, respect to the bandwidth of the basic element. In the design of this array, many parameters are subject to optimization: specifically, gain and bandwidth shall be maximized, while the axial ratio and insertion losses shall be minimized. These parameters can be optimized at every stage of the design: for the single patch, the sub-array, and the final array. In order to identify the best compromise possible between physical parameters and electromagnetic performance, a multi-objective optimization approach will be adopted, using a CST MWS® parametric model together with ESTECO’s modeFRONTIER® multi-objective optimization and process integration tool. Numerical results will be illustrated. 56 KSAT light – a low cost ground station network for CubeSats B.Eilertsen1, M.Krynitz1 1 Kongsberg Satellite Services AS, Tromsø, Norway As Cubesats are becoming more and more potent, data rates from their payloads are increasing quickly. This calls for using S-, X- or Ka-band transponders as on bigger satellites. KSAT, a leading supplier of commercial ground station network services is currently bringing online a brand new network of small aperture antennas specifically adapted to the cost- and performance requirements of the small satellite market. The new service, KSAT light, is initially composed of antennas ideally situated for serving polar orbits. The locations at Svalbard (Arctic), Tromsø (Arctic) and TrollSat (Antarctica) ground stations, provide the ability to communicate with, and download data from satellites practically two times per orbit (26 out of 28 possible daily passes). The polar sites will be complemented with low inclination sites as, where and when user community demand develops. The new network is operated in parallel with the larger diameter antenna network which remains indispensable to customers with higher requirements in terms of download bitrates and absolute availability. The antennas used work in S-, X- and Ka-band and have a diameter of 3.7 m. At the same time, and closely associated with the idea of a high efficiency, low operational complexity network, KSAT is rolling out an interactive web-based interface allowing the customer to instantly visualize available pass opportunities across the entire network, book the passes and handle payments and queries, all through a state of the art, intuitive graphic user interface. KSAT light offers high quality and dependability and gives small satellite operators access to a reliable ground station network without the need for initial investment as the pricing structure is entirely based on a “pay as you use” approach. This minimizes financial risk for small satellite operators in case of unexpected failures, short mission duration or premature end of mission. KSAT light makes using high data rates for CubeSats easy and affordable. 57 Challenges and Solutions for the QB50 Telecommunication Network G.March1, T. Scholz1, J. Thömel1, P. Rambaud 1 and S. Marcuccio2 1 2 von Karman Institute for Fluid Dynamics, Rhode-Saint-Genèse (Brussels), Belgium Aerospace Division of the Department of Civil and Industrial Engineering, University of Pisa, Italy QB50 space mission will provide the biggest CubeSat network in orbit. A constellation of 50 CubeSats in a ‘string-of-pearls’ configuration will be launched together in January 2016 by a single rocket, into a circular orbit at 380 km altitude. Due to the atmospheric drag the orbit will decay and progressively lower layers of the atmosphere will be explored. Main goals are exploration of the lower thermosphere with multi-point measurements, re-entry research and in-orbit science and technology demonstration. In this analysis of communication functions the ground segment is analyzed, with a global overview of different architectures, the main elements of a ground station, mission and control centres, and the link between them. This study is realized through the development of a tool which computes the number of stations required to recover a certain amount of data generated by a constellation of satellites. This tool ensures the efficiency of the communication system taking into account various design parameters like data rates, limited elevation angles from ground stations, and the effects on the link quality such as orbit perturbations, space and atmospheric losses and Doppler shifts. Particular attention is devoted to frequencies: two different types of systems (UHF/VHF and S-band) are analyzed. In order to optimize the positioning and number of stations, an iterative method is applied to compute the fraction of time when a station is in view of a CubeSat in function of various parameters such as the latitude of the station, its elevation and the altitude of the satellite. AGI-STK software was used to compute the access between satellites in the constellation and ground stations, simulating system operability. Starting with a gradual approach, the analysis begins by ideal study of the communication behaviour between one CubeSat and a single ground station at VKI. After the selection of the communication system architecture, author introduced the constellation concept, introducing also related considerations due to communication overlaps between close satellites. Through this gradual investigation was possible to increase the analysis complexity, having a detailed analytical description on communication behaviour, and finding reliable results, which are extremely useful for mission accomplishment. 58 CubeSat Flight Experience Lessons Learned 59 Lessons Learned from Four Months of UKube-1 in Orbit: A Software Perspective P. Mendham, M. McCrum Bright Ascension Ltd, Scotland, UK UKube-1 launched successfully on the 8th July 2014 and contact was made with the satellite shortly after launch. At the time of writing this abstract the platform commissioning phase is in progress, and there have been several interesting challenges to overcome during this period. As providers of the flight and mission control software we have been involved with the UKube-1 project for more than two years and a unique perspective on the mission. As the only team which spans both flight and ground segments, from interfacing on board to satellite operations, we have learned many useful lessons. This presentation reviews the mission development from a software perspective and presents a number of key recommendations for other projects. We begin by presenting an overview of the satellite development process, highlighting some of the many challenges of UKube-1 and their implications on the system, and especially software, engineering. These include the diverse payloads, demanding operational requirements and organisational challenges from the large number of collaborating teams. We specifically focus on the spacecraft test process and operations rehearsals, describing the evolution of the mission operational concept. Next we describe the development of the ground segment architecture, centred around RAL Space at Harwell in the UK. We describe the operational challenges and our software solutions, ranging from automation for attended operations to a low-cost functional simulator. Finally we describe the LEOPS and commissioning process and examine the reality of our various software systems in use. Rather than going into technical detail, we describe each solution at a high level, presenting the implications for the mission and recommendations for others. 60 The QB50 precursor flight: Status, preliminary results and lessons learned Z. de Groot, J. Elstak, E. Bertels, J. Rottevee1 ISIS – Innovative Solutions in Space BV On the 19th of June 2014, a Dnepr launch vehicle including the QB50 deployment system delivered the two QB50 precursor satellites into their designated orbit. The two spacecraft, QB50p1 and QB50p2, have been developed during an extremely compressed schedule. The on-ground development and test phase was finalised within 6 months and the launch took place in under 9 months from the kick-off of the project in October 2013. The QB50 precursor team consists of ISIS – Innovative Solutions in Space, who is responsible for system engineering, spacecraft design, Assembly, Integration and Verification (AIV) and the launch campaign including the deployment system; Surrey Space Centre (SSC), who are responsible for the Attitude Determination and Control System (ADCS); Mullard Space Science Laboratory (MSSL), who are responsible for the Ion & Neutral Mass Spectrometer (INMS) Science Unit; Technical University Dresden (TUD), who are responsible for the Oxygen Flux Probe (FIPEX); Ecole Polytechnique Federale de Lausanne (EPFL), who are responsible for the Satellite Control Software (SCS); Astrium GmbH, who are responsible for PA support; Von Karman Institute (VKI), who are responsible for the thermal analysis and the Qarman thermocouple payload; Amsat Francophone and Amsat NL, who both delivered a radio amateur communications payload. The aim of the QB50 precursor mission is to de-risk key parts of the QB50 project and to learn valuable lessons on the spacecraft and payload design, AIV and operations. This ensures that the participating QB50 teams in the main mission can benefit from the lessons learned and experiences gained during the precursor flight and thus minimizing risk in this challenging project. In addition, as QB50 will occupy the radio amateur bands for a significant portion of the available spectrum during its mission (however brief), the precursor satellites allowed AMSAT payloads to be embarked on the satellites as a ‘returnfavour’ to the radio amateur community for using their spectrum. Since launch, the early operations and commissioning has focussed on getting both satellites in a stable situation from a thermal, power, attitude and software point of view. Because of the extremely tight development schedule, it was decided to develop the majority of the full mission flight software after launch and subsequently using a software upload function to install the latest software images on the spacecraft once finalized and tested thoroughly on ground. This meant that the software on-board at the time of launch was limited to the most critical functionality. A lot of valuable information has been acquired from both satellites, showing information about for instance the temperature environment and power budget. Most progress has been made on commissioning the ADCS system and detumbling the satellites to a stable Y-Thomson spin and commissioning of the payloads is currently about to start. This presentation will explain the current status of the precursor flight, show preliminary results and discuss the lessons learned for the QB50 main flight. 61 QB50 Precursor ADCS Flight Results L. Visagie1, V.Lappas1, W.H. Steyn2 1 Surrey Space Centre, University of Surrey, Guildford, UK 2 Stellenbosch University, South Africa The QB50 ADCS (Attitude Determination and Control System) will provide attitude sensing and control capabilities to 2U CubeSats in order to meet the QB50 system requirements. CubeSats in the QB50 constellation require attitude control in order to minimize the influence of drag and to ensure science payloads point towards the ram direction. The QB50 ADCS makes use of a combination of magnetometer, sun and nadir sensor measurements and a MEMS rate sensor to estimate the current attitude. It uses magnetorquers and a single reaction wheel, operating as a momentum wheel, to stabilize and control the attitude of the satellite. The QB50 Precursor mission aims to de-risk a number of technologies and programmatic aspects of the main QB50 mission. The ADCS module is one of these technologies – each of the 2 precursor CubeSats carry one of the QB50 ADCS modules, and operation of the precursor satellites involve commissioning of the ADCS and stabilization of the platform by active control. In the first few months, valuable experience has been gained in commissioning and operation of the ADCS modules. In this presentation, the in-flight results of the precursor ADCS will be presented as well as the problems that were experienced and lessons learnt. 62 A Worldwide Survey on the Regulatory and Economical Aspects of NanoSatellites D. Andoni1, S. Cabrera1, K. Kornfeld1, P. Maier1, A. Raposo1, C.O. Asma2 1 Space Generation Advisory Council, Wien (Austria) S-3, Swiss Space Systems, Payerne (Switzerland) 2 Development of nano-satellites is an emerging and key technological domain with more and more nano-satellites being readied for launch every year. Other than their educational and PR benefits, nano-satellites are also seen as complementary space technology platforms to bigger industrial satellites. This study, carried by Swiss Space Systems (S3) Department of Academic Projects and Space Generation Advisory Council project groups, aims at understanding and showing the diversity of a typical nano-satellite development, which would include technical, regulatory and economical aspects. The project aims at performing a worldwide study of the typical roadmap and considerations for the development of a nano satellite with an Earth-Observation payload. The development concepts are to be analysed from the point of technical development, space law and regulations, economics and business cases for the key technologies. Other than showing the diverse options for handling all the developmental issues, this project also aims at proposing a feasible roadmap for the future steps of the ‘small-scale’ organisations who would like to develop, test, launch and operate their small satellites. Answers will be sought for typical questions such as (but not limited to): What is the typical cost of a nano-sat development, broken into items such as hardware, human power, testing, launch, etc? What are the typical regulatory steps that are followed by the nano-sat developers? (existence of space law, registration, frequency allocation, definition of operator, definition of launcher stage, launch contract, ITAR, import/export licences, insurances, etc) What are the major differences among different countries/regions in terms of nano-sat regulations? How are the economic trends for development and the launch of nano-sats? Would it be possible to propose an optimized strategy for the development, launch and operations of the nano-satellites, taking into account the technical, regulatory and economic factors? 