• Refine Query
  • Source
  • Publication year
  • to
  • Language
  • 2
  • 2
  • Tagged with
  • 2
  • 2
  • 2
  • 2
  • 2
  • 2
  • 2
  • 2
  • 2
  • 1
  • 1
  • 1
  • 1
  • 1
  • 1
  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
1

GS-based電腦輔助同步合作學習對國小學童閱讀理解成效之研究 / A study of GS-based CSCL for elementary school students on the effectiveness of reading comprehension

楊肅健, Yang, Suh Jiann Unknown Date (has links)
學童階段推動閱讀教育非常重要,過去不乏對於閱讀動機與閱讀興趣之調查研究,但對於新興之數位閱讀實證性研究瞭解有限,有鑑於數位媒體將逐漸成為閱讀的新趨勢,本研究旨在探討GS-based 合作學習活動運用在國小閱讀教學的可行性,將學生的閱讀合作學習及教師的教學策略串連,研究採用準實驗研究法,以金門縣二所國小四年級各一班的學生,分成實驗組與控制組,實驗組進行「運用GS軟體結合電子繪本的合作學習教學活動」,而控制組進行「電腦教室環境不分組的大班電子繪本教學活動」,經過實驗處理後,接受「自編閱讀理解測驗」,以比較學生在閱讀理解成效的差異性,輔之以問卷調查實驗組學生對課程活動的態度看法,並以研究者觀察、錄影及訪談作為質性資料討論,最後,根據研究結果提出具體建議,以提供未來研究與教師在運用電腦輔助合作學習融入閱讀教學時之參考。 研究發現如下: 一、GS-based電腦輔助合作學習活動的閱讀教學模式,學生在閱讀理解成效方面,優於不分組大班學生獨立學習的電子繪本閱讀教學模式。 二、GS-based電腦輔助合作學習活動的閱讀教學,有利於幫助學生在推論分析及詮釋整合層次的閱讀理解,尤其是詮釋整合的理解歷程上,閱讀理解成效最為顯著。 三、無論是高成就組、中成就組或低成就組,實驗組不同成就組別之學生的閱讀理解成效皆優於控制組,尤以中成就組之學生,閱讀理解成效最為顯著。 四、透過GS-based合作學習活動,有助於小組集思廣益。積極參與型的小組運作,小組後測平均成績比主領導強勢型、無領導零碎型的小組運作方式成績高。 五、學生對GS結合電子繪本合作學習活動的新穎學習模式,持正向肯定的態度,同時認為可提高閱讀的興趣。 / The purpose of research is to discuss the practicability of applying GS- based collaborative learning project to reading instruction of primary school, which is to connect the reading collaborative learning with teachers’ teaching strategy. The research uses Quasi-experimental method by separating classes of students from two primary schools in Kinmen County as an experimental group and a control group. Experimental group implements the collaborative learning project by applying GS software to connect with electronic books and control group practices the ungrouped electronic books learning project in the computer classroom. After experimenting, to know the students’ reading comprehensive effectiveness, the students accepted the self-prepared comprehension tests and to use questionnaire survey to know how the students of experimental group think about the learning project. Moreover, serving as the researchers to observe, make the video record and interview as the qualitative for discussions ; finally, to address specific suggestions according to research result so as to provide the reference for future researches and teachers when they collaboratively apply computer to reading instruction. The research findings are as followings: (1)The reading instruction of applying GS based computer to collaborative learning project, the students’ reading comprehensive effectiveness is better than students who independently learn with the electronic books reading ins- truction in the big ungrouped class. (2)The reading instruction of applying GS-based computer to collaborative learning project is helpful for students’ reading comprehension on the parts of inferential analysis and interpretation of integrating levels; especially in the interpretation of integrating comprehensive process, the reading comprehend- sion is the most significant. (3)No matter for high achievement group, middle achievement group or low achievement group, the different experimental groups of students’ reading comprehension are better than control groups; especially the middle achieve- ment groups. Their reading comprehensive effectiveness is the best. (4)GS-based collaborative learning project is helpful for group thinking. The operation of group is positive and active. Their test results are better than con- trol group and non-leader fragmented group. (5)The students are positive about GS connecting electronic books with collaborative learning project and they also think which can enhance their inte- rest to reading.
2

