TY - GEN
T1 - CubeSat Downlink Communications Enhanced by Movable Antennas
AU - Khodkar, Zeynab
AU - Yan, Shihao
AU - Ali Shah, Syed Afaq
AU - Biswa, Rajen
AU - de Souza, Paulo
AU - Uggalla, Leshan
AU - Kwan Ng, Derrick Wing
PY - 2025/9/26
Y1 - 2025/9/26
N2 - In this work, we propose to use the emerging movable antenna (MA) technology for enhancing the performance of a CubeSat downlink communication system. Specifically, one surface of the CubeSat is considered as the transmit region for antenna movement. Meanwhile, solar panels, which are deployed above the CubeSat body, are regarded as reflectors that lead to multi-path signals and may intensify channel gains. This phenomenon is exploited in this work to maximize the downlink channel gain by adjusting MA positions in the transmit region. The continuous orbital movement of the CubeSat alters the angle of departure (AoD) of each transmitted signal, which may potentially affect channel gains across numerous positions in the transmit region. Therefore, the maximum channel gain is achieved for different elevation angles of the CubeSat via moving the antenna across the entire transmit region. Numerical results confirm that the optimal position of the MA could be different for different CubeSat elevation angles. In addition, our examinations shows that the maximum average channel gain achieved by MA is higher by more than 3 dB compared to the fixed antenna case. This demonstrates that the emerging MA technology can significantly enhance the CubeSat communication performance (e.g., extending the communication coverage of the CubeSat), especially when the CubeSat is near the horizon relative to a ground receiver.
AB - In this work, we propose to use the emerging movable antenna (MA) technology for enhancing the performance of a CubeSat downlink communication system. Specifically, one surface of the CubeSat is considered as the transmit region for antenna movement. Meanwhile, solar panels, which are deployed above the CubeSat body, are regarded as reflectors that lead to multi-path signals and may intensify channel gains. This phenomenon is exploited in this work to maximize the downlink channel gain by adjusting MA positions in the transmit region. The continuous orbital movement of the CubeSat alters the angle of departure (AoD) of each transmitted signal, which may potentially affect channel gains across numerous positions in the transmit region. Therefore, the maximum channel gain is achieved for different elevation angles of the CubeSat via moving the antenna across the entire transmit region. Numerical results confirm that the optimal position of the MA could be different for different CubeSat elevation angles. In addition, our examinations shows that the maximum average channel gain achieved by MA is higher by more than 3 dB compared to the fixed antenna case. This demonstrates that the emerging MA technology can significantly enhance the CubeSat communication performance (e.g., extending the communication coverage of the CubeSat), especially when the CubeSat is near the horizon relative to a ground receiver.
KW - Cube Sat
U2 - 10.1109/ICC52391.2025.11161675
DO - 10.1109/ICC52391.2025.11161675
M3 - Conference contribution
SN - 979-8-3315-0522-6
T3 - ICC 2025 - IEEE International Conference on Communications
SP - 1061
EP - 1066
BT - ICC 2025 - IEEE International Conference on Communications
A2 - Valenti, Matthew
A2 - Reed, David
A2 - Torres, Melissa
CY - Montreal, QC, Canada
T2 - ICC 2025 - IEEE International Conference on Communications
Y2 - 8 June 2025 through 12 June 2025
ER -