63 LituanicaSAT-1: lessons learned from the first Lithuanian cubesat mission L. Maciulis1, V. Buzas1, L. Bukauskas1, M. Dvareckas1, Z. Batisa1 1 Faculty of Mathematics and Informatics, Vilnius University, Lithuania LituanicaSAT-1 is a 1U CubeSat developed by Vilnius University. The primary objective of the mission is to provide university students and young researchers knowledge and real hands-on experience in satellite design, development, deployment and operations. Hence the process helps to develop infrastructure and know-how in space technology by interdisciplinary interaction between academia and industry in Lithuania. Following key technology demonstrations have been carried out during the mission: Low resolution visible wavelength imaging system based on the open-source Arduino platform Mode V/U FM transponder In-house built silicon solar cells Results from these technology demonstrations will be presented together with lessons learned from mission operations and project management perspective. Special attention will be given to the feedback received from amateur radio community that operated the FM transponder. LituanicaSAT-1 is one of two Lithuanian CubeSats to be Lithuania's first satellites in space. The satellite was launched from the International Space Station to space on February 28, 2014 by JAXA astronaut Koichi Wakata. 64 Lessons Learned from Developing and Producing Structure and Mechanical Systems for ESTCube-1 P. Liias1, E. Kulu2, M. Eerme1, P. Orusalu3, M. Noorma2 1 Tallinn University of Technology, Estonia 2 Tartu Observatory, Estonia 3 Protolab, Tartu Science Park, Estonia ESTCube-1 is a 1U CubeSat which was launched on 7th May 2013 whose subsystems were developed by students for educational purposes. It gave a unique experience and the educational outcome was much better compared to using commercial products. The development and production of structures and mechanical systems for nanosatellites generally receives little attention but there were many valuable lessons learned in ESTCube-1 project. ESTCube-1 frame is made from mono-block aluminium which was recommended by several persons and publications early in the project to save weight and achieve required tolerances more easily. Considering the production cost and complexity and the difficulty of systems engineering and satellite assembly it might not have been the best choice. To meet the delivery date of the satellite last minute changes to material selection had to be made. Some of the reasons were different legislative and material numbering systems in Europe and USA, delivery dates and finances. What we have learned is that problems caused by these kinds of changes may not come out during testing and can occur months after a successful launch, for example screws will be magnetised and disturb attitude control. Due to mission requirements a new antenna deployment system had to be developed for one side of the satellite which needed to also have solar cells. Finding a supplier for beryllium copper antennas and burn wire for the deployment was also challenging. For a long time ESTCube-1 had been expected to be launched with PSLV from India when an opportunity to launch with European Vega rocket emerged. Vega has much higher vibration levels during launch compared to PSLV which was unexpected. That put a lot of physical strain on the harness which held the satellite during vibration testing which broke several times and stronger ones were made after every test. It is a long process from planning of the mission to launching a spacecraft, but it could be done much more effectively when using the right methods, materials, manufacturing and testing. Learning from the lessons of ESTCube-1 we have now started the development of new structure and mechanical systems for the next missions of Estonian Student Satellite Program. Being part of the project since the beginning has given a very good experience which components, materials and coatings should be used to achieve a more streamlined development process. 65 Legal Aspects on CubeSats and Space Debris Issues N. Antoni Leiden University, International Institute of Air and Space Law Small satellites are designed mainly for scientific or educational purposes at a low cost with a small size and mass less than 500 kg. Many of them are based on the CubeSat standard and they are frequently launched in low Earth orbit, with an increasing number of them being launched the last years -and predicted to be launched in the near future- particularly into the Sun-synchronous orbit (SSO) at the altitude between 650 and 800 km. The major concerns that arise from these small satellite missions are the risks related to space debris creation in SSO and in-orbit collision with other space objects. At the altitude of 650 and above natural orbital decay decreases, and, as a result CubeSats remain in orbit longer than the life expectancy they are designed for. Currently, their small size and mass prevent them to be equipped with a propulsion system that would allow them to be deorbited and adhere to the 25-year in orbit lifetime limit as defined by COSPAR and also required by their design specifications. In addition to this, experience has shown so far a considerable failure rate of CubeSats launches either upon separation from the launcher or after a sudden break-up or loss of contact only within a few weeks or even days of operation in orbit. These non-functional small satellites are hazardous for the current and future inherently high risk operations in the near-Earth space environment which is much crowded and congested, especially after the collision of Cosmos 2251 and Iridium 33 satellites. The case of Cerise collision with an untraceable object 20 years ago, when the population of debris was even smaller, should draw our attention to this fact. Their inability to manoeuver and their very small size that might not be tracked could pose an imminent risk not only to the mission itself but also to other space objects that cannot exercise debris avoidance manoeuvres without having exact information of the location. The aforementioned risks might be multiplied and, thus, intensify the problem in the case of many CubeSats launched either in constellation or in formation flying in SSO, which will soon be the case. In order to mitigate the above risks, it is highly recommendable for the operators of CubeSats missions to comply with the voluntary UNCOPUOS Space Debris Mitigation Guidelines, which establish the legal basis for a sustainable development of outer space activities. In accordance with this legal framework CubeSats missions should be developed with the appropriate propulsion system that will allow them to be maneuvered in case of collision risk and deorbited after the mission lifetime ends without exceeding the 25-year rule. This will ensure the compliance of CubeSats operation with the corpus juris spatialis, in the interest and benefit of the international space community. 66 E-st@r-I lessons learned and their application G. Obiols-Rabasa1, S. Corpino1, R. Mozzillo1 and F. Nichele1 1 Politecnico di Torino, Torino, Italy CubeSats are characterised to be small and cheap platforms, born within universities with educational objectives. However, these systems are becoming more and more attractive for other missions, such as for example technology demonstration, science application, and Earth observation. This requires an increase of CubeSat performance and reliability, because educationally-driven missions have often failed. Nowadays, ESA Education Office is conducting its first edition of Fly Your Satellite! Program devoted to provide support to selected University CubeSat developers of ESA specialists for verification phase of their CubeSats. The goal of the initiative is to increase CubeSat mission reliability through several actions: to improve design implementation, to define best practice for conducting the verification process, and to make the CubeSat community aware of the importance of verification. Within this initiative, CubeSat team at Politecnico di Torino developed the e-st@r-II CubeSat as follow-on of the est@r-I satellite, launched in 2012 on the VEGA Maiden Flight. Both 1U satellites are developed to give hands-on experience to university students and to test an active attitude determination and control system. The present work describes the lessons learned gathered during e-st@r-I development and operations, and their application to improve the new CubeSat, from design to operations. In particular, design improvements have been applied to reduce assembly procedure complexity and to deal with possible on-board computer failures. ECSS rules have been considered to design and assess new procedures for the verification campaign, tailoring them when possible with the support of ESA specialists. Different operative modes have been implemented to deal with some anomalies observed during the operations of the first satellite; mainly leading to a new version of the on-board software. In particular, a new activation sequence has been considered to have a stepwise switch-on of the satellite. In conclusion, the know-how gained during e-st@r-I development and operations have been crucial for the development and verification of the e-st@r-II CubeSat. 67 Orbital Dynamics, De-orbiting And Debris Mitigation Techniques 68 The Aerospace Blockset for Xcos P. Zagórski1 1 AGH University of Science and Technology, Kraków, Poland Aerospace Blockset for Xcos is a free, open and extendable software tool for aerospace simulations. The project was developed thanks to ESA Summer of Code in Space initiative. It is under active development ever since 2012. From the very begging it was envisioned as a tool that fills the gap between the free purpose-driven aerospace software (eg. Space Trajectory Analysis, Gpredict), and the very expensive professional tools (eg. AGI STK, Matlab-Simulink). On the one hand anyone can download it and use it for free for any purposes. On the other hand it is based on a powerful CelestLab library developed by CNES and validated against true data and commercial simulation environments. It provides wide functionality including but not limited to: propagating satellite orbits, propagating planet orbits, conversions of reference and time frames, environmental models (Earth magnetic field, solar pressure, atmospheric drag, etc...), ground station visibility, unit conversions, attitude dynamics and quaternion algebra. It also provides real-time simulation capability to enhance ground station software suite. Aerospace Blockset is a part of an open source Scilab/Xcos environment, which provides many other compatible blocksets (FEM simulations, statistical analysis, etc.). It is also possible to freely modify and write your own blocks to extend the capability and customize the tool for own needs. Users who develop new functionalities are free to either keep them for themselves or contact the developers and include them in future releases. Its availability, capability, extendibility makes it a great tool for aerospace education and educational CubeSat projects. Additionally, as the blockset is based on visual programming concept user can not only perform complex simulations, but also better imagine and understand the nature of simulated phenomenon by studying relationship between the functional blocks. 