Near real-time telecommand solutions for CubeSats: State of the art and applications to the SkyHopper mission

TL;DR

This paper analyzes the potential of commercial orbital networks for near-real-time telecommands to CubeSats, demonstrating feasibility for rapid communication with applications exemplified by the SkyHopper mission.

Contribution

It introduces an analysis framework for assessing contact likelihood and duration with commercial networks, and compares their effectiveness for CubeSat telecommand applications.

Findings

Near-real-time telecommands achievable within 10 minutes with 62-74% likelihood.

Commercial networks could reach over 98% coverage with 1-second latency in future developments.

SkyHopper mission benefits from improved communication options for rapid-response observations.

Abstract

Cubesats and similarly scaled nano-satellites present significant opportunities for hosting both scientific and commercial payloads for Earth sensing and astronomical observations, in particular in the area of rapid-response observations to external triggers. However, one limiting factor to full exploitation of the CubeSat potential in this area lies in the traditional approach of ground-spacecraft communications, which is based on infrequent contact via a limited network of ground stations. An alternative is to leverage existing commercial machine-to-machine orbital networks to transmit the triggers in near-real-time. Here, we present an analysis framework for calculating the likelihood of a time to first contact and the length of contact under minimum guaranteed conditions for these networks. The analysis is then extended to likely operational conditions in orbit, and the results of a comparative trade study of a number of orbital networks are presented, with an emphasis on the applicability to the SkyHopper Space Telescope CubeSat, a nanosatellite astronomical observatory currently undergoing preliminary design. It was found that near-real- time telecommands could be transmitted to SkyHopper within 10min with a likelihood of 62% using the Globalstar network, or a likelihood of 74% using the Iridium network, under predicted nominal operational conditions in orbit. Future networks currently under development could improve these figures to reach greater than 98% coverage with a one second latency.