Onboard Orbit Determination Using GPS Measurements for Low Earth Orbit Satellites

Zhou, Ning

January 2005

Recent advances in spaceborne GPS technology have shown significant advantages in many aspects over conventional technologies. For instance, spaceborne GPS can realize autonomous orbit determination with significant savings in spacecraft life cycle, in power, and in mass. At present, the onboard orbit determination in real time or near-real time can typically achieve 3D orbital accuracy of metres to tens metres with Kalman filtering process, but 21st century space engineering requires onboard orbit accuracy of better than 5 metres, and even sub-metre for some space applications. The research focuses on the development of GPS-based autonomous orbit determination techniques for spacecraft. Contributions are made to the field of GPS-based orbit determination in the following five areas: Techniques to simplify the orbital dynamical models for onboard processing have been developed in order to reduce the computional burden while retaining full model accuracy. The Earth gravity acceleration approximation method was established to replace the traditional recursive acceleration computations. Results have demonstrated that with the computation burden for a 55× spherical harmonic gravity model, we achieve the accuracy of a 7070× model. Efforts were made for the simplification of solar & lunar ephemerides, atmosphere density model and orbit integration. All these techniques together enable a more accurate orbit integrator to operate onboard. Efficient algorithms for onboard GPS measurement outlier detection and measurement improvement have been developed. In addition, a closed-form single point position method was implemented to provide an initial orbit solution without any a priori information. The third important contribution was made to the development of sliding-window short-arc orbit filtering techniques for onboard processing. With respect to the existing Kalman recursive filtering, the short-arc method is more stable because more measurements are used. On the other hand, the short-arc method requires less accurate orbit dynamical model information compared to the long-arc method, thus it is suitable for onboard processing. Our results have demonstrated that by using the 1 ~ 2 revolutions of LEO code GPS data we can achieve an orbit accuracy of 1 ~ 2 metres. Sliding-window techniques provide sub-metre level orbit determination solutions with 5~20 minutes delay. A software platform for the GPS orbit determination studies has been established. Methods of orbit determination in near-real time have been developed and tested. The software system includes orbit dynamical modelling, GPS data processing, orbit filtering and result analysis modules, providing an effective technical basis for further studies. Furthermore a ground-based near-real time orbit determination system has been established for FedSat, Australia's first satellite in 30 years. The system generates 10-metre level orbit solution with half-day latency on an operational basis. This system has supported the scientific missions of FedSat such as Ka-band tracking and GPS atmosphere studies within the Cooperative Research Centre for Satellite System (CRCSS) community. Though it is different from the onboard orbit determination, it provides important test-bed for the techniques described in previous section. This thesis focuses on the onboard orbit determination techniques that were discussed in Chapter 2 through Chapter 6. The proposed onboard orbit determination algorithms were successfully validated using real onboard GPS data collected from Topex/Poseidon, CHAMP and SAC-C satellites.

GPS measurements

Low Earth Orbit Satellites

GPS technology

onboard orbit determination

orbital dynamical models

onboard processing

Testing for verification and validation of an onboard orbit determination system exploiting GNSS : A nanosatellite application for HERMES-SP / Testning for verifikation och validering av ett ombord banbestämningssystem med GNSS : En applikation av nanosatelliter för HERMES-SP

Nermark, Clara

January 2023

When developing products for space, including nanosatellites, the verification and validation process is a mandatory part of any project conducted within the European space industry. Within such a process, testing is a method for verification and validation. In this degree project, the appropriate tests for verification and validation of a nanosatellite were investigated. The project was conducted at the Royal Institute of Technology and the Polytechnic of Milan, as part of a larger research project under the name HERMES-SP. The research project was, at the time at which the degree project was taking place, in its first phase of the verification process. Therefore, tests for verification and validation of the Orbit Determination System (ODS) had not yet been defined. HERMES-SP is developing a nanosatellite platform with a very precise and reliable ODS, combining both Inertial Navigation System (INS) and Global Navigation Satellite System (GNSS). This degree project was thus conducted with HERMES-SP as an applicative case to investigate tests for a ’nanosatellites onboard ODS focusing on the GNSS. The ODS developed for the nanosatellite platform was studied, along with the underlying theory for ODS and GNSS. The plan for verification defined within HERMES-SP was also examined, and the presented methodology for test development was followed. To fully answer the project’s research question, the appropriate tests had to be identified and defined. This was done by first determining the requirements related to the ODS, and then identifying the tests that were needed to verify the requirements. Lastly, the tests were defined in test specifications and procedures. It was found that the relevant tests in the verification process were a handful of tests on the Equipment Test (ET), Software Test (SWT), and Subsystem Integration Test (SSIT) test levels. The tests were needed for verification of individual components in the system, as well as integrated components and their interfaces. The defined tests were considered appropriate for verification and validation for the first phase of the verification process. The project contributed to the identification and definition of tests for a restricted part of the verification process, related to the specified system of the HERMES-SP nanosatellite. The findings could be used in other nanosatellite projects with similar ODS by following the process and the methodology for test development documented in this report. / Vid utvecklandet av produkter ämnade för rymden, såsom satelliter, är processen för verifiering och validering en obligatorisk del av projekt utförda inom den Europeiska rymdindustrin. Under en sådan process är testning en metod för verfiering och validering. I detta examensarbete undersöktes de lämpliga testerna för verifiering och validering av en nanosatellit. Arbetet utfördes på Kungliga Tekniska Högskolan (KTH) och Politecnico di Milano, som en del av ett större foskningsprojekt under namnet HERMES-SP. När detta examensarbete tog plats var forskningsprojektet i sin första verifieringsfas. Därför hade inte tester för verifiering och validering av systemet för ombord banbestämning ännu definerats. Inom HERMES-SP utvecklas en platform för nanosatelliter med ett precist och tillförlitligt banbestämmnings system. Systemet kombinerar därför både tröghetsnavigeringssystem och satellitnavigering (GNSS). Systemet för ombord banbestäming utvecklat för nanosatelliten studerades, tillsammans med underliggande teori för banbestäming och GNSS. HERMES-SPs plan för verifiering och validering studerades, och den presenterade metodiken för testning adapterades. För att besvara arbetets forskningsfråga behövdes de lämpliga testerna identifieras och sedan defineras. Detta gjorder genom att först bestämma krav på systemet för banbestämning, och därefter identifiera de tester som behövdes för att verifiera kraven. Sist definerades testen i form av test specifikationer och test procedurer. Arbetet resulterade i att en handfull at tester relevanta för verifieringsprocessen identifierades. Dessa tester tillhörde olika nivåer av testing, nämligen testning av komponenter, mjukvara, och integrering av delsystem. Dessa tester var nödvändiga för att utvärdera individuella komponenter i systemet, samt integrerade komponenter och deras gränssnitt. De tester som definerades i arbetet ansågs nödvändiga för verifiering och validering under den första fasen av processen för verifiering. Examensarbetet bidrog till identifiering och definering av tester tillhörande en begränsad fas av verifieringsprocessen, relaterade till det specifiecerade systemet av HERMES-SPs nanosatellit. Upptäckterna skulle kunna användas i andra projekt för nanosatelliter med liknande system för banbestämning, genom att följa metodiken för utveckling av tester dokumenterade i denna rapport.

Onboard orbit determination system

GNSS

nanosatellite

testing

verification and validation

Ombord banbestämning

GNSS

nanosatellit

testning

verifikation och validering

Computer Sciences

Datavetenskap (datalogi)

Computer Engineering

Datorteknik

Elektroteknik och elektronik