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研究生:李東鴻
研究生(外文):Li, Tung-Hung
論文名稱:基於智慧型倒階同動控制之三軸龍門式定位平台
論文名稱(外文):Intelligent Backstepping Synchronous Control for Three-Axis Gantry Positioning Stage
指導教授:陳瑄易
指導教授(外文):Chen, Syuan-Yi
學位類別:碩士
校院名稱:國立臺灣師範大學
系所名稱:電機工程學系
學門:工程學門
學類:電資工程學類
論文種類:學術論文
論文出版年:2017
畢業學年度:105
語文別:中文
論文頁數:97
中文關鍵詞:動態面控制函數鏈結模糊類神經網路龍門式定位平台非整數階倒階控制雙平行線型馬達同動控制
外文關鍵詞:Dynamic Surface ControlFunctional-Link-Based Neural Fuzzy SystemGantry Position StageNon-Integer Order Backstepping ControlParallel Linear MotorsSynchronous Control
相關次數:
  • 被引用被引用:2
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  • 下載下載:41
  • 收藏至我的研究室書目清單書目收藏:0
本論文以個人電腦控制為基礎,發展具有高精度與高強健性之智慧型同動控制系統於龍門式定位平台。龍門式定位平台係利用三部永磁線型同步馬達組合成H型運動模式之雙軸定位平台,其中由於垂直方向是由兩部平行馬達共同驅動,故同動控制遂成為研究龍門式定位平台之重要課題。有鑑於此,本論文先發展單軸馬達倒階控制系統,再將非整數階微積分計算加入其中,以增加可控制參數自由度之方式改善控制效能。接著,為了加強系統的強健性,使用函數鏈結模糊類神經網路對系統不確定項進行估測與補償。而為了達到雙平行馬達之同動,本論文基於單軸控制之基礎,進一步以Lagrange 方程式建立三自由度龍門動態模型,同時為了避免倒階控制中微分膨脹之問題,於設計過程中引入一階低通濾波器成為動態面控制,而為了提升各軸之控制精準度與雙軸之同動效果,亦引入非整數階微積分系統於動態面控制。最後為了確保系統在參數變化、外在干擾與摩擦力等影響下系統均具備強健性,再利用函數鏈結模糊類神經網路直接補償系統之不確定項,並進行控制系統之穩定性分析。本論文所發展之控制系統皆由個人電腦實現,並由實作結果驗證所設計之控制理論有效性與可行性。
關鍵字:動態面控制、函數鏈結模糊類神經網路、龍門式定位平台、非整數階倒階控制、雙平行線型馬達、同動控制
The objective of this thesis is to develop personal computer (PC) based high precision and robust intelligent synchronous control systems for a gantry position stage. The gantry position stage is composed of H-type three permanent magnet linear synchronous motors (PMLSMs) in which the vertical direction is driven by two parallel motors. In this regard, the synchronous control has become an important research task of gantry position stage. In this thesis, a backstepping control (BC) system is developed to control the single axis PMLSM first. Then the non-integer calculus is added to increase the degree of freedom of controlled parameter for the improvement of control performance. Moreover, in order to strengthen the robustness of the system, a functional-link-based fuzzy neural network (FLFNN) is developed to estimate and compensate the system uncertainties. In order to achieve the synchronous control of the parallel motors, a Lagrange’s equation is used to establish the three-degree-of-freedom (3-DOF) dynamic model of gantry stage. Furthermore, to avoid differential expansion problem in the design of the BC, a first-order low-pass filter is introduced to perform dynamic surface control (DSC). For the purpose of enhancing the control accuracy of each axis and the synchronization performance of the parallel axes. A non-integer order calculus is further utilized for DSC. Finally, in order to ensure the robustness of the system under the influences of parameters variations and external interferences. In addition, the FNFS is employed to compensate the system uncertainties directly. All the control systems developed by this thesis were realized by PC to verify the effectiveness and feasibility experimentally.
摘要 II
ABSTRACT III
誌謝 V
目錄 VI
圖目錄 VIII
表目錄 XII
第一章 緒論 1
1.1 研究背景與動機 1
1.2 文獻探討 2
1.3 研究目的與方法 5
1.4 研究架構 7
第二章 三軸龍門式定位平台介紹 8
2.1 永磁線型同步馬達之基本介紹 8
2.2 單軸永磁線型同步馬達之工作原理 10
2.3 伺服驅動器 12
2.4電腦硬體設備及軟體介面 13
2.5龍門式定位平台控制系統之控制流程介紹 15
第三章 基於非整數階倒階控制之單軸永磁線型同步馬達控制系統 17
3.1 簡介 17
3.2倒階控制器設計 17
3.3非整數階倒階控制系統 19
3.3.1非整數階倒階控制器設計 22
3.4智慧型非整數階倒階控制系統 24
3.4.1函數鏈結模糊類神經網路架構 24
3.4.2智慧型非整數階倒階控制器設計 27
第四章 基於智慧型動態面同動控制之三軸龍門式定位平台 32
4.1 簡介 32
4.2 三自由度龍門動態模型 33
4.3基於三自由度龍門動態模型之動態面控制器設計 36
4.4基於三自由度龍門動態模型之非整數階動態面控制器設計 39
4.5基於三自由度龍門動態模型之智慧型非整數階動態面控制器設計 41
第五章 實驗結果與討論 48
5.1 實驗設置 48
5.2單軸實驗結果 50
5.3三軸實驗結果 58
第六章 結論與未來研究展望 89
參考文獻 90
自傳 96
學術成就 97
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