23 results on '"Enderle, Werner"'
Search Results
2. GENESIS: co-location of geodetic techniques in space
- Author
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Delva, Pacôme, Altamimi, Zuheir, Blazquez, Alejandro, Blossfeld, Mathis, Böhm, Johannes, Bonnefond, Pascal, Boy, Jean-Paul, Bruinsma, Sean, Bury, Grzegorz, Chatzinikos, Miltiadis, Couhert, Alexandre, Courde, Clément, Dach, Rolf, Dehant, Véronique, Dell’Agnello, Simone, Elgered, Gunnar, Enderle, Werner, Exertier, Pierre, Glaser, Susanne, Haas, Rüdiger, Huang, Wen, Hugentobler, Urs, Jäggi, Adrian, Karatekin, Ozgur, Lemoine, Frank G., Le Poncin-Lafitte, Christophe, Lunz, Susanne, Männel, Benjamin, Mercier, Flavien, Métivier, Laurent, Meyssignac, Benoît, Müller, Jürgen, Nothnagel, Axel, Perosanz, Felix, Rietbroek, Roelof, Rothacher, Markus, Schuh, Harald, Sert, Hakan, Sosnica, Krzysztof, Testani, Paride, Ventura-Traveset, Javier, Wautelet, Gilles, and Zajdel, Radoslaw
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- 2023
- Full Text
- View/download PDF
3. NEW TYPE ON THE BLOCK: Generating High-Precision Orbits for GPS III Satellites
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Dilssner, Florian, Springer, Tim, Schonemann, Erik, Gini, Francesco, and Enderle, Werner
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Lockheed Martin Corp. ,Aerospace industry ,Artificial satellites ,Business ,Telecommunications industry ,European Space Agency ,European Space Agency. European Space Operations Centre - Abstract
To produce GNSS satellite orbit ephemerides and clock data with high precision and for all constellations, the Navigation Support Office of the European Space Agency's European Space Operations Centre (ESA/ESOC) [...]
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- 2023
4. Combination strategy for consistent final, rapid and predicted Earth rotation parameters
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Kehm, Alexander, Hellmers, Hendrik, Bloßfeld, Mathis, Dill, Robert, Angermann, Detlef, Seitz, Florian, Hugentobler, Urs, Dobslaw, Henryk, Thomas, Maik, Thaller, Daniela, Böhm, Johannes, Schönemann, Erik, Mayer, Volker, Springer, Tim, Otten, Michiel, Bruni, Sara, and Enderle, Werner
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- 2023
- Full Text
- View/download PDF
5. GENESIS GENESIS ESA’s Multi-Modal Space Mission to Improve Geodetic Applications.
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Enderle, Werner, Schönemann, Eric, Gini, Francesco, Gidlund, Sara, Fusco, Gaia, Waller, Pierre, Honoré-Livermore, Evelyn, Sakalauskaite, Evelina, and Navarro, Vicente
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VERY long baseline interferometry - Abstract
The article discusses the Genesis multi-modal space mission established by the European Space Agency (ESA). Topics explored include its use of a combination of space-based geodetic techniques such as global navigation satellite system (GNSS) and satellite laser ranging (SLR), the way this mission may help improve the International Terrestrial Reference Frame (ITRF), and the execution of the mission under the ESA Navigation Directorate and Operations Directorate.