69 LitSat-1 Decay Analysis V.Tomkus 1, D. Brucas2, D. Gailius3 , P. Kuzas3, A. Karpavicius3 and A. Vilkauskas3 1 2 Lithuanian Space Association, Vilnius, Lithuania Space Science and Technology Institute (SSTI), Vilnius, Lithuania 3 Kaunas University of Technology (KTU), Kaunas, Lithuania As CubeSat technologies get more and more popular due to its availability, low cost and short development cycle, Lithuania has also joined the countries operating their own satellites in the beginning of 2014 with two satellites LitSat-1 and LituanicaSat-1. LitSat-1 satellite has been developed as the test and demonstration platform for future mission, to analyse the possibilities and ways of constructing, launching and controlling CubeSats. Due to that the construction design was as simple as possible. Considering the further research of Attitude Determination and Control (parameters important for that), 1U satellite had a mass of 950 g, passive magnetic attitude control (permanent magnets and Permalloy), and three 10 mm wide communication antennas in VHF and UHF bands. The satellite was launched on 28th February 2014 from ISS (at an altitude of 420 km) together with 4 other CubeSats, and became one of the two first orbital bodies manufactured in Lithuania. After the extremely successful orbital experimental work, the satellite faced an extremely rapid (both in time and compared to other satellites launched at the same time) orbital decay with orbital life of only 83 days. Such rapid decay could be contributed to low ballistic coefficient of satellite (high drag and low mass), nonetheless it could not be explained only by the influence of aerodynamic drag. According to comparison of theoretical (computational) and experimental data it was determined that besides aerodynamic drag, the rapid decay of the satellite was caused also by passive magnetic hysteresis damping of the Permalloy having quite considerable influence on the dissipation of the kinetic energy . Due to relatively long two 145 MHz antennas the 1U Cubesat attitude was determined by the prevailing sum of aerodynamic and gravitational torque vectors combined with changing direction of the magnetic vector. It caused the complex behaviour and spinning of the satellite around the mass centre with average period of 18 s and remagneting of the Permalloy (mass of 6 g). According to the theoretical calculations such remagneting decreased orbital speed (and caused decay of satellite) by average Δv of 5x10-3 m/s per hour. These assumptions together with further analysis of data and comparison with other satellites (launched at the same time) will be given in the presentation. 70 In orbit testing of a de-orbiting sail on the Cubesat URSA MAIOR M. Valdatta1, N. Bellini1, A. Locarini1, S. Naldi1, D. Rastelli1, F. Piergentili2, F. Santoni2 1 2 NPC S.r.l., New Production Concept/Spacemind division, Italy CRAS, Centro Ricerca Aerospaziale la Sapienza, University of Rome “La Sapienza” Italy One of the most important innovations in space sciences, due to the recent increasing of cubesat based missions, is the possibility to have a low cost platform suitable for in orbit testing of new technologies. Many universities continue to build cubesats for educational purposes so that the number of these nanosatellites launched into space is rapidly increasing. Cubesats are, in general, not provided with a post mission disposal system to perform de-orbiting at the end of operative life. The result is an increasing number of space debris in a size range which is at the same time difficult to track and potentially destructive for operative missions. Moreover, typical cubesat features do not include active attitude and orbital control systems capable to perform a de-orbiting manoeuvre. The space on board of these nanosatellites is a particular issue especially for 1U cubesats, where usually all the available space is filled with the main subsystems of the satellite itself. Therefore, post mission disposal systems do not play a key role for operative life of cubesats and are not considered as design drivers. In case of existing de-orbiting guidelines becoming rules, a post mission disposal system would become mandatory for all satellites, including nanosatellites. For this reason, the Spacemind division of NPC Italy has designed and manufactured a de-orbiting drag sail which will be host onboard the 3U cubesat Ursa Maior part of the constellation of QB50. The sail is a square of 70x70cm based on the use of a polyurethane foam that can be stored in a little volume. Once the closing mechanism is released the sail returns to the original shape. The idea is to use the mission for in-orbit validation of the system. The post mission disposal device constitutes a stand-alone system with its own electronics and power resources, nonetheless a connection with the satellite power supply has been considered as a backup in case of failure. In general the sail is designed to guarantee the respect of the IADC guidelines for all the orbits commonly used in a nanosatellite mission. 71 A tether-based aerodynamic de-orbiting system O. Vallet1, C.O. Asma2 1 2 ELISA, ÉcoLe d’Ingénierie des Sciences Aérospatiales, Saint Quentin (France) Swiss Space Systems, Payerne (Switzerland) Keeping the near-Earth orbit in a sustainable condition is the main purpose of the 25 years lifetime rule for LEO (Low Earth Orbit) satellites. CubeSats orbiting under 600 km naturally respect the criteria but the others have to integrate a post-mission disposal system. The main issue is to deorbit the satellite with an efficient passive system, which will use minimal power, mass and volume resources. In this way, a “tethered sail” system is under study to efficiently allow the deorbiting of LEO CubeSats. The studied concept involves tethers or tether-like sails with a small mass at their tips, simply deployed from the satellite at the end of their functional lifetimes. With no rigid structures to maintain the drag area but by making use of the natural gravity gradient positioning of tethers, the deployment issues of common solar sails are reduced. The length of the system will only be metric scaled (not kilometric like usual tethers) which will lead to reduced deployment, orbital debris and oscillations issues. There is no use of any Electromagnetic or Electrodynamic effect, but only the drag capabilities. The system will be useful until the drag forces clearly prevail against the gravity forces. For a 3U CubeSat, the objective could be to reach 550km. From this point, when tumbling, the satellite re-enters within 4 years even in case of system failure. The improved area-to-mass ratio for such a system when applied on CubeSat makes it potentially interesting. The endpoints masses of the tether can be some of the satellite’s original subsystems (solar panels, structure…), in order to not launch useless mass in orbit. Presentation will approach the work under development of potential mechanisms, material, and results of the deorbiting system for different typical missions. 72 De-risking Active Debris Removal with CubeSat in-Orbit Demonstrations M. Richard, G. Feusier, R. Wiesendanger, C. Pirat, C. Paccolat, F. Belloni, D. Courtney* A. Pollini** D. Bovey, J. Buchli, M. Bircher*** * Swiss Space Center, EPFL, Switzerland ** HES-SO, Switzerland *** ETH-Zurich, Switzerland This presentation will be discussing the current results of the analysis performed in the frame of the ESA study « CubeSat Technology Pre-Developments, QB-50- Active Debris Removal”. Two mission scenarios utilizing CubeSat technologies for the main satellite subsystems have been investigated. These two missions are called CADRE, for CubeSat Active Debris Removal Experiment. The first CADRE mission scenario involves the demonstration of rendezvous sensor technologies and operations. The second CADRE mission scenario is targeted toward the demonstration of net deployments and flexible link (tether dynamics). Both CADRE missions assume the use of 6U (6 Units) to 8U chasers and targets of 3-4U, launched together in a 12U deployer. The analyses performed include a trade-off of the vision-based rendezvous sensors and of the radar technologies, net technologies, and also trade-offs at the CubeSat subsystem levels, especially for micro-propulsion. The outcome of these analyses includes conceptual mission and satellite designs, technology gaps identification and make-or-buy options, and a set of mission, system and technology requirements. One of the key aspects of the CADRE IOD is the scalability and applicability of the demonstration utilizing such small flight systems. These aspects are addressed for the rendezvous sensors (in the three primary functions of Debris Detection, Debris Identification and Debris Motion Reconstruction), for the Guidance, Navigation and Control, for the Net capture system and its dynamics, for the flexible link tether dynamics, and for the mission operations. Considerations and preliminary scalability conclusions will be presented. Current issues and limitations with such IODs will be discussed, as well as conclusions on the feasibility of CADRE missions. 73 CubeSat Networks and Constellations, Formation Flying 74 Space-based Ad hoc network: a solution for multiple satellite TT&C problem in QB50 project Pengfei Liu1, Lei Yang1and Xiaoqian Chen1 1 Institute of Space Technology, National University of Defense Technology, China For the QB50 project, 50 CubeSats will be launched and injected in 2016 into a 380km orbit to perform in situ observations of the thermosphere as well as science and technology in-orbit demonstration. Since most of these satellites have no position control, their orbit trajectories are mainly subject to pure orbital mechanics. Simply relying on the slight differences in orbital elements caused by in-orbit release mechanism, these satellites are not easy to drift apart in short periods after deployment. That is to say, more than one satellite would be located in the boresight range of one ground station antenna at the same time. Since some of the QB50 satellites may adopt the same up- and downlink frequency, the TT&C link would be affected due to co-channel interferences. How to keep an efficient TT&C channel between all the 50 CubeSats and ground stations during initial orbital periods is a difficult problem for the system design of this project, and is also the topic of this contribution. The idea to solve the multiple satellite TT&C problem in QB50 project by space-based ad hoc network is proposed in this contribution. An integrated system architecture of space-based ad hoc network is described. To support the rapid initial networking process of satellite cluster when just deployed by the rocket, a GPS aided network formation algorithm is presented. On the base of IEEE802.15.4 standard, a light-weight network protocol stack is designed with a cluster-tree routing algorithm and a smart network address distribution mechanism. Result from the simulation scenario built in OPNET has demonstrated the efficiency of our design. A system-in-loop platform is being built for further perfection of the system design. This paper describes technical details, hard- and software design, and also addresses some related results of this platform. 75 TW-1: A CubeSat constellation for space networking experiments Shufan Wu*,Zhongcheng Mu*,Wen Chen*,Pedro Rodrigues**, Ricardo Mendes** *Shanghai Engineering Centre for Microsatellites, Chinese Academy of Science, Shanghai, China **TEKEVER Space, Portugal In the past decade, Cubesat has gained more and more attentions in space communities, has evolved from purely educational tools to a useful platform for technology demonstration and scientific instrumentation, and has walked out of university labs into many potential applications. Networking and constellation with multiple Nanosats and CubeSats are foreseen an important direction for different applications. On this topic, two state of the art communication technologies, the software defined radio (SDR) based inter satellite communication and the ad hoc adaptive networking technologies, enter into the front stage. This paper presents a small space networking experiment mission (TW-1 project), to test and validate the new devices, and explore the cubesat space application based on the two technologies above discussed. The major technologies and related instrument or device modules to be used in this mission are GAMALINK, which is an S-band inter-satellite communication module, a novel dual band GPS/BD receiver, an AIS receiver, and an ADS-B receiver, all being designed based on SDR technologies. Also a novel cold-gas micro propulsion module based on MEMS technology will be used for orbit and constellation control. TW-1 project consists of three CubeSats carrying different payloads and instruments with one 3U CubeSat and two 2U CubeSats, to be put into an LEO orbit, forming an along-trace satellite network and/or constellation. It is designed and being implemented by a consortium led by the Shanghai Engineering Centre for Microsatellite in China, together with GomSpace from Denmark, Tekever Space from Portugal and NanoSpace from Sweden. The main tasks of this mission are listed in the following: Objective 1: CubeSats networking based on Gamalink; Objective 2: Monitoring sea ice and gaining the maritime traffic information in polar region based on AIS receiver and camera; Objective 3: Demonstration of autonomous formation flying including the along-track orbital (ATO) formation and the projected circular orbital (PCO) formation; Objective 4: In-orbit demonstration and validation of ADS-B receiver/ Gamalink / Micro-propulsion; Objective 5: Imaging the satellite separating process. 