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研究生: 陳培基
Chen, Pei-Chi
論文名稱: 運算思維策略融入技職體系學生學習成效之研究 -以可程式控制為例
The Study of the Learning Effectiveness of Vocational and Technical Students regarding the Integration of Computational Thinking Strategies:Case study of Programmable Logic Controller
指導教授: 周明
Jou, Min
口試委員: 周春美 石文傑 蕭照焜 曾百由 周明
口試日期: 2021/06/24
學位類別: 博士
Doctor
系所名稱: 工業教育學系
Department of Industrial Education
論文出版年: 2021
畢業學年度: 109
語文別: 中文
論文頁數: 215
中文關鍵詞: 技職體系運算思維問題導向學習技能自主學習學習遷移ADDIE教材發展模式
英文關鍵詞: technical and vocational education system, computational thinking, Problem-Based Learning, skills, self-directed learning, learning transfer, ADDIE textbook development model
研究方法: 準實驗設計法調查研究半結構式訪談法
DOI URL: http://doi.org/10.6345/NTNU202100796
論文種類: 學術論文
相關次數: 點閱:325下載:0
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  • 本研究旨在融入運算思維策略於可程式控制實習課程,以提升技職體系電機與電子群科(系)學生的技能表現。實驗研究以公私立科技大學各兩班學生(合計120人)、公私立技術型高中各兩班學生(合計120人)為研究對象(合計240人),每週授課兩小時、為期八週的實習課程教學。在實施教學實驗前,實驗組與控制組均接受一般生活化運算思維之前測;在實驗進行階段,實驗組於教學中融入一般生活化運算思維策略教學與使用PLC運算思維教材授課,控制組則採用傳統PLC教材教學,且為了強化學習效能,實驗組與控制組在教學中均採用PBL,並要求學生於課後至雲端教學平台進行自主學習;在實驗結束前,實驗組與控制組均接受一般生活化運算思維策略之後測與PLC學習成效測驗。研究結果發現:(1)技職體系全體實驗組學生之PLC學習成效明顯優於控制組學生;(2)技職體系全體運算思維高分組學生之PLC學習成效明顯優於運算思維低分組學生,由研究結果得知,運算思維素養較高之技職體系學生,能有效提升其實習之學習成效。此外,本研究透過觀察、學生日誌、教師日誌與課堂錄影等資料,進一步了解技術型高中電機與電子群科學生技能表現的改變情形,以及對於本課程方案的態度與看法。植基於研究之結果,本研究據以提出技職體系融入運算思維策略之教學模式,以供技職體系實習課程融入運算思維策略教學之參用。

    This research aims to integrate computational thinking strategies into programmable control practice courses to improve the technical performance of students in the electrical and electronic group (department) of technical and vocational education system. The experimental research takes a class of students from public and private universities of science and technology (120 people in total) and a class of students from public and private vocational high schools (120 people in total) as the research objects (240 people in total) to a 2-hour/week practical course for 8 weeks. Before the implementation of the teaching experiment, both the experimental group and the control group accept the pre-test of general life-oriented computing thinking. In the experimental stage, the experimental group integrates general life-oriented computing thinking strategy teaching and the use of PLC computing thinking textbooks into teaching. On the other hand, the control group is using traditional PLC teaching materials. In order to strengthen learning effectiveness, both the experimental group and the control group use PBL in teaching and students are required to enter the cloud teaching platform for autonomous learning after class. Before the end of the experiment, both the experimental group and the control group take general life-oriented computing thinking strategy post-test and PLC learning effectiveness test. The results of the study found that: (1) The PLC learning effectiveness of all experimental group students in technical and vocational education system was significantly better than that of control group students. (2) The PLC learning effectiveness of all students in the high computational thinking group of technical and vocational education system was significantly better than that of the low computational thinking group according to the research results. Students from technical and vocational education system with higher computational thinking literacy can effectively improve the learning effectiveness of their internships. In addition, this research uses observations, student journals, teacher journals, classroom videos and other materials to further understand the changes in the performance of technical high school electrical and electronic group students, as well as their attitudes and views on the course plan. Based on the results of the research, this research proposes a computational-thinking-strategies-integrated teaching model for the consideration of integrating computational thinking strategies into technical and vocational education system practice courses.

    摘要 i ABSTRACT ii 目次 iv 表次 vii 圖次 ix 第一章 緒論 1 第一節 研究背景與動機 3 第二節 研究目的與待答問題 8 第三節 名詞釋義 12 第四節 研究範圍與限制 26 第二章 文獻探討 29 第一節 工業 4.0 的來臨 29 第二節 科學探究活動與教學 46 第三節 運算思維策略 57 第四節 電機與電子群108課綱 64 第五節 可程式控制實習 66 第六節 自主學習及其相關研究 70 第七節 技能學習階層 85 第八節 學習遷移 88 第九節 ADDIE教材發展模式 91 第三章 研究設計與實施 93 第一節 研究對象 93 第二節 研究場域 94 第三節 研究架構 97 第四節 實驗設計 98 第五節 課程設計流程 101 第六節 實驗教學實施 106 第七節 研究工具 117 第八節 資料處理 125 第四章 研究結果與分析 129 第一節 PLC學習成效結果分析 129 第二節 質性訪談分析 146 第三節 本章小節 153 第五章 結論與建議 157 第一節 結論 157 第二節 建議 160 參考文獻 163 附錄 179 附錄一:教師日誌 179 附錄二:學習日誌 180 附錄三:訪談問題 181 附錄四:運算思維生活模擬試題 182 附錄五:技職體系現職教師觀課意見表 185 附錄六:第一堂課教案 186 附錄七:第二堂課教案 187 附錄八:第三堂課教案 188 附錄九:第四堂課教案 189 附錄十:第五堂課教案 190 附錄十一:第六堂課教案 191 附錄十二:第七堂課教案 192 附錄十三:第八堂課教案 193 附錄十四:學習者前測的質性回饋 194 附錄十五:學習者後測的質性回饋 195 附錄十六:可程式邏輯控制器之運算思維自我評估能力量表 196 附錄十七:技術型高中學生自我導向學習量表 199 附錄十八:技職體系學生自主學習量表(正式問卷) 205 附錄十九:108學年度臺北市立內湖高工電機科教學科目與學分數表 213 附錄二十:108學年度臺北市立內湖高工控制科教學科目與學分數表 214 附錄二十一:108學年度臺北市立內湖高工冷凍科教學科目與學分數表 215

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