- Published
- 2024
6. The Joint ESA/NASA Galileo/GPS Receiver Onboard the ISS – the GARISS Project
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Enderle, Werner, Schönemann, Erik, Gini, Francesco, Otten, Michiel, Giordano, Pietro, Miller, James J, Sands, O. Scott, Chelmins, David, and Pozzobon, Oscar
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Space Communications, Spacecraft Communications, Command And Tracking - Abstract
ESA and NASA conducted a joint Galileo/GPS space receiver experiment on-board the International Space Station (ISS). The objectives (Enderle 2017) of the joint project were to demonstrate the robustness of a combined Galileo/GPS waveform uploaded to NASA hardware already operating in the challenging space environment - the SCaN (Space Communications and Navigation) software defined radio (SDR) testbed (FPGA) - on-board the ISS. These activities data included the analysis of the Galileo/GPS signal and on-board Position/Velocity/Time (PVT) performance, processing of the Galileo/GPS raw data (code- and carrier phase) for Precise Orbit Determination (POD), and validate the added value of a space-borne dual GNSS receiver compared to a single-system GNSS receiver operating under the same conditions. This paper will provide a general overview of the Galileo/GPS experiment – called GARISS - on-board the ISS, describe design, test and validation and also the operations of the experiment. Further, the various analysis conducted in the con is joint project and also the results obtained will be presented with a focus on the (Precise) Orbit Determination results.
- Published
- 2019
7. The Multi-GNSS Space Service Volume
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Parker, Joel J, Bauer, Frank H, Ashman, Benjamin W, Miller, James J, Enderle, Werner, and Blonski, Daniel
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Space Communications, Spacecraft Communications, Command And Tracking - Abstract
Global Navigation Satellite Systems (GNSS), now routinely used for navigation by spacecraft in low Earth orbit, are being used increasingly by high-altitude users in geostationary orbit and high eccentric orbits as well, near to and above the GNSS constellations themselves. Available signals in these regimes are very limited for any single GNSS constellation due to the weak signal strength, the blockage of signals by the Earth, and the limited number of satellites. But with the recent development of multiple GNSS constellations and ongoing upgrades to existing constellations, multi-GNSS signal availability is set to improve significantly. This will only be achieved if these signals are designed to be interoperable and are clearly documented and supported.All satellite navigation constellation providers are working together through the United Nations International Committee on GNSS (ICG) to establish an interoperable multi-GNSS Space Service Volume (SSV) for the benefit of all GNSS space users. The multi-GNSS SSV represents a common set of baseline definitions and assumptions for high-altitude service in space, documents the service provided by each constellation, and provides a framework for continued support for space users. This paper provides an overview of the GNSS SSV concept, development, status, and achievements within the ICG. It describes the final adopted definition and performance characteristics of the GNSS SSV, as well as the numerous benefits and use cases enabled by this development, and summarizes extensive technical analysis that was performed to illustrate these benefits in terms of signal availability, both on a global scale, and for multiple distinct mission types.
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- 2018
8. Space User Visibility Benefits of the Multi-GNSS Space Service Volume: An Internationally-Coordinated, Global and Mission-Specific Analysis
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Enderle, Werner, Gini, Francesco, Boomkamp, Henno, Parker, Joel J, Ashman, Benjamin W, Welch, Bryan W, Koch, Mick V, and Sands, Obed S
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Space Communications, Spacecraft Communications, Command And Tracking - Abstract
The number and scope of Global Navigation Satellite System (GNSS)-based space applications has grown significantly since the first GNSS space receiver was flown in the early 1980's. The vast majority of GNSS space users operate in Low-Earth Orbit (LEO), where the use of GNSS receivers has become routine. However, the use of GNSS has expanded to other orbit regimes like Geostationary Orbits (GEO) and High Eccentric Orbits (HEO) but has been very limited due to the challenges involved. The major challenges for such types of orbits including much weaker signals, reduced geometric diversity, and limited signal availability. In any case, considering the recent development of multiple GNSS constellations and ongoing upgrades to existing constellations, GNSS signal availability will improve significantly. As a result, this expanded multi-GNSS signal capability will enable improved on-orbit navigation performance and will also allow the development of new mission concepts. High altitude space users will especially benefit from this evolution, which will provide GNSS signals to challenging regimes well beyond Low Earth Orbit. These benefits will only be realised, however, if additional signals are designed to be interoperable, are clearly documented and supported. In order to enhance the overall GNSS performance for spacecraft's in regimes from LEO, GEO to HEO and beyond, all Satellite Navigation constellation providers and regional augmentation system providers are working together through the United Nations International Committee on GNSS (ICG) forum to establish an interoperable GNSS Space Service Volume (SSV) for the benefit of all GNSS space users. This paper provides an overview of the technical work and in particular the simulations, performance analysis and discussions of the outcomes and results obtained by the UN ICG Working Group-B in the context of the GNSS Space Service Volume activities, which were supported by all GNSS service providers.
