Print Email Facebook Twitter Cost Effective Attitude Control Validation Test Methods for CubeSats Applied to PolarCube Title Cost Effective Attitude Control Validation Test Methods for CubeSats Applied to PolarCube Author Clarke, M.A.H. Contributor Guo, J. (mentor) Faculty Aerospace Engineering Department Spaceflight Programme Space Engineering Date 2016-03-31 Abstract The problem of testing the performance of an attitude control system presents new challenges and opportunities when conducted on a CubeSat scale. This is the result of drastic reduction in physical properties (size, mass, torques) as well as project resources (funds, manpower, time) when compared to traditional satellite programs. This thesis presents an analysis of the problem of validating active attitude control of a CubeSat before launch and a proposed methodology that is demonstrated on the Colorado Space Grant Consortium’s PolarCube satellite. In order for an attitude control system’s performance to be measured, it must be provided with a physical environment that allows the system to act similarly to how it would in orbit and its behavior must be recorded in such a way that metrics of performance can be derived. To date, published tests of this nature on CubeSats have been limited in their precision due to uncertainty in external torques on the attitude control system and have mostly been conducted on commercially available attitude control system modules. A string suspension testbed was chosen to provide a simulation of microgravity that allows the system to rotate free of friction. This thesis builds on the practices for string suspension testing developed for the MicroMAS CubeSat mission in which a "fit-predict-fit" method of producing metrics of attitude control system performance was first implemented for CubeSats. The project set out to identify and solve points of failure that were limiting measurement performance of the tests conducted on the MicroMAS system and ultimately produce more accurate measurements and predictions of testbed and attitude control system dynamic response. An engineering model of the satellite bus was designed and built to provide independent power, wireless communication and data handling to the attitude determination and control subsystem. An attitude determination method was developed using MEMS magnetometers, accelerometers and rate gyroscopes to operate within a laboratory environment. A model of the dynamics of the test model’s behavior in the testbed was created to generate predictions of the test model’s response to test conditions, act as a platform to compare measured and expected test results, and verify the attitude determination method. Attitude determination performance was determined through a combination of direct testing and dynamics modeling in software. The methods found a maximum (worst case scenario) heading determination error of 4.6 ? after feed-forward correction based on characterization tests. Oscillation tests were used to determine the external torque properties of the string suspension testbed to within two significant figures, a drastic improvement in performance compared to the MicroMAS test results. Less than $300 were spent on hardware dedicated to testing. The overall system is marked by its simplicity and cost-effectiveness. The results will render attitude control validation testing and consequently the use of active attitude control more accessible to future CubeSat missions. Improvements in performance when compared to the MicroMAS test results were identified as the result of more robust and flexible software modelling of string suspension testbed dynamics, improved methods of characterizing testbed external torque properties as well as improved attitude determination performance. Subject attitudecontrolCubeSatstringtesthardware in the loopdeterminationtestbedmethodmicrogravitysimulationvalidationXBeeArduinoPolarCubeSpace GrantTUDelftBoulderpointingmagnetometerimusystemALL-STARCOSGCnanosatellitesatellitereaction wheel To reference this document use: http://resolver.tudelft.nl/uuid:f2fcf3f0-dfc5-4a75-aab3-cffc2e1ad348 Part of collection Student theses Document type master thesis Rights (c) 2016 Clarke, M.A.H. Files PDF Maxim_Clarke_Thesis_Submission.pdf 7.07 MB Close viewer /islandora/object/uuid:f2fcf3f0-dfc5-4a75-aab3-cffc2e1ad348/datastream/OBJ/view