癌症及創傷對人類而言一直都是非常嚴重的威脅。電磁熱療的技術日漸進步，再加上高溫治療法的微創技術演進，為癌症的病患帶來一線曙光。燒灼治療原理是藉由高頻感應加熱器產生一交變磁場，並利用此磁場加熱在病灶區中的感磁治療針具，使感磁針具升溫至能燒灼腫瘤細胞的溫度，進而達到治療局部腫瘤之療效。本論文針對市售的高週波加熱器之加熱線圈進行改良與實驗研究分析，並改善系統電流回授機制，使系統能更準確、更穩定地運作以及能長時間監測機台，進而達到醫療儀器所要求之安全性。並輔以一多功能之人機介面，讓使用者可更方便地進行操作系統、設定系統相關參數及監控系統狀態，以達到即時控制之目的。

Cancer and trauma are the major threats to human beings up to present. The therapy method for these threats still needs further improvement. The use of electromagnetic thermotherapy systems in surgery offers new hope for these patients. The principle of ablation therapy is to create an alternating magnetic field by high-frequency induction heating machine, so that the magnetically sensitive needle in the lesion can be heated by this magnetic field to reach a temperature that is able to cauterize the tumor cells, in this way the therapeutic effect on local tumor could be achieved. The objective of this thesis is to analyze the applicator of the commercially available high-frequency heating devices, and to improve the accuracy the current feedback mechanism of the system for long time operation. We also designed a GUI program that can be used to easily control the system, setup parameters, and real-time monitor the state of the system.

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