76 Status of the QB50 Project J. Thoemel, F. Singarayar, T. Scholz, C. Asma, P. Testani, D. Masutti, J. Muylaert, von Karman Institute for Fluid Dynamics, Rhode-Saint-Genèse, Belgium CubeSats have emerged to be recognized powerful tools for a new class of space missions. They have served many objectives and mostly to educate young space engineers by means of the hands-on design and manufacturing experience. The QB50 project aims at the use of the CubeSat concept to further facilitate access to space for the future generations, to conduct unprecedented science, to demonstrate new space technologies and also to provide training to young engineers. To this end, the Project, coordinated by the von Karman Institute for Fluid Dynamics, Belgium, has invited universities from all over the world to submit a proposal for a CubeSat to be embarked on the mission. The QB50 consortium is managing the mission and in particular it develops the deployment system, the common sensors that will be placed on all science satellites, and procures the launch service. In addition, it provides a number of key technologies and services such an attitude control system and a satellite control software. A number of such are being tested on the QB50 precursor mission. Started in November 2011, the project is now beyond the detailed design phase. All technologies developed by the consortium and community have appeared now at as hardware for display, demonstration, test or even flight purposes. The project now prepares for the assembly of the satellites and the deployment system. The QB50 consortium consists of the following partners: ISIS B.V. (NL), MSSL/UCL (UK), EPFL (CH), SSC (UK), B.USOC (B), TU-Delft (NL), IAP (D), DLR (D), Stanford (US), ITAM (Russia), NPU (China), Airbus (D/Fr), SSLLC (USA), VKI (B). Sensor Unit providers are UiO (Norway) and TU-Dresden (D). The project is partially funded by the European Commission Framework Program 7 Grant 284427 and by consortium and community CubeSat provided in-kind financial contributions. It has established Memorandum of Understandings with AMSAT (UK/NL/Fr), Aalborg University (Denmark) and the SGAC and received substantial support from governmental organizations such as BELSPO (B), BIPT (B) and the ITU. Most importantly the project consists of 50+ CubeSat developing teams. The highly motivated work of individuals and organizations is very much appreciated by the authors. 77 Attitude Determination and Control 78 Aalto-1 Nanosatellite Attitude Determination and Control System End-to-End Testing T. Tikka1, O. Khurshid1, N. Jovanovic1, H. Leppinen1, A. Kestilä1 and J. Praks1 1 Aalto University, School of Electrical Engineering, Helsinki, Finland In this paper we present a hardware-in-loop (HIL) test setup and usage designed for high performance Attitude Determination and Control System (ADCS) end-to end testing and validation for multi-payload Cubesat missions. The Aalto-1 mission requires accurate pointing of a miniature radiation monitor and a hyperspectral imager, and a 200 °/s spin-stabilized operation mode for an electric solar wind sail based plasma brake experiment. The satellite’s ADCS, iADCS-100 provided by Berlin Space Technologies (BST), contains sensors and actuators typically only seen in larger satellites: star tracker, gyroscopes, a magnetometer, magnetorquers and reaction wheels. In addition, six digital sun sensors and a GPS receiver are integrated to the system. To verify correct operation of the ADCS before launch, and to assure compatibility with the satellite’s scientific mission, a thorough testing campaign is currently being performed. BST conducts environmental qualification, functional testing and control algorithm testing, whereas end-to-end mission tests and acceptance tests are performed in Aalto University. The mission tests are carried out using a HIL test setup running an attitude and orbit dynamics simulator in Simulink xPC Target. The simulation provides real-time sensor data to the ADCS through an I2C interface according to simulated sensor and actuator models, mission operations and disturbances. By connecting the HIL setup to the ADCS while integrated to the rest of the satellite subsystems, even the most complex mission operations can be tested and validated end-to-end in a closely flight representative configuration. 79 Star Tracker Cost Reduction for Small Satellites Tjorven Delabie1, Joris De Schutter1, and Bart Vandenbussche2 1 Department of Mechanics, KU Leuven, BE Institute for Astronomy, KU Leuven, BE 2 In recent years, the great potential of small satellites has become ever clearer and small satellites are selected to perform increasingly complex missions. With this rise in mission complexity, the requirements on the Attitude Determination and Control System of the satellite increase as well. Of all the attitude determination sensors, the star tracker is by far the most accurate one. The accuracy of this sensor is in the order of arc seconds. The disadvantages of this sensor are that it is expensive, takes a considerable volume, and has a high power consumption. In this paper, we will discuss the star tracker developments that are currently being done at the KU Leuven University. These star tracker developments are part of the development of an ADCS for the SIMBA Mission, which is scheduled to launch within the QB50 campaign. In the first part of this paper we discuss how the novel star tracker algorithms developed at KUL can reduce the cost of the Star Tracker. Both the centroiding algorithm and the tracking algorithm have a significantly reduced computational cost, thanks to analytical solutions of the optimization problem. This can allow to save costs in the electronical hardware and will reduce the strain on the power budget. Furthermore, the star identification algorithm and tracking algorithm are significantly more robust to inaccurate measurements. This allows to yield high accuracy, even with lower cost components. The algorithms will be presented and we will focus on the increased efficiency.In a second part, we discuss the tests that are performed to analyse the performance of the star tracker. For small satellites, testing procedures are often not as standardized as they generally are for satellite missions. As the SIMBA CubeSat is currently being developed as ESA’s first CubeSat through an ESA GSTP project, the test campaign of the KUL star tracker will adhere as strictly as possible to the standards set by ESA. The procedures that are followed will be outlined in this paper and may serve as a guideline for future star tracker test campaigns. This may help to reduce the time and money needed to devise and set up a test campaign for future missions. Since setting up a test campaign is often a serious strain on the manpower and financial budget, this could lead to a serious reduction in cost and lead time. An outlined procedure would also facilitate the comparison between different star trackers on the market and would allow small satellite developers to select the best star tracker for their mission. Both the novel star tracker algorithms and developed testing procedures will allow to make the accurate star tracker more accessible for small satellites. The increased attitude knowledge accuracy that this sensor brings to the satellite platform will allow small satellites to perform even more complex and interesting missions. This will again lead to new opportunities and new developments for this growing group of satellites. 80 ZA-AeroSat: A QB50 CubeSat demonstrator for multidisciplinary technology and scientific research M. Kearney1, W.H. Steyn1 1 Electronics Systems Laboratory, Stellenbosch University, Stellenbosch, South Africa CubeSats have proven to be valuable tools that can be used to satisfy a wide variety of commercial and scientific demands. ZA-AeroSat is designed with both of these goals in mind. The satellite is built by a team at the Electronic Systems Laboratory (ESL) at Stellenbosch University. It will be launched into a <400km Lower Earth Orbit (LEO) as part of the QB50 CubeSat constellation; an international project which is led by the Von Karman Institute for Fluid Dynamics (VKI). In terms of technology demonstration, the satellite will carry a variety of local South African CubeSat subsystems. The Attitude Determination and Control System (ADCS) of the satellite is the main subsystem designed by the ESL. This highly integrated, compact ADCS unit will be flown on-board more than 10 other QB50 satellites as their main ADCS. The first two units are flying currently on-board the QB50 precursor satellites, which serves as testing platforms for the technology being flown on QB50 satellites. The ESL developed star tracker, CubeStar, will be flown as payload and possibly used as part of the ADCS system. The satellite will also feature ESL designed mechanics in a deployable magnetometer and deployable 2U solar panels. These solar panels will be deployed to a specific angle, chosen to provide optimal power to the satellite throughout the entire range of Local Time of Ascending Node (LTAN) values the satellite will experience. This is a particular challenge considering the significant LTAN variation due to its fast decaying LEO orbit. Communications hardware built by a local partner, Cape Peninsula University of Technology (CPUT), will also have its maiden flight on board ZA-AeroSat. ZA-AeroSat will carry 3 scientific payloads. The first is the QB50 FIPEX science unit. The sensor will measure atomic oxygen in the lower thermosphere. This will, among other uses, serve as validation for current atmospheric models. Further, it will monitor the temperature of the different surfaces of the CubeSat to compliment the science data collected. The second scientific payload is the satellite’s featherlike antennas. The 4 VHF/UHF antennas will act as passive aerodynamic stabilization elements, while simultaneously enabling a communication link between the satellite and the ground. The satellite will use its ADCS unit in combination with these antenna feathers to control its orientation to within 5 ͦof its orbital velocity direction throughout the mission lifetime. Lastly, the satellite will carry a scientific experiment which aims to utilize a novel method to measure gravitational waves. This device will be able to measure the gravitational effects of the earth, sun and moon. 81 Attitude Control Simulation Using Variable Speed CMG for 3U CubeSat H. Kim1, H. Lee1, and Y. Chang2 1 Space System Research Laboratory (SSRL), Korea Aerospace University (Goyang), Republic of Korea 2 School of Aerospace Engineering, Korea Aerospace University (Goyang), Republic of Korea Control Moment Gyros (CMG) help small satellites become more agile and manoeuvrable. CMG has been implemented for CubeSat recently as the hardware miniaturization is feasible and its use in small satellite is being steadily increased. KAUSAT-5, a 3U CubeSat under development by Korea Aerospace University, will implement an advanced Variable Speed Control Moment Gyro (VSCMG) to demonstrate its capabilities in orbit. VSCMG is able to generate torques by changing flywheel speed with fixed gimbal. This research is regarding attitude control simulation according to each of the operation modes of KAUSAT-5 with a mounted VSCMG. One of KAUSAT-5’s missions is to demonstrate VSCMG in a space environment for future applications. Gimbal angles need to be determined using relative encoder in the early phase of the satellite, because they can become biased by vibrations in a launch environment. After that, gimbal angles should be reoriented using null motion for their regular operation. In mission mode, attitude control for targeting a desired point on an uploaded schedule is performed. In this study, the attitude control modes for each operation mode of KAUSAT-5 are defined, and equations of motion are derived with nonlinear techniques by considering structural properties, CMG specifications, and the CMG cluster configuration of KAUSAT-5; adaptive control laws at each operation modes are also suggested. Attitude control simulation is performed based on the derived equations of motion and control laws under MATLAB/Simulink. The paper also shows through numerical simulation that the designed control laws are applicable to ultra-small satellites. 82 The piNAV-L1 – The World’s First Ultra Low Power CubeSat GNSS Receiver J. Laifr1 1 SkyFox Labs, Prague, Czech Republic The piNAV-L1 is the World’s First Low Power Space-Friendly CubeSat GNSS receiver specially designed to provide continuous accurate position determination in LEO onboard small satellites or high altitude balloon missions with limited power and mass budgets. It requires only a fraction of power (150 mW maximum) in comparison with conventional space-grade GPS receivers allowing permanent 1 Hz data output within typical 1-Unit CubeSats. Easy-to-use serial (UART) data interface output providing standardized NMEA messages together with external GPS antenna provides a smart standalone solution for all kind of space-grade projects where the precise position, time, date and velocity information is needed. The PPS (Pulse-perSecond) and PF (Position Fix) signals are available on System Interface connector to indicate the receiver status. Ultra low mass and dimensions (753511 mm) fits perfectly with all kind of space-demanding satellite projects. Additional aluminium radiation shielding is delivered with the Space-Grade Flight Models (FM). High altitude, high velocity Engineering Model (EM) with identical mechanical and electrical properties is available with software limitation at reduced pricing. The receiver has been successfully tested onboard the stratospheric balloon flight up to 35 km of altitude and the space flight test is scheduled for the winter 2015. 