71 st International Astronautical Congress (IAC) – The CyberSpace Edition, 12-14 October 2020. Copyright ©2020 by the authors. Published by the IAF, with permission and released to the IAF to publish in all forms. IAC-20,C3,4,2,x59999 Page 1 of 18 IAC-20,C3,4,2,x59999 COMPARATIVE ANALYSIS OF SOLAR POWER SATELLITE SYSTEMS TO SUPPORT A MOON BASE Drew Gillespie a , Andrew Ross Wilson a *, Donald Martin a , Gareth Mitchell a , Gianluca Filippi a , Massimiliano Vasile a a Department of Mechanical and Aerospace Engineering, University of Strathclyde, James Weir Building, 75 Montrose Street, Glasgow, G1 1XJ, United Kingdom * Corresponding Author: andrew.r.wilson@strath.ac.uk Abstract This paper compares different concepts for a space-based power system to support a lunar base: a solar power satellite (SPS) with a microwave wireless power transmission system (WPT), a hybrid configuration where two solar reflector satellites (SRS) fly in formation with the SPS and concentrate sunlight onto the SPS, and the CASSIOPeiA SPS system. Sizing of the transmitting and receiving antennae is conducted for a WPT concept utilising high frequency microwaves. Design of the microwave generator is based on gyrotron technology, with parabolic reflectors, and an array of rectifying patch antennae. The WPT solution consists of a number of satellites with solar arrays and transmission capabilities to provide continuous power to the receiving array. Solar reflectors alleviate the issue of day-night cycles, for ground-based solar arrays, by providing constant sunlight. This concept could be extended by increasing the irradiance provided by the reflecting satellite, thus decreasing the size of the ground solar array required. However, reflective satellites struggle with efficiency stemming from the size of the footprint they create, which is dependent on the angular subtense of the Sun. This paper demonstrates that a hybrid design, utilizing both the reflector satellites and the WPT, would provide the greatest power to weight ratio - decreasing the size of the solar array required. An important aspect in the effectiveness of solar powered satellites are their distance from the ground receiver, determined directly by their orbit. Smaller orbits allow for reduced distances between the satellite and ground; reducing receiver sizes. However, larger orbits increase transmission windows, reducing the required energy transfer rate. Another important consideration is the stability of the orbit. Stability is affected by the Solar Radiation Pressure, the gravitational pull of the Earth, and the effects of the non-spherical gravity field of the Moon. Thus, when designing the orbit, these effects have been considered alongside the trade-off between larger and smaller orbits. The solutions have been scaled and compared to the CASSIOPeiA concept architecture of a similar nature which has been investigated to demonstrate the effectiveness of the concept provided. Keywords: Solar Power Satellite, CASSIOPeiA, Solar Mirrors, Space Power, Wireless Power Transmission Acronyms AU Astronomical Unit CFRP Carbon Fibre Reinforced Polymer DC Direct Current GEO Geostationary Earth Orbit ISS International Space Station LEO Low Earth Orbit PV Photovoltaic RCS Reaction Control System RF Radio Frequency SBSP Space-Based Solar Power SPS Solar Power Satellite SRS Solar Reflector Satellite TRL Technology Readiness Level UV Ultraviolet WPT Wireless Power Transmission 1. Introduction The demand for electrical power is a critical consideration in the design of all space systems. Even more so for crewed missions, the provision of power for habitat and outpost infrastructure such as life support, navigation and communications, as well as supporting scientific research and exploration, is an essential system component and determinant of mission success [1]. These considerations are of great importance for the upcoming Artemis missions - humanity’s return to the Moon. Additionally, with plans for longer-term, more sustainable, habitation on the lunar surface, astronauts will require greater magnitudes of power than any space system ever previously deployed [2]. Whilst various technologies have been used to support human space exploration, the most common power systems utilise solar photovoltaic arrays. In space these systems can provide near continuous power