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- 2018
9. Development of an Interoperable GNSS Space Service Volume
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Parker, Joel J, Bauer, Frank H, Ashman, Benjamin W, Miller, James J, Enderle, Werner, and Blonski, Daniel
- Subjects
Space Communications, Spacecraft Communications, Command And Tracking ,Astronautics (General) - Abstract
Global Navigation Satellite Systems (GNSS), now routinely used for navigation by spacecraft in low Earth orbit, are being used increasingly by high-altitude users in geostationary orbit and high eccentric orbits as well, near to and above the GNSS constellations themselves. Available signals in these regimes are very limited for any single GNSS constellation due to the weak signal strength, the blockage of signals by the Earth, and the limited number of satellites. But with the recent development of multiple GNSS constellations and ongoing upgrades to existing constellations, multi-GNSS signal availability is set to improve significantly. This will only be achieved if these signals are designed to be interoperable and are clearly documented and supported.All satellite navigation constellation providers are working together through the United Nations International Committee on GNSS (ICG) to establish an interoperable multi-GNSS Space Service Volume (SSV) for the benefit of all GNSS space users. The multi-GNSS SSV represents a common set of baseline definitions and assumptions for high-altitude service in space, documents the service provided by each constellation, and provides a framework for continued support for space users. This paper provides an overview of the GNSS SSV concept, development, status, and achievements within the ICG. It describes the final adopted definition and performance characteristics of the GNSS SSV, as well as the numerous benefits and use cases enabled by this development. Extensive technical analysis was also performed to illustrate these benefits in terms of signal availability, both on a global scale, and for multiple distinct mission types. This analysis is summarized here and presented in detail in a companion paper by Enderle, et al.
- Published
- 2018
10. Development of an Interoperable GNSS Space Service Volume
- Author
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Parker, Joel J. K, Bauer, Frank H, Ashman, Benjamin W, Miller, James J, Enderle, Werner, and Blonski, Daniel
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Astronautics (General) - Abstract
Global Navigation Satellite Systems (GNSS), now routinely used for navigation by spacecraft in low Earth orbit, are being used increasingly by high-altitude users in geostationary orbit and high eccentric orbits as well, near to and above the GNSS constellations themselves. Available signals in these regimes are very limited for any single GNSS constellation due to the weak signal strength, the blockage of signals by the Earth, and the limited number of satellites. But with the recent development of multiple GNSS constellations and ongoing upgrades to existing constellations, multi-GNSS signal availability is set to improve significantly. This will only be achieved if these signals are designed to be interoperable and are clearly documented and supported. All satellite navigation constellation providers are working together through the United Nations International Committee on GNSS (ICG) to establish an interoperable multi-GNSS Space Service Volume (SSV) for the benefit of all GNSS space users. The multi-GNSS SSV represents a common set of baseline definitions and assumptions for high-altitude service in space, documents the service provided by each constellation, and provides a framework for continued support for space users. This paper provides an overview of the GNSS SSV concept, development, status, and achievements within the ICG. It describes the final adopted definition and performance characteristics of the GNSS SSV, as well as the numerous benefits and use cases enabled by this development. Extensive technical analysis was also performed to illustrate these benefits in terms of signal availability, both on a global scale, and for multiple distinct mission types. This analysis is summarized here and presented in detail in a companion paper by Enderle, et al.
