Sun sensor calibration algorithms: A systematic mapping and survey

TL;DR

This paper systematically reviews and maps existing sun sensor calibration algorithms, highlighting research gaps and suggesting future directions to enhance spacecraft attitude accuracy.

Contribution

It provides the first comprehensive survey and systematic mapping of sun sensor calibration methods, consolidating two decades of research.

Findings

Identifies key calibration techniques and their effectiveness.

Highlights gaps in current methodologies and areas for improvement.

Recommends future research directions for enhanced calibration accuracy.

Abstract

Attitude sensors determine the spacecraft attitude through the sensing of an astronomical object, field or other phenomena. The Sun and fixed stars are the two primary astronomical sensing objects. Attitude sensors are critical components for the survival and knowledge improvement of spacecraft. Of these, sun sensors are the most common and important sensor for spacecraft attitude determination. The sun sensor measures the Sun vector in spacecraft coordinates. The sun sensor calibration process is particularly difficult due to the complex nature of the uncertainties involved. The uncertainties are small, difficult to observe, and vary spatio-temporally over the lifecycle of the sensor. In addition, the sensors are affected by numerous sources of uncertainties, including manufacturing, electrical, environmental, and interference sources. This motivates the development of advanced calibration algorithms to minimize uncertainty over the sensor lifecycle and improve accuracy. Although modeling and calibration techniques for sun sensors have been explored extensively in the literature over the past two decades, there is currently no resource that consolidates and systematically reviews this body of work. The present review proposes a systematic mapping of sun sensor modeling and calibration algorithms across a breadth of sensor configurations. It specifically provides a comprehensive survey of each methodology, along with an analysis of research gaps and recommendations for future directions in sun sensor modeling and calibration techniques.