83 In-House Magnetic Field Simulator For Cubesats M. Balan1, C. Dragasanu1, M. Pripasu1, S. Radu1, C. Cherciu1, M. Trusculescu1 1 Institute of Space Science, Magurele (Bucharest), Romania The presentation presents a three axis controlled Helmholtz cage designed as an attitude determination and control test bed for CubeSat type nanosatellites. Having a useful testing volume of approximately 30 dm3 and a maximum designed magnetic field intensity of 150 μT for each pair of coils, the cage can simulate the entire range of LEO orbits. Starting from the coil design mathematics, the paper presents in detail the magnetic field measuring and control equipment chain. Initially, the magnetic field intensities values along the orbit are determined by using STK software and translated in real time to current intensities on each pair of coils. Moreover, a custom SGP4 orbit propagator is implemented and the magnetic field intensities value can be obtained by IGRF interrogation. The system can work in most common configuration where the magnetic field is generated in an Earth inertial reference frame or Earth Centered Earth fixed reference frame simulating in this way the magnetic field vector. Moreover, a detumbling test mode has been implemented. In this mode, the satellite rotational matrix is added to the satellite trajectory in the STK simulation scenario and the magnetic intensities on each axis are generated in the body reference frame. The magnetic field computed in this way is generated with the cage having the satellite fixed inside. This rapid variation field is used to trick the satellite magnetometer and observe the satellite behavior in the detumbling operational mode. The cage is powered from a current source with a resolution of 0.1 mA which makes possible the obtaining of 10 nT of magnetic field increments on each axis. The cage control can be done in an open loop configuration by supplying a proportional current or with a tri-axis magnetometer used as sensor for the control loop. The paper concludes with the experimental data obtained during the cage magnetic environment characterization and the zero offsets determinations. 84 Active magnetic attitude control algorithms for CXBN-2 CubeSat M. Ovchinnikov1, V. Penkov1, B. Malphrus2, K. Brown2, D. Roldugin1 1 Keldysh Institute of Applied Mathematics of RAS, Moscow, Russia 2 Morehead State University, Morehead, KY, USA Magnetic attitude control system for CXBN-2 satellite is considered. The goal of the CXBN-2 mission (follow-up of successful CXBN) is to increase the precision of measurements of the Cosmic X-Ray Background in the 30-50 keV range to a precision of <5%. CXBN-2 has already been selected for flight through the NASA ElaNa Program and will be launched in 2016-2017. Control system should provide possibly maximum number of data sets for the payload and possibly even celestial sphere coverage. Absolute minimum data volume is million seconds of scientific data per year. The main source of data loss is sensor sensitivity to high-energy illumination from close sources. Earth, Moon and Sun blanket exposure in case located in sensor field of view. The sensor itself is resistant to this illumination and is not damaged, however the data are lost. Four different control strategies are proposed and studied. They are assessed according to a number of criteria, ranging from the scientific mission requirements to engineering and mathematical robustness of a system. Following modes are studied: 1. Spin-stabilized satellite with regular spin axis rotation. The satellite is considered axisymmetrical one, payload sensors are perpendicular to the spin axis. This provides continuous rotation for sensors field of view. 2. Spin-stabilization with Earth avoiding. Spin axis is always directed roughly to the local vertical. 3. Spin-stabilized with solar panels charging and Earth avoiding. Satellite faces the Sun for half an orbit to provide battery charge. Then it moves to local vertical stabilization. 4. Free-flying satellite with speed control. This regime provides no specific attitude. Angular velocity is affected only, the satellite should keep rotating to cover full sphere. Free flying with occasional (de)tumbling is proved to be the best solution in comparison with different spin stabilization schemes. Although the simulations modeling the free flying concept of operations will result in less effective sky coverage near the polar regions, this is not anticipated to be a problem given that the science data is expected to be less usable in these regions. The expected scientific data gain is present. 85 Characterisation of Hysteretic Dampers for Passive Attitude Control of CubeSats D. Ivanov1, V. Penkov1, D.Roldugin1, M. F. Barschke2, K. Briess2, N. Kupriyanova1 1 Keldysh Institute of Applied Mathematics of RAS (Moscow), Russia 2 Technische Universität Berlin, Germany As many CubeSat mission scenarios do not require active control of the satellite’s attitude, passive attitude control is considered an efficient solution due to its simplicity. Such systems typically consist of a strong permanent magnet and hysteretic damper made by a special soft magnetic material with low coercivity and high magnetic permeability at low external field intensity that reaches saturation in the geomagnetic field. The magnet aligns the satellite to Earth’s magnetic field lines, whereas the damper is required to reduce the oscillation. Magnet and damper must be carefully matched in order to ensure proper functioning of the system. While dimensioning of the permanent magnet is comparatively simple, the damping capabilities of the hysteretic damper are not only dependent on the amount of material used, but also on the shape of the damper. Therefore experiments are required to determine the actual damping properties for a certain design. Technische Universität Berlin developed a hysteretic plate damper for passive satellite attitude control within the BEESAT CubeSat series. While a plate shaped damper was expected to be less preformat than a rod system, it is significantly easier to integrate, since it has the same form factor as the satellite’s electronic boards. Within the framework of a bilateral agreement, characterization of prototypes of this damper was conducted at the Keldysh Institute of Applied Mathematics. This paper presents the results of theoretical study and laboratory experiments on hysteresis plates and rods that were conducted to obtain and compare their damping capabilities. Coercivity, permeability and saturation remanence of various damper designs were derived from an experimentally determined hysteresis loop curve of the damper. These properties were then used to estimate the ohmic and hysteresis energy dissipation at different angular velocities. In order to evaluate and compare the effectiveness of the different damper designs, the obtained properties were used for numerical simulation of CubeSats equipped with different dampers for various angular velocities. Hereby, a comprehensive collection of suitable design, carefully adjusted to different use cases is presented. 86 A Constrained Attitude Control Method for Aoxiang-Sat R.Liu, H.Chen, Y.Liu, X.Yu and J.Zhou Shaanxi Engineering Laboratory for Microsatellites, Northwestern Ploytechnical University, Xi’an, China Aoxiang-Sat is a 12U CubeSat aimed at performing scientific and technological experiments in-orbit and scheduled to launch in 2015. It is an interdisciplinary, interdepartmental effort that has involved over 30 teachers and students, researched by Shaanxi Engineering Laboratory for Microsatellites of NPU. The main goals of the Aoxiang-Sat are detecting the skylight polarization patterns and measuring gravity. These main tasks request the satellite to be earth-pointing and three-axis stabilization. The Attitude Determination and Control Subsystem (ADCS) is the precondition of fulfilling all kinds of tasks. Many commercial products are selected to complete attitude tasks. In order to meet the targets of being cheaper and lighter, the numbers of sensors and actuators are as few as possible. The sun sensor we used has a field of view (FOV) of 60 degree. Orbit analysis indicates that at least three sun sensors are needed to achieve the attitude demands. Finally, three sun sensors, three gyros and three magnetometers are selected to accomplish attitude determination, three flywheels and three magnetorquers are used as actuators. The ADCS of Aoxiang-Sat can realize functions such as earth-pointing, sun-pointing and three-axis stabilization. Since the Aoxiang-Sat just has three sun sensors, there are many cases that the sun can not be seen. This paper presents an attitude control strategy for three-axis stabilization CubeSat with constrained FOV of sun sensors. For the sake of stabilization, sun acquisition must be done first, which is the first difference from common methods. Attitude determination begins after sun sensors capture the sun. The results of attitude estimation are used to undertake attitude stabilization. An attitude path is programmed to ensure that the sun sensors can track the sun all along the maneuver, which is the second distinction from others. Simple but effective control law is applied to decrease the load of On-Board Computer and to guarantee high reliability. Numerical simulations demonstrate the effectiveness of the proposed attitude control strategy. 87 Future Technologies on CubeSats 88 Characterization & Design of Solid State Hinges for Deployable Cubesat Structures Elbara Ziade* ([email protected]), Calvin Patmont* ([email protected]), Nathan Darling ([email protected]), Theodore Fritz* ([email protected]) Center for Space Physics, Boston University, Boston MA USA * Authors contributed equally to this work The success of the university-developed CubeSat specification has already demonstrated the broad impact that a simple, robust and modular satellite bus has on military, civilian and private industry spaceflight endeavors. In addition, the economic benefits of configuring and qualifying commercial off-the-shelf (COTS) technology for space applications continues to increase the popularity of Cubesat missions. However, as Cubesats evolve their electronic and instrument complexity to achieve more sophisticated endeavors, the constrained power budget has to be met by using either more expensive solar cells that are outside a Cubesat budget, or by incorporating deployable solar panels to increase the sun-facing surface area. Often small satellite teams design an in-house solar panel deployment system because available space-rated deployment systems are too expensive. Therefore, there is a need to design an economical deployment system that is within a Cubesat financial constraints. Our response is a scalable and configurable hinge for popular Cubesat sized satellites. In lieu of the common pinned-joint torsional-spring hinge - which must account for the effects of thermal expansion, galling, cold welding and lubrication in a vacuum environment - we have developed a “solid-state”, or a non-linear single-component hinge. Through a novel off-planar arrangement of COTS spring steel strips, we have designed a self-actuating, self-guiding, and self-locking hinge; while circumventing the risks associated with the pinned-joint scheme. In this paper we investigate the dynamic response of the spring steel hinge to find: 1) the momentangle relationship the hinge places on common solar panel form-factors; 2) the impulse that the locking solar panel places on the satellite structure; 3) and the damping coefficient internal to the hinge. These are obtained through a combination of tests on typical 1U, 3U and 6U Cubesat solar panel form-factors. We performed benchtop static tests that measure the static-moment vs deployment angle; and dynamic zero-gravity tests on a NASA reduced gravity flight that measure the dynamic moment vs. deployment angle and dampening time. Using the results, a satellite engineer is able to configure a spring steel hinge for his/her solar panel’s form factor and attitude determination capabilities, without extensive testing requirements. 