- Published
- 2018
11. Developing a Robust, Interoperable GNSS Space Service Volume (SSV) for the Global Space User Community
- Author
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Bauer, Frank H, Parker, Joel J. K, Welch, Bryan, and Enderle, Werner
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Communications And Radar ,Earth Resources And Remote Sensing ,Space Communications, Spacecraft Communications, Command And Tracking - Abstract
For over two decades, researchers, space users, Global Navigation Satellite System (GNSS) service providers, and international policy makers have been working diligently to expand the space-borne use of the Global Positioning System (GPS) and, most recently, to employ the full complement of GNSS constellations to increase spacecraft navigation performance. Space-borne Positioning, Navigation, and Timing (PNT) applications employing GNSS are now ubiquitous in Low Earth Orbit (LEO). GNSS use in space is quickly expanding into the Space Service Volume (SSV), the signal environment in the volume surrounding the Earth that enables real-time PNT measurements from GNSS systems at altitudes of 3000 km and above. To support the current missions and planned future missions within the SSV, initiatives are being conducted in the United States and internationally to ensure that GNSS signals are available, robust, and yield precise navigation performance. These initiatives include the Interagency Forum for Operational Requirements (IFOR) effort in the United States, to support GPS SSV signal robustness through future design changes, and the United Nations-sponsored International Committee on GNSS (ICG), to coordinate SSV development across all international GNSS constellations and regional augmentations. The results of these efforts have already proven fruitful, enabling new missions through radically improved navigation and timing performance, ensuring quick recovery from trajectory maneuvers, improving space vehicle autonomy and making GNSS signals more resilient from potential disruptions. Missions in the SSV are operational now and have demonstrated outstanding PNT performance characteristics; much better than what was envisioned less than a decade ago. The recent launch of the first in a series of US weather satellites will employ the use of GNSS in the SSV to substantially improve weather prediction and public-safety situational awareness of fast moving events, including hurricanes, flash floods, severe storms, tornados and wildfires. Thus, the benefits of the GNSS expansion and use into the SSV are tremendous, resulting in orders of magnitude return in investment to national governments and extraordinary societal benefits, including lives saved and critical infrastructure and property protected. However, this outstanding success is tempered by dual challenges: that for GPS, the current SSV specifications do not adequately protect SSV future use; and that for GNSS, the capabilities that are currently available are not protected in the future by specifications.
- Published
- 2017
12. Experimenting Galileo on Board the International Space Station
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Fantinato, Samuele, Pozzobon, Oscar, Sands, Obed S, Welch, Bryan W, Clapper, Carolyn J, Miller, James J, Gamba, Giovanni, Chiara, Andrea, Montagner, Stefano, Giordano, Pietro, Crisci, Massimo, Chelmins, David T, and Enderle, Werner
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Space Communications, Spacecraft Communications, Command And Tracking ,Electronics And Electrical Engineering - Abstract
The SCaN Testbed is an advanced integrated communications system and laboratory facility installed on the International Space Station (ISS) in 2012. The testbed incorporates a set of new generation of Software Defined Radio (SDR) technologies intended to allow researchers to develop, test, and demonstrate new communications, networking, and navigation capabilities in the actual environment of space. Qascom, in cooperation with ESA and NASA, is designing a Software Defined Radio GalileoGPS Receiver capable to provide accurate positioning and timing to be installed on the ISS SCaN Testbed. The GalileoGPS waveform will be operated in the JPL SDR that is constituted by several hardware components that can be used for experimentations in L-Band and S-Band. The JPL SDR includes an L-Band Dorne Margolin antenna mounted onto a choke ring. The antenna is connected to a radio front end capable to provide one bit samples for the three GNSS frequencies (L1, L2 and L5) at 38 MHz, exploiting the subharmonic sampling. The baseband processing is then performed by an ATMEL AT697 processor (100 MIPS) and two Virtex 2 FPGAs. The JPL SDR supports the STRS (Space Telecommunications Radio System) that provides common waveform software interfaces, methods of instantiation, operation, and testing among different compliant hardware and software products. The standard foresees the development of applications that are modular, portable, reconfigurable, and reusable. The developed waveform uses the STRS infrastructure-provided application program interfaces (APIs) and services to load, verify, execute, change parameters, terminate, or unload an application. The project is divided in three main phases. 1)Design and Development of the GalileoGPS waveform for the SCaN Testbed starting from Qascom existing GNSS SDR receiver. The baseline design is limited to the implementation of the single frequency Galileo and GPS L1E1 receiver even if as part of the activity it will be to assess the feasibility of a dual frequency implementation (L1E1+L5E5a) in the same SDR platform.2)Qualification and test the GalileoGPS waveform using ground systems available at the NASA Glenn Research Center. Experimenters can have access to two SCaN Testbed ground based systems for development and verification: the Experimenter Development System (EDS) that is intended to provide initial opportunity for software testing and basic functional validation and the Ground Integration Unit (GIU) that is a high fidelity version of the SCaN Testbed flight system and is therefore used for more controlled final development testing and verification testing.3)Perform in-orbit validation and experimentation: The experimentation phase will consists on the collection of raw measurements (pseudorange, Carrier phase, CN0) in space, assessment on the quality of the measurements and the receiver performances in terms of signal acquisition, tracking, etc. Finally computation of positioning in space (Position, Velocity and time) and assessment of its performance.(Complete abstract in attached document).
