| 摘要: | 本研究針對低軌道(Low Earth Orbit, LEO)衛星所使用之相控陣列天線系統進行探討,聚焦於天線單元失效所造成的波束品質劣化問題。由於衛星運行環境嚴苛,天線元件長期運作下容易因輻射、溫度循環或製程缺陷而產生故障,進而導致陣列輻射場型偏移,降低通訊效能。為解決此一挑戰,本研究提出一種基於深度學習之天線權重修復方法,透過輸入失效位置與原始權重配置,利用神經網路自動重新分配剩餘正常天線之權重,以實現容錯波束成形(fault-tolerant beamforming),有效恢復近似原始狀態之天線輻射模式。
在演算法設計方面,本研究採用自編碼器(Autoencoder)神經網路架構,並透過大量模擬天線失效資料進行訓練,使模型能學習不同失效組合下的修復策略。模擬結果顯示,在單一、雙重與三重天線失效情境下,所提出方法皆能有效抑制旁瓣水準(SLL)並維持原始半功率波束寬度(HPBW),其平均修復率相較傳統啟發式演算法具有顯著提升。此外,本研究特別考慮天線失效位置之各種排列組合,不論位於中央或邊緣,皆能展現穩定修復效果,顯示其優異的泛化能力。
本研究亦進一步將所提神經網路演算法實現為晶片架構,設計專用之運算單元、權重記憶體與近似激活函數電路,並透過Cell-based 流程於40 奈米CMOS 製程下完成電路實現,達成238 MHz 運作頻率,具備即時推論能力。研究成果驗證了深度學習結合硬體加速於衛星通訊應用的可行性,成功達成具備自我修復能力之衛星相控陣列系統設計目標。;This study focuses on phased array antenna systems in Low Earth Orbit (LEO) satellites, addressing the beam quality degradation caused by antenna element failures. Due to the harsh space environment, antenna elements are prone to long-term faults from radiation, thermal cycling, or manufacturing defects, leading to deviations in radiation patterns and reduced communication performance. To tackle this challenge, we propose a deep learning–based antenna weight recovery method that reallocates the weights of functional elements based on failure locations and original configurations, thereby enabling fault-tolerant beamforming and restoring radiation patterns close to the original state.
An Autoencoder neural network architecture is employed and trained with a large dataset of simulated antenna failures, enabling the model to learn recovery strategies under different fault combinations. Simulation results show that, for single, double, and triple element failures, the proposed method effectively suppresses sidelobe levels (SLL) and preserves the half-power beamwidth (HPBW), achieving significant improvements in average recovery rates compared with heuristic algorithms. Moreover, all possible failure position combinations are considered, and consistent recovery performance is achieved for both central and edge failures, demonstrating strong generalization capability.
The algorithm is further implemented in hardware through a circuit architecture with dedicated computing units, weight memory, and approximate activation function circuits. Using a cell-based flow in a 40-nm CMOS process, the design achieves 238 MHz operating frequency with real-time inference capability. These results confirm the feasibility of combining deep learning with hardware acceleration for satellite communications and demonstrate the potential of self-healing phased array antenna systems. |