89 Autonomous Command and Data Handling System for a 3U CubeSat L. Feruglio1, R. Mozzillo1, S.Corpino1 and F. Stesina1 1 Politecnico di Torino, IT Over the last few years, increasing efforts have been spent by the scientific community on enhancing the autonomy of a space mission, both concerning ground and space segment. Different solutions have been proposed, from satellite procedure execution languages, which aim to reduce the chances of operator mistakes and improve monitoring, to the implementation of on-board autonomous capabilities, for health keeping, efficient resource optimization, communication planning, and more. The paper presents the Command and Data Handling (C&DH) subsystem of 3-STAR, a 3U CubeSat project currently under development at Politecnico di Torino. The program started to take part in the GEOID constellation promoted by the European Space Agency, but it later evolved to be used also as a stand-alone technology innovation platform: this is the reason why the satellite is being developed keeping in mind future adaptation to different types of payload. In this sense, the 3-STAR C&DH design features algorithms for autonomous decision making and healthkeeping, based on functions of pattern recognition and intelligent machine learning. A mission case study for 3-STAR is presented, showing a comparison between traditional mission and envisaged autonomous operations, highlighting critical aspects of both technologies and detailing the improvements gained through the use of artificial intelligence on-board. In addition, the architecture of the C&DH, described using model-based representation, is depicted for both the on-board hardware and the algorithm itself. Results show how boosting on-board autonomy can greatly improve mission reliability especially for CubeSats, where a continuous communication link cannot always be granted, and where the teams involved cannot usually allocate many human resources to the ground control station. In addition, onboard autonomy allows to satisfy mission operation design criteria that would be significantly more demanding using traditional approaches: fast response to critical events, relevant telemetry downlink, on board scheduling optimization, are among the features that will be within reach of an increasing number of teams, especially, but not limited to, university ones. 90 Early Orbit Phase of Deployment Mission of Inflatable Membrane Structure of Nano-Satellite ''SPROUT'' K. Mita, M. Yamazaki and Y. Miyazaki Department of Aerospace Engineering, Nihon University, Japan The authors have been developing a nano-satellite named SPROUT. SPROUT is a 20 x 20 x 22 cm amateur radio nano-satellite with a mass of 7.1 kg, launched successfully with the Synthetic Aperture Radar (SAR) satellite ALOS-2 on May 24, 2014. In recent years, space structure, such as a solar sail and a communication antenna, are becoming larger. But the payload of a rocket has limits on the volume and the weight. Inflatable membrane structure is very attractive for space structure because it is lightweight and compact. But it has not been verified sufficiently in space so far. The main mission is to demonstrate the deployment of a combined membrane structure (1.5m-sided triangular membrane supported with two inflatable tubes). SPROUT will take the images of the deploying shape of membrane by two cameras. The image date will be compared with those of the ground experiments and numerical simulation. Thereby, we estimate reliability of the results of analysis. In this presentation, the author introduces the initial operation results, operation plan based on the initial operation results and detailed system of the membrane deployment mechanism. M onopole antenna (x4) 210 .0[m m] Sun sensor (x6) Camera(x1) Camera(x2) 1500[mm] x y m] .8[m 214 Before M embrane Deployment y x M embrane z 15 00 [m m ] 220.0[mm] z 60deg Solar cell (x30) I nflatable tube(x2) After M embrane Deployment 91 Implementation of an On-Board Computer & a Modem into a Single Subsystem for CubeSat M.E. Bas1, M.S. Uludag1, I.E. Akyol1 , M.D. Aksulu1,M.Karatas2 and A.R. Aslan2 1 2 ERTEK Space Sys. Co., Istanbul, Turkey Istanbul Technical University, Istanbul, Turkey The importance of CubeSats has been increasing dramatically in the last decade due to their short development time and cost effectiveness. Since there are constraints for the volume and mass of the CubeSat, it is critical to reduce the space consumed by the mandatory subsystems. The main purpose of this study is to develop a joint subsystem, which includes an On-Board Computer and a UHF/VHF Modem which is developed by ERTEK Space Systems Co.; thus, leaving more space for scientific units and payloads. BeEagleSat is a 2U CubeSat, which is being developed with the cooperation of various universities and industrial corporations, within the context of the QB50 Project. The payloads of the BeEagleSat are MNLP, which is going to be supplied within the context of the QB50 project, and the X-Ray detector, which is being designed in-house with the cooperation of ITU and Sabanci University. The OBC part of the joint subsystem, is constituted of an ARM based 32-bit microcontroller, a memory unit, and failsafe precautions such as; an external watchdog timer and buffers for communication buses. The OBC will control the other subsystems in accordance with the flight algorithm. The communication between the OBC and the other subsystems can be established through various communication protocols (i.e. I2C, SPI, UART). The Modem part of the joint subsystem is used for data communications and telecommand. SI4463 RF ICs are responsible for RF side of modem. The received data will be processed and handled by the same ARM-based microcontroller. The RF parameters (e.g. frequency, modulation type, gain control) are adjustable through the OBC software via API of SI4463 IC. The used data protocol is compatible with the AX.25, which is a commonly used by radio amateurs. The modem is also capable of transmitting and receiving data simultaneously. The data rate will be 9.6kbps for UHF band and 1.2kbps for VHF band. The joint subsystem will both control the CubeSat subsystems and will be in charge of transmitting and receiving data from the ground station. By comparison to the currently available, separate Modem and OBC subsystems, this joint subsystem is more cost & mass effective and space saving. 92 BIRDY: an interplanetary CubeSat to collect radiation data on the way to Mars with a precursor flight around the Earth in GTO Boris Segret1, Jordan Vannitsen2, Marco Agnan2, Audrey Porquet3,4,5, Oussema Sleimi2, Jim Lin2, Damien Boisseau2, Florent Deleflie3,4,5, Jiun-Jih Miau2, Jyh-Ching Juang6, Kaiti Wang7 1 2 Laboratoire d'Etudes Spatiales et d'Instrumentation en Astrophysique, (LESIA), Observatoire de Paris, Meudon, France National Cheng Kung University, Department of Aeronautics and Astronautics, Tainan, Taiwan 3 Institut de Mécanique Céleste et de Calcul des Ephémérides (IMCCE) Observatoire de Paris, Paris, France 4 Centre National de la Recherche Scientifique (CNRS), France 5 6 7 Université Pierre et Marie Curie, Paris, France National Cheng Kung University, Department of Electrical Engineering, Tainan, Taiwan National Cheng Kung University, Institute of Space and Plasma Sciences, Tainan, Taiwan BIRDY is a 3-Unit CubeSat that is piggy-backed on a host mission to Mars and jettisoned at the beginning of the journey. Then it operates in full autonomy: no assistance, no communications but a beacon signal. The mission profile is a new contribution in Space Weather monitoring and an opportunity to assess the risks in the manned missions to Mars. It counts energetic particles in the maximum range 1 MeV/nucleon to 1 GeV/nucleon. The ground segment prepares a fine-tuned trajectory to be stored on-board, on the basis of the planed trajectory of the host mission that provides the main delta-V but not the ideal path. It makes the CubeSat compatible with almost all missions going to Mars. During the cruise, the CubeSat relies on an optical planet tracking system to locate itself and on small electrical thrusters to adapt its trajectory and perform the exact flyby at Mars that permits to come back to the Earth. The science data are collected all along the journey and only uploaded once in Mars' vicinity to one of the existing Martian orbiters or rovers, and once at the arrival back to the Earth. A BIRDY protoflight model is expected to be ready for a precursor flight around the Earth in GTO by 2018 in order to test the innovative functions of the mission such as the autonomous navigation and communications subsystems. More widely than its own scientific mission, BIRDY demonstrates a new way to gather data from distant locations in the solar system. The project is an educational space mission, essentially leaded and designed by students from different educational levels in France and in Taiwan. 93 Target Shape Identification for Nanosatellites using Monocular Point Cloud Techniques Mark Post, Xiu-Tian Yan Space Mechatronic Systems Technology (SMeSTech) Laboratory, Department of Design, Manufacture and Engineering Management University of Strathclyde, 75 Montrose St, Glasgow, G1 1XJ, UK Many mission scenarios for nanosatellites and CubeSat hardware have already been created that will require autonomous target tracking and rendezvous maneuvers in close proximity to other orbiting objects. While many existing hardware and software designs require the use of rangefinders or laser-based sensors to identify and track nearby objects, the size and power limitations of a CubeSat make a simple monocular system greatly preferable, so long as reliable identification can still be carried out. This presentation details the development and testing of an embedded algorithm for visually identifying the shape of a target and tracking its movement over time, which can include rotation about any axis. A known three-dimensional geometric model is required for use as a reference when identifying a target. First, feature descriptors implemented in the OpenCV framework are used to create a sparse point cloud of features from a nearby object. Using structure-from-motion (SfM) methods, feature points obtained over successive images can be triangulated in three dimensions to obtain a pose estimate. Statistical shape recognition is then used to identify the object based on features from available three-dimensional models. While more feature points make the identification more accurate, more computing power is required, and within the limitations of an embedded system, the balance of speed and accuracy is evaluated. The algorithm is designed to be efficient enough for feasible operation using embedded hardware useable on a CubeSat, and can be used with appropriate hardware for real-time operation. An overview of the algorithm and vision system design is given, and some initial test results for a simulated orbital rendezvous scenario are provided for some indication of the performance of these methods. Applications of interest for this type of algorithm include external monitoring of other spacecraft, robotic capture and docking, and space debris removal. 94 Posters 95 QBITO, the first CubeSat by Universidad Politécnica de Madrid I.Barrios1, A. Laverón1 and E. Moreno1 1 Universidad Politécnica de Madrid, Madrid, Spain QBITO is the first CubeSat developed by Universidad Politécnica de Madrid (UPM). It is a 2U CubeSat and is one of the satellites that compound the project QB50 led by Von Karman Institute (VKI) in Belgium. The main task of QBITO will be to operate the Ion Neutral Mass Spectrometer (INMS) that is the primary payload on-board the CubeSat and that will study the properties of the lower thermosphere. The most outstanding feature of QBITO is the amount of new in-house developments that are present in the design. These include the structure subsystem, the Electrical Power Subsystem, the Communications subsystem and a novel antenna deployment mechanism. These new developments are complemented with Commercial Off-The-Shelf units in order to reach a robust, yet innovative, architecture. Apart from the INMS, QBITO will carry three other payloads in order to take advantage of the mission as much as possible. The first is an experiment that will assess the performance of the n-Octadecane as a Phase Change Material. It is being developed by the University of Liège. The second experiment, the Medium Wave Infrared Detector, is developed by the Spanish company New Infrared Technologies and aims at testing this kind of detectors, whose manufacture process is based on the Vapour Phase Deposited PbSe technology, in space conditions. Finally, the third additional payload, the Experimental Software, implements an attitude determination and control software whose algorithms are based on fuzzy control theory. The purpose is to test the suitability of this kind of control techniques for spacecraft attitude control applications. QBITO´s ground segment is composed by four ground stations. Two of them are placed in Madrid at the Spanish User Support and Operations Center (E-USOC) and Escuela Técnica Superior de Ingenieros de Telecomunicaciones (ETSIT). The other two are provided by Universidad Nacional de Ingeniería (UNI) in Lima and Universidad Nacional Autónoma de Méjico (UNAM) that are collaborating with the project. The CubeSat is currently being manufactured and tested by QBITO team which includes UPM staff, professors and students and it will be ready for the launch scheduled in January 2016. The team has also the support of the Spanish company SENER, which provides with technical support along the project and the access to its environmental test facilities. 