- Published
- 2016
13. GPS and Galileo Developments on Board the International Space Station With the Space Communications and Navigation (SCaN) Testbed
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Pozzobon, Oscar, Fantinato, Samuele, Dalla Chiara, Andrea, Gamba, Giovanni, Crisci, Massimo, Giordana, Pietro, Enderle, Werner, Chelmins, David, Sands, Obed S, Clapper, Carolyn J, and Miller, James J
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Aircraft Communications And Navigation - Abstract
The Space Communications and Navigation (SCaN) is a facility developed by NASA and hosted on board the International Space Station (ISS) on an external truss since 2013.It has the objective of testing navigation and communication experimentations with a Software Defined Radio (SDR) approach, which permits software updates for testing new experimentations.NASA has developed the Space Telecommunications Radio System (STRS) architecture standard for SDRs used in space and ground-based platforms to provide commonality among radio developments to provide enhanced capability. The hardware is equipped with both L band front-end radios and the NASA space network communicates with it using S-band, Ku-band and Ka-band links.In May 2016 Qascom started GARISS (GPS and Galileo Receiver for the ISS), an activity of experimentation in collaboration with ESA and NASA that has the objective to develop and validate the acquisition and processing of combined GPS and Galileo signals on board the ISS SCaN testbed. This paper has the objective to present the mission, and provide preliminary details about the challenges in the design, development and verification of the waveform that will be installed on equipment with limited resources. GARISS is also the first attempt to develop a waveform for the ISS as part of an international collaboration between US and Europe. Although the final mission objective is to target dual frequency processing, initial operations will foresee a single frequency processing. Initial results and trade-off between the two options, as well as the final decision will be presented and discussed. The limited resources on board the SCaN with respect to the challenging requirements to acquire and track contemporaneously two satellite navigation systems, with different modulations and data structure, led to the need to assess the possibility of aiding from ground through the S-band. This option would allow assistance to the space receiver in order to provide knowledge of GNSS orbits and reduce the processing on board. Trade off and various options for telemetry and uplink data are presented and discussed. Finally, integration and validation of the waveform are one of the major challenges of GARISS: The Experiment Development System (EDS) and the the Ground Integration Unit (GIU) for VV will be used prior to conducting the experiment on the ISS. The EDS can be used in lab environment and allows prototyping and verification activities with the simulator, but does not include all hardware components. The GIU on the other side is the flight model which replicates the flying equipment, but has limited flexibility for testing.As conclusion, the project is now approaching the Preliminary Design Review (PDR) and indeed only preliminary results are available. This paper is an opportunity to present the GARISS mission as part of an International cooperation between ESA, NASA and Qascom. The preliminary results include GPS and Galileo processing from space signals, the challenges and trade off decisions, the high level STRS architecture and foreseen experimentation campaign. Detailed results from the test campaigns are expected in 2017.
