本文主旨係設計與實現一個新型高昇壓多輸出轉換器並完成數位控制晶片之佈局與模擬驗證。相較於傳統的昇壓型電路，本文提出的新型高昇壓轉換器使用了疊接、電壓提升與耦合電感技術而達成了較高的電壓增益比，且該電路具有漏感回收的功能可提升電路轉換效率。先藉由可規畫邏輯閘陣列(FPGA)控制器完成初步的電路控制，其包含有最大功率追蹤、用於電致變色層之正負電壓極性變換及併網型換流器的控制。並以TSMC 0.18μm標準元件庫設計流程，實現太陽能最大功率追蹤晶片之佈局設計與功能模擬驗證。最後，研製一個75W應用於併網型光伏系統的新型高昇壓多輸出轉換器，並由實驗結果驗證多輸出轉換器與控制程式的可行性。

In this thesis, a novel high step-up multiple-output converter and digital control chip are designed and implemented. Compared with the conventional boost circuit, the proposed topology utilizes a coupled inductor, cascade and voltage-lift techniques; therefore, the high voltage gain of the converter can be achieved. Besides, the energy of the leakage inductor is recycled to improve overall conversion efficiency. With the FPGA controller, the system possesses the maximum power point tracking, electrochromic device smart color control, and grid-connected inverter control. After the functions are verified, the MPPT chip is fabricated with TSMC 0.18μm Cell-Based Design Flow. Finally, The proposed converter for 75W grid-connected PV system is implemented to verify the performances of the converter and the control program.

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