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Theoretical Proof and Implementation of Digital Beam Control and Beamforming Algorithm for Low Earth Orbit Satellite Broadcast Signal Reception Processing Terminal

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Publicado en:Electronics vol. 14, no. 3 (2025), p. 440
Autor principal: Shen, Haoran
Otros Autores: Li, Jian, Li, Xiaozhi, Cheng, Ruiqi, Hao, Kexin, Wang, Ziwei
Publicado:
MDPI AG
Materias:
China
Receivers & amplifiers
Antenna arrays
Accuracy
Satellite communications
Beamforming
Sidelobes
Rocket launches
Self calibration
Optimization
Signal processing
Error analysis
Field programmable gate arrays
Digital signal processors
Radio broadcasting
Research & development > R&D
Synthesis
Low earth orbit satellites
Low earth orbits
Spherical antennas
Lookup tables
Antennas
Flexibility
Algorithms
Signal reception
Radar systems
Radio signals
Parameter estimation
Signal to noise ratio
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Resumen:Compared to analog beamforming, digital beamforming offers better self-calibration and lower sidelobe performance, which has a profound impact on improving low Earth orbit receiver performance. The Digital Beamforming (DBF) module in the low Earth orbit satellite broadcast signal reception terminal can use digital phase shifting to compensate for the phase differences caused by path and spatial distance variations due to inconsistent Radio Frequency (RF) channel delays. This compensation ensures in-phase summation, thereby achieving maximum energy reception in the desired direction. Although DBF has gained widespread attention in the radar field due to its unique functions and advantages, its application is limited by beamforming accuracy and gain. Therefore, with the development of DBF technology, how to improve its accuracy and gain has also attracted extensive attention both domestically and internationally. To address this issue, this paper proposes a beamforming method based on a cap-shaped array for low Earth orbit satellite broadcast signal reception and processing terminals. The method combines prior information and spatial domain search for beam control, and employs a lookup table for beam synthesis. It derives formulas for the Signal-to-Noise Ratio, noise figure, processing flow of the beamforming network, and the determination of beamforming weights for the spherical antenna array. The paper presents a beam control approach that combines prior information with spatial domain search, along with an implementation process for beam synthesis using a lookup table. It also details the corresponding Field-Programmable Gate Array (FPGA) implementation process. Finally, the beamforming algorithm is experimentally validated, and error analysis is conducted. The experimental results show that the measured beamforming sensitivity at all incident angles is below −133 dBm and the G/T values are all greater than −9 dB/K, the beam uniformity at three operating frequencies is less than 3°, and the measured errors in pitch and azimuth angles are both below 2°. The beam pointing error is also below 2°.
ISSN:2079-9292
DOI:10.3390/electronics14030440
Fuente:Advanced Technologies & Aerospace Database