電腦輔助合作學習與知識翻新對大學生科學本質觀之影響 / Effects of computer-supported collaborative learning and knowledge building on college students’ view of nature of science

林靜宜 Unknown Date (has links)
本研究的主要目的在幫助學生發展更主動與建構取向的科學本質觀。以42位修習「自然科學概論」通識課程的大學生為對象,採用「知識論壇」(Knowledge Forum, KF)的線上學習帄台,透過集體共構與分享知識讓學生學習自然科學,並在線上進行知識翻新(knowledge-building)。 研究資料主要來自(1)帄台上的貼文--以此分析學生知識建構與合作分享的情形;(2)「科學本質問卷」--以此分析學生在期初與期末對自然科學本質概念的轉變;(3)科學理論開放問卷--以此探討學生在期初與期末對科學理論概念的差異;以及(4)學生自我反思--藉此了解學生科學觀點轉變的過程。資料分析主要為推論統計之單因子變異數分析及質性的內容分析法。根據分析結果,本研究提出以下四點結論: 一、相較於傳統課堂,學生表現出比較多的同儕互動,特別是在知識論壇帄台中的活動。透過分享與想法的連結(每人帄均貼文14.5篇,貼文連結度達26.9%),帄台中呈現出密切的知識建構與互動學習。而隨著時間的增長,同儕之間的互動密集度亦呈現逐步增加的趨勢(期初10.1%,期末16.6%)。此外,除了互動學習,學生也在課室中扮演科學史的探索者,透過自身與同儕資訊分享的力量,建構對科學理論發展的認知。根據研究結果,在知識論壇中的活動顯示出學生合作學習與互動頻繁,並能透過多元的學習模式進行知識翻新。 二、學生的科學本質觀產生轉變。在科學本質中的「暫時性」、「理論蘊涵」、「多元化」、「發明觀」、「想像力使用」、「科學知識檢證」與「主觀性」等陎向,期末呈現顯著的轉變,從比較實證的觀點轉變為比較建構的取向。此結果顯示出學生對於科學本質逐漸具備較多元的 看法,認為科學是多元發展的。 三、學生對科學理論的認識也漸趨「建構取向」。針對科學理論在「科學理論知識」、「科學理論探究方法」、「科學理論來源」、「科學理論與科學事業發展」以及「科學理論價值性」等五個陎向,期末時學生對於科學理論的認識逐漸呈現多元與建構的觀點。研究結果顯示,學生認為科學理論是可以從不同角度去進行探究,藉由不同觀點的研究方法或程序,它是可以被不斷翻新與修正的;每個人也都可以透過集體合作、討論、發想來形成新的科學理論概念。 四、從期末反思中發現學生的科學態度亦產生變化。學生了解到理論與想法的進步是需要經過不斷的修改與翻新。再者,學生也認知到理論與理論之間關係緊密,科學家、科學理論之間的不斷互動是促進科學理論演化的動力;最後,學生也瞭解到科學學習應秉持質疑、創新的態度,適時批判權威理論而不照單全收,並且應培養主動學習、勇敢懷疑的態度,以及應能提出自己的想法與他人激盪等,如此方能真正認識科學理論的本質,並有助於推動科學的進步。 本研究根據研究結果及發現,在科學教學與學習方陎提出下列六點建議:(1)擺脫記憶、背誦的科學學習方式;(2)儘量不給標準答案,強調學習者間腦力激盪;(3)建構式科學學習,融入科學史,讓學習者自我建構並認知科學知識;(4)創造互動與合作的知識建構環境;(5)教師應多引導想法的討論與激盪,刺激學生以多元觀點進行對話與知識翻新;(6)脫離制式、標準的教學程序,營建開放的學習環境並促進多元想法。 / The purpose of this study was to help college students develop more informed and sophisticated scientific epistemological beliefs. Forty-two undergraduates who took a college course titled ―Introduction to Natural Sciences‖ participated in the study. An online collaborative knowledge building environment, enabled by a software program called Knowledge Forum, was provided for students’ knowledge work. Data primarily came from (1) Students’ online discourse: which was posted in the form of notes, recorded in a Knowledge Forum database, and was used to analyze students’ collaborative learning and knowledge building. (2) A questionnaire—View on Science and Education Questionnaire (VOSE): which was originally designed and validated by Chen (2006) and it was used to analyze the differences of students’ view of nature of science between the beginning and the end of the course. (3) A open-ended survey with regard to the nature of scientific theory: which was employed to triangulate the findings derived from the VOSE and was administered in the beginning and at the end of the course. (4) Students’ self-reflection on what they learned from this course. To analyze, quantitative statistics (e.g., ANOVA) was employed to explore students’ online activities. Additionally, an open-coding procedure was adapted to content-analyze students’ notes. There were four main findings as follows: (1) Students shared ideas constantly, developed connections among ideas, and worked collaboratively and closely with knowledge in Knowledge Forum (with mean number of notes posted being 14.5 and percentage of notes linked being 26.9%). Furthermore, there was an gradual increase in students’ online