Abstract
Although Geostationary-Equatorial-Orbit (GEO) satellites have achieved significant success in conducting space missions, they cannot meet the 5G latency requirements due to the far distance from the earth surface. Therefore, Low-Earth-Orbit (LEO) satellites arise as a potential solution for the latency problem. Nevertheless, integrating the 5G terrestrial networks with LEO satellites puts an increased burden on the satellites’ limited budget, which stems from their miniature sizes, restricted weights, and the small available surface for solar harvesting in the presence of additional required equipment. This paper aims to design the Electrical Power System (EPS) for 5G LEO satellites and investigate altitudes that meet the latency and capacity requirements of 5G applications. In this regard, accurate solar irradiance determination for the nadir-orientation scenario, Multi-Junction (MJ) solar cells modeling, backup batteries type and number, and designing highly-efficient converters are addressed. Accordingly, the power budgeting of the 5G LEO satellite can be achieved based on defining the maximum generated power and determining the satellite’s subsystem power requirements for 5G missions. In the sequel, the measured and simulated values of the electrical V-I characteristics of an MJ solar panel are compared to validate the model by using a Clyde Space solar panel that reaches a maximum power generation of approximately $1~W$ at ( $I_{MPP}=0.426\,\,A$ , $V_{MPP}=2.35\,\,V$ ). Moreover, a synchronous boost converter circuit is designed based on commercial off-the-shelf elements.
Highlights
T HE vicinity to the earth, low-cost, relatively low complexity, and off-the-shelf elements are unique merits for LEO satellites; which have motivated researchers to consider them for communication systems
The importance of deploying LEO satellites to support the terrestrial communication networks has been emphasized in literature [2], obtaining LEO satellites that are capable of providing the same quality of service (QoS) as that of the terrestrial network remains a big challenge
It is known that the latency requirements for the 5G connection should not exceed 1 ms for the ultra-Reliable Low Latency Communication services and 4 ms for the enhanced Mobile Broadband services
Summary
T HE vicinity to the earth, low-cost, relatively low complexity, and off-the-shelf elements are unique merits for LEO satellites; which have motivated researchers to consider them for communication systems. Several papers have proposed schemes that utilize the high-capacity of GEO satellites and the low latency of LEO satellites at the same time. The high number of antennas in the 5G mission, which are required on the LEO satellite to support connections between the constellation’s satellites, between GEO satellites and LEO satellites, and between LEO satellites and the earth, contributes to increasing the consumed power from the Electrical Power System (EPS). The optimal EPS characteristics of one common type of LEO satellites (Cubesat) are investigated for the 5G mission. To this end, the CubeSat’s subsystems are defined, so the satellite’s energy requirements can be specified.
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