96 A survey of CubeSats: Present status and trends Xiaozhou Zhu, Xin Song, Xiaoqian Chen and Yuzhu Bai1 College of Aerospace Science and Engineering, National University of Defense Technology, P. R. China Over a decade ago, Professors Bob Twiggs and Jordi Puig-Suari proposed the concept of CubeSats. Since then, CubeSats have gained comprehensive attentions from academia, industries and space agencies due to their low construction and launch costs, short research and development cycle, promising capabilities, and ubiquitous launch providers. As a result, the last decade had witnessed a tremendous surge in the number of CubeSats launched. And by the time this paper was written, more than two hundred CubeSats have been sent into space. In this paper, statistical analysis of CubeSats launched is conducted using data collected from a variety of sources to throw light upon the present status. Then, examples of a wide range of applications are provided, including scientific research, technology demonstration, communication, earth observation, etc. Finally, the potential future issues and development trends are explored. 97 Nano-SSoC: Low cost sun sensor for high accuracy attitude determination in CubeSats J. M. Moreno1, J. M. Quero2 and P. Castro1 1 2 Solar MEMS Technologies S.L., Seville (Spain) Department of Electronic Engineering, University of Seville (Spain) During the last years applications for CubeSats are rapidly diversifying, with increased use in the future for Earth observation and remote sensing. These platforms need accurate attitude determination and control systems (ADCS), therefore those instruments - solar panels, antennas and other hardware - have to be properly oriented in order to perform their functions. The Department of Electronic Engineering of the University of Seville and the spin-off company Solar MEMS have been developing sun sensors in satellite and industrial applications for many years. A new version specially intended for CubeSats and small platforms, called Nano Sun Sensor on a Chip (NANOSSOC) is a miniaturized two axis sun sensor capable of measuring the incidence angle of a sun ray accurately in both azimuth and elevation. The sensor consists of four quadrant photodiode fabricated monolithically in the same crystalline silicon substrate, including a transparent cover glass on the same silicon die to act as shield to prevent space radiation. The sunlight is guided to the detector through a window above the sensor, inducing photocurrents on each diode that depend on the angle of incidence. The novelty of this approach is that SSOC sensing element is based on MEMS technology to achieve high integrated sensing structures, providing high accuracy, robustness and size and weight reduction. NANO-SSOC have both analog and digital versions with interfaces fully compatible with most CubeSat structures and OBCs, with a dimensions around 2,0 x 1,5 x 0,5 cm, a mass close to 5 g and an accuracy better than 0.5º (3σ) in a 120º FOV. The device integrates electronic circuitry for signal amplification and conditioning. In addition to this, the digital NANO-SSOC version includes a microcontroller integrated for selecting, filtering and processing the amplified outputs, directly providing the sunlight incident angles via UART, SPI or I2C communications interface. A similar version of these sensors have already been integrated in NANOSAT-1B, launched in 2009, in SEOSAT satellite as a payload and in CEPHEUS CubeSat mission, which is planned for launch in the first half of 2016. 98 The RIBRAS Software System W. S. Lisboa, L. R. Hissa, L. R. Amaduro, L. G. L. Moura, R. A. de Carvalho and C. S. Cordeiro Instituto Federal Fluminense, Campos dos Goytacazes (Rio de Janeiro), Brasil The RIBRAS (Brazilian Integrated Satellite Tracking Network) system is a collection of softwares with the objective of controlling the network of ground stations that will receive the Brazilian satellites data. The ground stations will work in a synchronized fashion, following a previous generated working plan, to make sure that the maximum amount of data is collected during satellites’ overflights. The Software is organized into the master/slave communication model. Each of the Server (master) and Client (slave) packages has three modules: Scheduler, Distributor and Controller for the server, and Job Controller, Antenna Controller, and Communication Controller for each client - the ground stations. On the master side, the Scheduler is responsible for generating an integrated plan for tracking the satellites of a given constellation during a certain period of time - usually the time between the first and the last satellites. The Distributor divides the plan into specific jobs that will be dispatched to each correspondent station. Finally, the Controller will supervise the whole network functioning and is capable of analysing and re-starting the scheduling process if something goes wrong. On each station - the slave side - the Job Controller receives the incoming jobs, prepares their execution, and at the right time executes them. During a job execution, the Antenna Controller and Communication Controller will control, respectively, the antenna position and radio functioning. 99 VISION: A VIS-NIR atmospheric spectral imager operated from a triple CubeSat 1 D. Fussen, 1D. Pieroux, 1S. Ranvier, 1J. De Keyser and 1P. Cardoen, 1E. Dekemper, 1F. Vanhellemont and 2 H. Saari 1 Belgian Institute for Space Aeronomy, Brussels, Belgium VTT Microelectronic Systems, Tietotie 3, Espoo, P.O.Box 1000, FI 02044 VTT, Finland 2 The Visible Spectral Imager for Occultation and Nightglow (VISION) is a tuneable spectral imager active in the visible and near-infrared. It targets primarily the observation of the Earth's atmospheric limb during orbital Sun occultation. By assessing the radiation absorption in the Chappuis band for different tangent altitudes, the vertical profile of the ozone is retrieved. A secondary objective is to measure the deformation of the solar disk so that stratospheric and mesospheric temperature profiles are retrieved by inversion of the refractive ray-tracing problem. Finally, occasional full spectral observations of polar auroras are also foreseen. This miniaturized hyper-spectral imager will be carried as the primary payload of the PICASSO IOD CubeSat mission and it will be developed by VTT Research Centre in Finland. VISION is innovative in space applications for remote sensing and it will be based on MEMS-based Fabry-Perot Interferometer technology. This technology allows the imager to operate over a variable spectral range with a 10 nm spectral resolution whilst remaining physically compact. Optimisation of the VISION design for the PICASSO mission is expected to result in stratospheric ozone measurements to 5% accuracy with a vertical resolution of 2 km after post-processing. 100 FR03 EntrySat A.Sournac1, J. Chaix1, R.Garcia1, D.Mimoun1 1 ISAE France Entrysat has for main scientific objective the study of uncontrolled atmospheric re-entry. This project, is developed by ISAE in collaboration with ONERA and University of Toulouse, is funded by CNES, in the overall frame of the QB50 project. This nano-satellite is a 3U CubeSat measuring 34*10*10 cm3, similar to secondary debris produced during the break up of a spacecraft. EntrySat will collect the external and internal temperatures, pressure, heat flux, attitude variations and drag force of the satellite between ≈150 and 90 km before its destruction in the atmosphere, and transmit them during the re-entry using the IRIDIUM satellite network. The result will be compared with the computations of MUSIC/FAST, a new 6-degree of freedom code developed by ONERA to predict the trajectory of space debris. In order to fulfil the scientific objectives, the satellite will acquire 18 re-entry sensors signals, convert them and compress them, thanks to an electronic board developed by ISAE students in cooperation with EREMS. In order to transmit these data every second during the re-entry phase, the satellite will use an IRIDIUM connection. In order to keep a stable enough attitude during this phase, a simple attitude orbit and control system using magnetotorquers and an inertial measurement unit (IMU) is developed at ISAE by students. A commercial GPS board is also integrated in the satellite into Entry Sat to determine its position and velocity which are necessary during the re-entry phase. This GPS will also be used to synchronize the onboard clock with the real-time UTC data. During the orbital phase (≈1 year) EntrySat measurements will be recorded and transmitted through a more classical “UHF/VHF” connection. 101 Technical aspects of the SNUSAT-1 operation simulator J. H. Park1, J. Lim1, C. W. Kang1, M. Kim1, Y. D. Kim1, C. G. Park1, H. J. Kim1, S. Kim2 and I.-S. Jeung1 1 Department of Mechanical and Aerospace Engineering, Seoul National University, Korea 2 Department of Biomedical Engineering, Seoul National University, Korea As one of the development process of SNUSAT-1, a simulator has been put together in order to perform analysis on operation sequence and satellite state. The fundamentals of the simulator runs on orbital dynamics including perturbation effects due to geopotential, atmospheric drag, solar radiation pressure, and third-body, modelled using EGM96 geopotential coefficients, Jacchia77 atmosphere model, and van Flandern ephemerides model. Fourth order Runge-Kutta method is implemented as the main integrator. Quasi-inertial reference frame, orbital reference frame and body reference frames are implemented for attitude simulation, with SNUSAT-1 physical characteristics such as its shape or subsystem elements represented in vectors within the body frame. Operation analysis includes the operation sequence, such as solar panel deployment or detumbling and control, communication with ground stations, power generation and consumption and various states of SNUSAT-1. The analysis is performed by implementing power model, ADCS models, and time-stamped operation sequence. The work describes the technical aspects in detail with descriptions of assumptions made for certain models and its parameters suitable for operation simulation. 102 A Review of Attitude Determination and Control Subsystem of a Nanosatellite Parth Garg1, Hitesh Agarwal1 and Pinakin M. Padalia1 1 Birla Institute of Technology and Science, Pilani, Rajasthan, India Advances in highly reliable commercial electronics, miniaturization techniques and materials have enabled university student teams to design, build and launch nanosatellites. Nowadays nanosatellites have proved significant as a technology test bed for the Universities. The mission success is critically dependent on the reliability, consistency and accuracy of spacecraft. The attitude determination and control system is important to autonomously orient the spacecraft and control the vehicle. The increase in mission complexity drives the need for a more precise ADCS. The lessons from previous ADCS designs have proved to be valuable for future mission designs, testing and integration. The purpose of this paper is to elucidate the process of designing phase of ADCS by taking help from previous cubesats missions. The paper presents review of ADCS designs of five successful cubesat missions namely Aausat3, Swisscube, Rax, Delfinext and Cubestar on the basis of hardware selection of sensors and actuators for pointing as well as stabilization purpose and intricacies involved in the design electronics. The satellites were chosen on the basis of mission success and testing of new capabilities in the ADCS design. The paper helps the beginners to get an insight of the various components of the ADCS and their interconnections. It helps the experts to review different ADCS designs and come up with the best combination of sensors, actuators and algorithms for their requirements. It also focuses to help the reader in evaluating different hardware and software for the ADCS on the basis of power, cost, size, weight and the harsh space environment. The paper gives a general idea of various stabilization and pointing methods implemented in previous missions according to the level of control requirements. The estimation and control algorithms are compared along with their advantages and limitations. With the detailed system design of the reviewed satellites, the paper also provides their experiences and modifications made by the designers in their successor satellites. Hence an attempt is being made to provide the readers with a structured approach in designing ADCS. 103 Simple and robust algorithm for CubeSat attitude estimation P. Zagórski, A. Tutaj, T. Dziwiński AGH University of Science and Technology, Kraków, Poland One of the crucial problems concerning control of artificial Earth's satellites is determination of the spacecraft spacial orientation. Accurate attitude estimate is required for example for precise communication antenna pointing. The estimation problem is particularly challenging for very small satellites (eg. CubeSats), where large and expensive sensors like star trackers are impractical. In the following paper a computationally inexpensive Quaternion Steepest Descent Attitude Estimator (QSDAE) algorithm is presented. It is designed to take advantage of minimal number of arguably the simplest measurements that enable attitude estimation. For this purpose two vector quantities have been selected: the measurement of the Earth's magnetic field vector and the relative gyroscopic (MEMS) measurement of satellite angular rate. Both of those measurements can be obtained by cheap, lightweight and energy-efficient sensors. Additionally estimator does not require knowledge of satellites inertia tensor, shape or size. The paper presents derivation of the algorithm and realistic computer model of the environment and measurements. Results of several simulations and computer tests are included. A procedure of estimator tuning balancing convergence and noise rejection requirements is proposed. 