discourse as reflected by the density of network interaction (10.1 % in the beginning of the course vs. 16.6% at the end of the course). In addition, students served as explorers by reconstructing stories of natural science history in Knowledge Forum, in order to develop a deeper understanding of the process of scientific theory development. The findings suggest that students worked closely together in collaborative learning and interaction, and were able to build knowledge using multiple methods in Knowledge Forum. (2) Students also changed their view of nature of science. It was found that there were significant pre-post change between their view in the beginning and that at the end of the course, in terms of the following seven dimensions: ―tentativeness‖, ―nature of observations‖, ―scientific methods‖, ―theories and laws‖, ―use of imagination‖, ―validation of scientific knowledge‖, and ―subjectivity and objectivity‖. Overall, students’ view shifted from more positivism-oriented to more constructivism-oriented. It was found that towards the end of the course, students started to possess more multiplistic view of nature of science. Students thought that science is advanced by means of multiplistic ways with no standardized methods. (3) In terms of students’ view of scientific theory, it became more ―constructivism-oriented‖ and more multiplistic towards the end of semester, in terms of the following five dimensions: ―knowledge about scientific theory-building‖, ―method of scientific theory-building‖, ―source of scientific theory‖, ―scientific theory and science as an enterprise‖ and ―value of scientific theory‖. It was found that student thought that scientific theory is developed through inquisition from many perspectives. Scientific theory is falsifiable, rather than fixed knowledge entity, and it should not be associated with pre-determined research procedure and standardized answers. Scientific theory can be improved by collaboration discussion and use of imagination. (4) In terms of students’ self-reflection on what they learned from this course, it was found that students demonstrated better understanding that theories are improvable, and that it is important to relate one theory to another for the purpose of creating new knowledge. Moreover, students also realized that it is important to possess critical and creative attitude towards studying science. Building on the above results, this study made the following six suggestions: (1) science learning must go beyond memorization and rote learning; (2) science learning should avoid the pursuit of standardized answers and encourage idea brainstorming; (3) science teachers should promote more constructive way of science learning, try to integrate history of science into science teaching, and help learners construct their own understanding of science; (4) it is important to cultivate a more creative and collaborative learning environment; (5) science teachers should also help students learn how to work with ideas, discuss together, and solve conflicting views; and (6) science teachers should help create an open environment to promote multiple scientific views.

Page generated in 0.0226 seconds