近年來利用光纖作為感測網路架構的實驗紛紛被提出，主要是因為光纖具備有細小、質輕、耐高溫、抗腐蝕、不受電磁感擾等的優點。相較於傳統的電子機械式感測系統，光纖感測網路的感測範圍更大且其製造成本也更為低廉，故使得光纖感測網路在感測系統上有舉足輕重的地位。
在本論文所提出的感測網路架構中，同時應用了分時多工技術以及分波多工技術來提升感測網路的感測範圍與感測容量，此外由於大範圍的監測網路都需要一個高輸出功率的光源，這裡我們所用的光源為迴圈式光纖雷射。隨著光纖感測網路範圍越來越大，光纖感測網路的可靠性與存活率就變成另一個大家努力的目標，因此我們將提出一個具有非常優越自我治癒能力的感測網路架構，在網路發生故障時系統可以藉由控制遠端移動點有效的切換傳輸路徑以取代毀壞的路徑，使得感測網路依然可以正常監測工作。
在我們所提出的感測網路中我們還加入了陣列式波導光柵，利用陣列式波導光柵輸出頻道的中心波長與光纖布拉格光柵的反射波長之間的關係，使得我們可以藉由測量陣列式波導光柵輸出的光強度達到分析光纖布拉格光柵受到的拉力大小的目的，因此大大的提升了監測的速度並且有效地降低成本。本論文所提出的環形網狀布拉格感測網路的原理架構及應用，都予以詳述的分析與實驗驗證，該成果希望有助於光纖通訊系統以及感測網路的發展。

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