Abstract
This paper proposes a robust digital signal recovery (DSR) technique to tackle the high signal-to-noise ratio (SNR) variation and transmitter memory effects for broadband power efficient down-link in next-generation low Earth orbit (LEO) satellite constellations. The robustness against low SNR is achieved by concurrently integrating magnitude normalization and noise feature filtering using a filtering block built with one batch normalization (BN) layer and two bidirectional long short-term memory (BiLSTM) layers. Moreover, unlike existing deep neural network-based DSR techniques (DNN-DSR), which failed to effectively take into account the memory effects of radio-frequency power amplifiers (RF-PAs) in the model design, the proposed BiLSTM-DSR technique can extracts the sequential characteristics of the adjacent in-phase (I) and quadrature (Q) samples, and hence can obtain superior memory effects compensation compared with the DNN-DSR technique. Experimental validation results of the proposed BiLSTM-DSR with a 100 MHz bandwidth OFDM signal demonstrate an excellent performance of 11.83 dB and 9.4% improvement for adjacent channel power ratio (ACPR) and error vector magnitude (EVM), respectively. BiLSTM-DSR also outperforms the existing DNN-DSR technique in terms of the ACPR and EVM by 2.4 dB and 0.9%, which provides a promising solution for developing deep learning-assisted receivers for high-throughput LEO satellite networks.
Highlights
L OW Earth orbit (LEO) satellite constellations have grown drastically in recent years and have attracted great attention from both academia and industry
This allows spaceborne radio-frequency power amplifiers (RF-PAs) to work in their saturation regions for high power efficiency while maintaining a satisfactory error vector magnitude (EVM) at the ground station
We established a close correlation between our bidirectional long short-term memory (BiLSTM) model and the memory effects of RFPAs and concurrently integrated noise feature filtering and magnitude normalization into a filtering block, which ensures superior signal recovery performance than existing Deep neural network-based digital signal recovery (DNNDSR) techniques
Summary
L OW Earth orbit (LEO) satellite constellations have grown drastically in recent years and have attracted great attention from both academia and industry. Different from RF-PA linearization techniques for narrow band terrestrial communication systems, the mitigation of nonlinear distortion in broadband LEO satellite systems features a few unique challenges including the remarkably varying SNR of the received signal due to the low obit, the strong memory effects that are uneasy to characterize when signal bandwidth increases, and the stringent requirement of high power efficiency and low system complexity for the satellites. The DNN-DSR technique has demonstrated its capability of handling varying power and additive white Gaussian noise (AWGN) This allows LEO spaceborne RF-PAs to operate near their saturation regions for high power efficiency while maintaining satisfactory EVM performance at ground stations. The correlation between the memory effects of RF-PAs and LSTM networks is not studied deeply and intuitively in these papers, especially for broadband systems They are mainly to prevent interference to adjacent channels, and are not EVM quantitative evaluation based RF-PAs nonlinear modeling and linearization.
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