本篇論文主要利用光注入與光回饋共同作用下之系統產生週期一動態，並利用週期一動態特性，在不減少原本光雙調制邊帶能量的條件下，達到光雙單調制邊帶轉換的目的，以克服光載微波通訊系統在進行訊號傳輸時產生的能量消逝效應。本文深入了解各物理量在調制前後以及隨著不同注入條件改變所產生的變化，並加以分析可能的原因，研究如何達到更好的轉換效果，在達成光雙單調制邊帶轉換的同時也能成功將微波功率放大，除此之外，提高調制深度也能使系統可操作範圍更廣，更具便利性。另外由於光注入與光回饋共同作用下之系統的複雜與多變性，存在更多研究空間，因此本文分成兩章節分別討論操作系統為光注入操作在穩態且光回饋操作在週期一動態以及操作系統為光注入操作在穩態且光回饋操作在週期一動態的轉換效果，並在文末比較其優劣。

optical single-sideband (SSB) modulation signals are preferred to optical double-sideband (DSB) modulation signals when we need to distribute microwaves over fibers. This purpose of this study is to investigate an optically injected semiconductor laser with optical feedback at period-one nonlinear dynamics for optical DSB-to-SSB conversion. For the operating microwave frequencies up to 37 GHz investigated in this study, the proposed system regenerates or even enhances the microwave features of an optical DSB input while converting its optical feature into SSB with an intensity difference of at least 20 dB. As will be shown in the following sections, optical double-sideband modulation to optical signal-sideband modulation conversion and photonic microwave amplification are simultaneously achieved.

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