Session
Pre-Conference Poster Session II
Location
Utah State University, Logan, UT
Abstract
In the last 10-20 years, the simplified structure and low-costattributes of CubeSats have given universities and other student groups the opportunity to build and launch their own small satellites. This was the case with the University of Southern California’s 4th CubeSat, Magneto. Magneto’s mission objective is to validate two magnetometers, provided in partnership by Omega Engineering, by attempting to map the Earth’s magnetic field in a low Earth orbit (LEO).
This goal presented a multifaceted problem, characterized by the design challenges associated with building a low-cost CubeSat that can collect and downlink data from all over the globe. A balance had to be maintained, operating within onboard storage limitations and keeping power demands low, while still downlinking enough widespread data to make the mission meaningful. Amateur radio operators around the world were proposed to act as the CubeSat’s distributed global ground station network, providing a means by which to receive downlinked data in locations out of range of Southern California. Additionally, a rotating onboard beacon scheme with stored data points further preserved magnetosphere measurements taken out of range of a ground station. Employing these resources and techniques, the Magneto team hopes to produce a map of the magnetosphere comparable to one produced by European Space Agency (ESA) satellites.
Paper for Low Cost Magnetosphere Measurement
Low Cost Magnetosphere Measurement: Leveraging Fusion of Low Data Rate Downlink with Amateur Radio Community
Utah State University, Logan, UT
In the last 10-20 years, the simplified structure and low-costattributes of CubeSats have given universities and other student groups the opportunity to build and launch their own small satellites. This was the case with the University of Southern California’s 4th CubeSat, Magneto. Magneto’s mission objective is to validate two magnetometers, provided in partnership by Omega Engineering, by attempting to map the Earth’s magnetic field in a low Earth orbit (LEO).
This goal presented a multifaceted problem, characterized by the design challenges associated with building a low-cost CubeSat that can collect and downlink data from all over the globe. A balance had to be maintained, operating within onboard storage limitations and keeping power demands low, while still downlinking enough widespread data to make the mission meaningful. Amateur radio operators around the world were proposed to act as the CubeSat’s distributed global ground station network, providing a means by which to receive downlinked data in locations out of range of Southern California. Additionally, a rotating onboard beacon scheme with stored data points further preserved magnetosphere measurements taken out of range of a ground station. Employing these resources and techniques, the Magneto team hopes to produce a map of the magnetosphere comparable to one produced by European Space Agency (ESA) satellites.
