In this paper the natural dynamics of a rigid body are exploited to plan attitude manoeuvres for a small spacecraft. By utilising the analytical solutions of the angular velocities and making use of Lax pair integration, the time evolution of the attitude of the spacecraft in a convenient quaternion form is derived. This enables repointing manoeuvres to be generated by optimising the free parameters of the analytical expressions, the initial angular velocities of the spacecraft, to match prescribed boundary conditions on the final attitude of the spacecraft. This produces reference motions which can be tracked using a simple proportional-derivative controller. The natural motions are compared in simulation to a conventional quaternion feedback controller and found to require lower accumulated torque. A simple obstacle avoidance algorithm, exploiting the analytic form of natural motions, is also described and implemented in simulation. The computational efficiency of the motion planning method is discussed

Biggs, James

Maclean, Craig David

Pagnozzi, Daniele

English

Shaveen Singh

Sunil Pranit Lal

Crossref

Educational courseware evaluation using Machine Learning techniques

With the introduction of massive open online courses (MOOCs) and other web-based learning management systems (LMS), there is a greater need to develop methods for exploring the unique types of data that come from the educational context. This paper highlights the advantage of using Machine Learning (ML) as an e-planning tool to enhance learning and improve courseware development. Researchers generally consider student evaluation survey on courses to be highly reliable and at least moderately valid on courseware evaluation. However, low response rate, retaliation, grades and comparison with past instructors sometimes affects the reliability of the result. ML algorithms has been deployed in this paper to intelligently examine the interaction log data from the LMS to obtain a predictive map that permits mapping the online interaction behaviour of students with their course outcome. These predictive relationships are then investigated and ranked using various ML algorithms to evaluate and validate the various learning tools and activities, and their effectiveness within the course

Singh, Shaveen

Lal, Sunil P.

University of the South Pacific Electronic Research Repository

Educational courseware evaluation using machine learning techniques

University of Strathclyde Institutional Repository

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