- Published
- 2016
14. Real-Time GNSS activities at ESA: navigation Support Office provides services for IGS and users
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Enderle, Werner, Agrotis, Loukis, Zandbergen, Rene, Kints, Mark van, and Martin, Jens
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Artificial satellites in navigation -- Standards -- Technology application ,Technology application ,Business ,Telecommunications industry ,European Space Agency -- Services - Abstract
The European Space Operations Centre has taken on the roles of real-time analysis center, data provider, and analysis-center coordinator for the International GNSS Service's Real-Time Service, providing a number of [...]
- Published
- 2013
15. Galileo and GNSS to the fore: activities of the European Navigation Support Office
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Enderle, Werner, Zandbergen, Rene, Springer, Tim, and Agrotis, Loukis
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Artificial satellites ,Business ,Telecommunications industry ,European Space Agency ,Glonass (Artificial satellite) - Abstract
The European Space Operations Centre (ESOC) in Darmstadt, Germany operates spacecraft on behalf of the European Space Agency (ESA) and maintains the ground facilities and expertise for ESA and other [...]
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- 2012
16. NEW TYPE ON THE BLOCK.
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DILLSNNER, FLORIAN, PRINGER, TIM, SCHONEMANN, ERIK, GINI, FRANCESCO, and ENDERLE, WERNER
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ORBIT determination ,GLOBAL Positioning System ,ORBITS (Astronomy) ,TRANSMITTING antennas - Abstract
The article offers information on Navigation Support Office of the European Space Agency's European Space Operations Centre (ESA/ESOC) which has been working to improve the precision of its precise orbit determination (POD) strategies for GNSS satellite orbit ephemerides and clock data. Efforts have been made to enhance the accuracy of the orbit estimates for GPS Block III satellites, including on-ground and in-flight determinations of transmit antenna phase center characteristics.
- Published
- 2023
17. Combination of precise GNSS orbit and clocks in a multi-constellation, multi-frequency environment
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Ortiz Geist, Estefania, Dach, Rolf, Schoenemann, Erik, Enderle, Werner, and Jäggi, Adrian
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520 Astronomy - Published
- 2015
- Full Text
- View/download PDF
18. Satellite Clock Modelling and Multi-GNSS Solutions
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Orliac, Etienne, Dach, Rolf, Wang, Kan, Rothacher, Markus, Hugentobler, Urs, Steigenberger, Peter, and Enderle, Werner
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520 Astronomy - Published
- 2013
19. Integer ambiguity resolved orbits for Sentinel and the benefits of combined Sentinel and GPS processing.
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Gini, Francesco, Otten, Michiel, Flohrer, Claudia, Mayer, Volker, Geist, Estefania Ortiz, and Enderle, Werner
- Published
- 2019
20. ESA Multi-GNSS Products.
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Mayer, Volker, Springer, Tim, Schönemann, Erik, and Enderle, Werner
- Published
- 2019
21. The BeiDou Attitude Model for Continuous Yawing MEO and IGSO Spacecraft.
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Dilssner, Florian, Läufer, Gwendolyn, Springer, Tim, Schönemann, Erik, and Enderle, Werner
- Published
- 2018
22. Satellite clock modeling for kinematic determination of GNSS orbits and satellite attitude.
- Author
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Koch, Donovan, Rothacher, Markus, Prange, Lars, Dach, Rolf, Schoenemann, Erik, and Enderle, Werner
- Published
- 2018
23. First GPS/Galileo Receiver Flown in Space.
- Author
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Enderle, Werner and Miller, James J.
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GALILEO satellite navigation system - Abstract
The article focuses on a joint Galileo space receiver experiment conducted on the International Space Station (ISS) by the European Space Agency (ESA) and the U.S. National Aeronautics and Space Administration (NASA). It mentions involvement of Navigation Support Office (NavSO) and ESTEC Experts for Radio Navigation Systems and Techniques (TEC-ESN) in the project. It also mentions technical support from industry participants such as Qascom for the project.
- Published
- 2017
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