104 New Star Identification Algorithm Using Ring Projection and Vector Sum Ki-Duck Kim, Su-Jang Jo, Hyo-Choong Bang Korea Advanced Institute of Science and Technology, Daejeon 305-701, Republic of Korea In this paper, a new identification algorithm using ring projection transform (RPT) and vector sum is proposed for small satellites. The proposed algorithm is one of the pattern recognition methods among several categories of star identification algorithms. Vector sum, which is created from a ring projection transform, has rotation invariant characteristics. Also it represents a pattern as very simple imaginary value. Therefore, star identification can be performed using the captured with reduced amount of database. Many researches about ADCS (Attitude Determination and Control System) of small size satellites have been actively studied in the current satellite area. These small satellites have constraints on using star trackers because of its size. Limited performance of flight computer causes smaller database capability and low-speed operation. Miniature star trackers for small satellites require an algorithm, which can identify star rapidly under restricted database condition. Also, CMOS (Complementary Metal-OxideSemiconductor) active pixel devices are frequently used for miniature star trackers rather than CCD (Charge-Coupled Device) because of the low power consumption and high update rate. However, the image Noise of CMOS active pixel devices is relatively larger than CCD images. Consequently, a robust identification algorithm is important to use CMOS devices for small satellites. Vector sum using ring projection transform is a well-used method in image pattern matching area. Calculated vector sum from images becomes a one imaginary value. Only two values, which are its norm and phase angle, are required in the final comparison step. High identification speed and low amount of database are expected with this identification algorithm. Identification failure, which can be occurred by employing the Cartesian coordinates can be avoided with vector sum algorithm because its rotation invariant characteristics. Using this approach, the robustness for low quality images could be achieved. 105 Technological experiments on-board the URSA MAIOR nanosatellite L. Arena, F. Piergentili, F. Santoni, B. Betti, F. De Cesare, F. Nasuti, M. Onofri Sapienza Aerospace Research Center (CRAS), University of Rome “La Sapienza”, Rome (IT) The Sapienza Aerospace Research Center (CRAS) is involved in the design and manufacturing of the nanosatellite URSA MAIOR (University of Rome la SApienza Micro Attitude In ORbit testing), scheduled for launch in January 2016 as one of the Cubesats selected in the framework of the QB50 mission, leaded by the Von Karman Institute for Fluid Dynamics. In addition to the mNLP QB50 scientific payload, a drag sail deorbiting system for nanospacecraft and a cold gas microthruster for attitude control will be tested on board. The drag sail is made of a special polymeric material. This material works like a memory shape or elastic material. A sample of this material can be compressed and stored in a small volume. Once the compression is removed, the material expands again to its original shape. After the deployment, this sail will use the drag force to deorbit the spacecraft. A first prototype has been realized at Alma Mater Studiorum – University of Bologna. It passed both vibration and thermo-vacuum tests. The main goal of the cold gas microthruster experiment (MEMIT – MEMS MIcroThruster) is to test a new integrated MEMS (Micro Electro Mechanical System) valve-nozzle system. The whole system is designed to fit in less than a 1/2 U of the CubeSat. The cold gas propellant is nitrogen at ambient temperature. The MEMS nozzle and valve are manufactured by means of innovative techniques: the present MEMS nozzle has an axis symmetric geometry and it is controlled by a MEMS valve which works mainly like an electromagnetic valve. The micropropulsion test consists in providing a constant thrust for a given amount of time and measuring the angular velocity induced by the thruster on the CubeSat by means of the gyroscopes. The electronic control system is designed to survive on-orbit for the entire mission (at least one year). It coordinates all the telemetry information to be sent to the radio (currents, voltages, temperatures, earth magnetic field strength, satellite angular velocities and sun vector orientation) and the payloads operations. It is based on a multi-microcontrollers and FPGAs cold redundancy scheme. This allows both to enhance the overall satellite reliability and to test on-orbit the endurance of different electronics technologies (microcontrollers and FPGAs of different brands). 106 The FIRST-S Project: technical challenges V. Lapeyrère, S. Lacour, L. Gauchet, S. Arroub, R. Gourgues, and G. Perrin Laboratoire d'Etudes Spatiales et d'Instrumentation en Astrophysique (LESIA), Observatoire de Paris, France The FIRST-S project is an astronomical project in the context of exoplanet detection. The goal is to measure the amount of exozodiacal light scattered by dust around bright nearby stars. To do this we need high dynamic range (103) at moderate resolution (arcsec). The proposed instrument is 30 cm baseline stellar interferometer with nulling capabilities based on a LiNbO3 active optic on a 3U CubeSat. This nulling technique is currently developed in laboratory, and is suitable for a nanosat application. The challenging parts of this project are to control the injection of the light in a single-mode fiber with a accuracy of 1 arcminute and to control the optical path difference between the two arms of the interferometer at the level of few nanometer, while the CubeSat stability is about 0.1°. A three stages control solution is proposed. The first stage is the pointing and stability capabilities of the ADACS system of the CubeSat, reaching 0.1° accuracy. The second stage is to mount the fiber on a three axis piezo nanopositioner controlled via a position sensing diode. We now reach an accuracy better than 1 arcminute (the star light is properly injected into the fiber) and an OPD accuracy of 1µm. The last stage is to control the optical phase difference to the nanometer and to scan the null fringe using the active part of the LiNbO3 component. The interferometer itself is used as an OPD sensor. With these 3 layers of control we can reach the accuracy in terms of pointing and OPD control. 107 The GOSMOZ Project, an Innovative CubeSat Development Platform F. Jordan1, J.-M. Jordan1, J. Harris1, B. Chapuis1, J. Iseli1 and J. Selz2 1 2 ELSE SA, Carrouge, Switzerland EPFL Space Center, Lausanne, Switzerland Experience has shown that high-quality CubeSats (like SwissCube) are very custom-designed mainly because of their high system integration. Therefore, they cannot be easily used as platforms for new payloads. A system-level approach focusing on innovations that change the way of building and developing CubeSats led to the creation of a new development platform. This project, called GOSMOZ, not only is a very useful tool for the next generations of CubeSat developers; it also represents the first family of Swiss-made products available on the CubeSat market. The feasibility and success of the next generations of CubeSats will increasingly depend on a very good budget control. Starting CubeSat development from the very beginning is expensive and such cost quickly becomes a showstopper. With a very efficient development platform at the disposal of developers, the budget can be better controlled. The first objective of the study was therefore to determine which innovative technologies or mechanisms would help to drastically reduce the duration and risks of the development, the integration as well as the testing of a CubeSat. The study shows how it is achievable by dividing the frame into several slices, inter-connecting the subsystems through the satellite side-panels with spring-loaded contacts, etc. The second objective of the study was to figure out how developers can spend more time focusing on the development of their subsystems instead of trying to solve the recurring problems of subsystems integration. The answer was found through a smart standardization that provides a high potential for customization, where it is really needed. The concept can be applied to any CubeSat sizes, up to 12U. The project’s final objective was to build a website, allowing developers to define their CubeSat online, to obtain CAD files, mechanical parts, as well as electrical components (connectors, kill-switches and complete CubeSats subsystems). 108 Development of a sweeping Langmuir probe instrument for monitoring the upper ionosphere on board a triple CubeSat S. Ranvier, P. Cardoen, J. De Keyser, D. Pieroux, D. Fussen 1 Belgian Institute for Space Aeronomy, Belgium A novel Langmuir probe instrument, which will fly on board the Pico-Satellite for Atmospheric and Space Science Observations (PICASSO), is under development at the Belgian Institute for Space Aeronomy. PICASSO was initiated to join the QB50 project as scientific in-orbit demonstrator. The sweeping Langmuir probe (SLP) instrument is designed to measure both plasma density and electron temperature at an altitude varying from about 400 km up to 700 km from a high inclination orbit. Therefore, the plasma density is expected to fluctuate over a wide range, from about 1e6/m³ at high latitude and high altitude up to 1e12/m³ at low/mid latitude and low altitude. The electron temperature is expected to lie between approximately 1000 K and 3000 K. Given the high inclination of the orbit, the SLP instrument will allow a global monitoring of the ionosphere with a maximum spatial resolution of the order of 150 m. The main goals are to study 1) the ionosphere-plasmasphere coupling, 2) the subauroral ionosphere and corresponding magnetospheric features, 3) auroral structures, 4) polar caps, and 5) ionospheric dynamics via coordinated observations with EISCAT’s heating radar. To achieve the scientific objectives described above, the instrument includes four thin cylindrical probes whose electrical potential is swept in such a way that both plasma density and electron temperature can be derived. Along the orbit, the Debye length is expected to vary from a few millimetres up to a few meters. Due to the tight constraints in terms of mass and volume inherent to pico-satellites, the use of long booms, which would guarantee that the probes are outside the sheath of the spacecraft (several Debye lengths away), is not possible. Consequently, the probes might be in the sheath of the spacecraft in Polar Regions. Extensive modelling and simulations of the sheath effects on the measured current/voltage characteristics will be performed to ensure an accurate parameter extraction from the measured data. Another issue implied by the use of a pico-satellite platform for a Langmuir probe instrument is the limited conducting area of the spacecraft which can lead to spacecraft charging. In order to avoid this problem, the spacecraft potential is monitored and the probes are swept in a particular way with limited duty cycle. The resulting measurement data rate is compatible with the limited telemetry bandwidth available on PICASSO, which will have an S-band downlink session when it passes over the ground station every few orbits. 109 CubeSat Constellation Design for Zonal Mutual Coverage: Comparison between Rider Analytical Design and Genetic Algorithm Optimization I. Meziane-Tani1,2 1 Laboratoire de Télécommunications de Tlemcen, University of Tlemcen, Algeria Géoazur, Nice Sophia-Antipolis University, CNRS (UMR 7329), Observatoire de la Côte d’Azur, 250 rue Albert Einstein, Sophia Antipolis 06560 Valbonne, France 2 Satellite constellations offer a better spatial diversity and are sometimes the only solution to some mission requirements. In global coverage case, the design is relatively simple and some models already exist (Walker and Ballard constellations). However when the coverage becomes more complicated (regional, zonal), the design is no longer deterministic and several analytical, semianalytical and numerical approaches are proposed in the literature. On the other hand, using CubeSats instead of convectional large satellites minimizes the development and launch costs in order to match with regional mission budget. In this paper, we consider the simple case of a data collection mission where the transmitting station and the receiving station are both within the same geographical zone. The CubeSats relaying data are considered without any intersatellite links. First, the Rider analytical model used to find an approximate constellation to the problem of zonal coverage is evaluated in the case of mutual coverage. Then, these results are numerically optimised using a genetic algorithm that we implemented. Finally, through some examples we show that the number of satellites has been significantly reduced.
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