• Educational Technology International
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• 제8권2호
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• pp.93-112
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• 2007

This case study explored the potential for implementing content-based English as a Foreign Language (EFL) instruction in a Korean middle school facilitated by computer-mediated communication (CMC). The instructor scaffolded the student participant's language learning online, helping her to produce English output on her own. While experimental social studies lessons on the topic of stereotyping were taught, data were collected on the student's online exchanges with her counterpart in Iran about their respective cultures. Findings show that the student from Korea was able to better understand her own culture as a result of the online experience. This interaction and the in-class lessons have demonstrated that content-based EFL instruction is a viable alternative to the school's existing curriculum.

• 컴퓨터교육학회논문지
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• 제5권3호
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• pp.89-106
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• 2002

본 연구의 목적은 네트웍 기반 협력학습(CSCL)에서 학습자의 성찰을 지원하는 인지적 도구를 설계하는 주요전략과 도구의 구성요소를 탐색해 보는데 있다. CSCL에서는 실세계에서 직면하는 복잡한 문제를 해결하기 위한 방안으로 학습자가 다양한 관점에서 의견을 교환하고 협력하는 활동을 강조한다. 학습경험을 유의미한 의미생성과 지식구성으로 확장하기 위해서는 학습자의 성찰이 필수적이며, 따라서 학습자가 자신 또는 그룹의 학습과정과 결과를 지속적으로 모니터링할 수 있는 기제가 제공될 필요가 있다. 이에 본 연구에서는 학습자 성찰의 중요성을 이론적으로 탐색하고 네트웍 기반 성찰지원 도구에 대한 선행연구들을 분석하여 시사점을 도출하였다. 나아가 사회문화적 인지 이론을 토대로, 협력학습과정을 지원하고 그룹인지를 확장시킬 수 있도록 협력적 성찰지원 도구를 설계하였다. 구체적으로는 (1)학습자의 협력적 인식, (2)사고의 시각화, (3)대화(협상) 촉진, (4)메타타인지적 단서로 세분화하였으며, 성찰지원 도구의 구성요소로서 추석달기, 협력노트 및 메타인지 프롬프트 등의 적용을 제안하였다.

• 한국지구과학회지
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• 제25권3호
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• pp.194-204
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• 2004

The purpose of this literature review is to investigate what kinds of research have been done about scientific inquiry in terms of scientific argumentation in the classroom context from the upper elementary to the high school levels. First, science educators argued that there had not been differentiation between authentic scientific inquiry by scientists and school scientific inquiry by students in the classroom. This uncertainty of goals or definition of scientific inquiry has led to the problem or limitation of implementing scientific inquiry in the classroom. It was also pointed out that students' learning science as inquiry has been done without opportunities of argumentation to understand how scientific knowledge is constructed. Second, what is scientific argumentation, then? Researchers stated that scientific inquiry in the classroom cannot be guaranteed only through hands-on experimentation. Students can understand how scientific knowledge is constructed through their reasoning skills using opportunities of argumentation based on their procedural skills using opportunities of experimentation. Third, many researchers emphasized the social practices of small or whole group work for enhancing students' scientific reasoning skills through argumentations. Different role of leadership in groups and existence of teachers' roles are found to have potential in enhancing students' scientific reasoning skills to understand science as inquiry. Fourth, what is scientific reasoning? Scientific reasoning is defined as an ability to differentiate evidence or data from theory and coordinate them to construct their scientific knowledge based on their collection of data (Kuhn, 1989, 1992; Dunbar & Klahr, 1988, 1989; Reif & Larkin, 1991). Those researchers found that students skills in scientific reasoning are different from scientists. Fifth, for the purpose of enhancing students' scientific reasoning skills to understand how scientific knowledge is constructed, other researchers suggested that teachers' roles in scaffolding could help students develop those skills. Based on this literature review, it is important to find what kinds of generalizable teaching strategies teachers use for students scientific reasoning skills through scientific argumentation and investigate teachers' knowledge of scientific argumentation in the context of scientific inquiry. The relationship between teachers' knowledge and their teaching strategies and between teachers teaching strategies and students scientific reasoning skills can be found out if there is any.

• East Asian mathematical journal
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• 제34권4호
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• pp.339-358
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• 2018

There has been researches for effective education. Among them, many researchers are striving to apply Zone of Proximal Development of Vygotsky which is emphasizing the social interaction in the field of teaching and learning. Researchers usually research based on individual or small group of students. However the math class in school relies on system that one teacher teach many students in reality. So this research will look for the effect that the teaching and learning program based on Zone of Proximal Development of Vygotsky by designing the teaching and learning program which is based on scaffolding structuring to overcome the zone of proximal development in many-students class. The results of this research are as follows: First, the studying program considered the theory of Vygotsky has a positive effect on improving the mathematical achievement of elementary student. Second, the studying program considered the theory of Vygotsky has a positive effect on improving the student's studying attitude upon mathematics.

• 국제초고층학회논문집
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• 제4권3호
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• pp.161-169
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• 2015

Experience on the construction of several 100-plus-story skyscrapers including Guangzhou West Tower, Guangzhou East Tower, and Shenzhen's KK100 is described considering the increasingly strong development trend of 100-plus-story skyscrapers in China. Difficulties in the construction of 100-plus-story skyscrapers are investigated. Four innovative construction technologies receive detailed descriptions: intelligently and entirely-jacked work platforms, formwork and suspension scaffolding systems ("jacking and formwork systems"), multi-function low-carbon concrete, 5D-BIM ("five-dimensional building information modeling"), and safe and rapid vertical transport, as they have found successful applications in actual projects. Popularized systematically as technical achievements, these technologies will significantly influence the construction of similar projects in the future, and produce more social and economic benefits.

• 대한수학교육학회지:수학교육학연구
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• 제9권1호
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• pp.263-278
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• 1999

Computer with various powerful functions has profound potential for mathematics instruction and learning. As computer technology progress, its applicability to mathematics education become more comprehensive. Not only its functional development but various psychological positions also changed the way computer technology utilized in mathematics education. In behaviorist's perspective, computer viewed as a teaching machine and constructivist viewed computer as microworld where students could explore various mathematical contents. Both theoretical positions emphasized individual aspect of learning because behaviorist tried to individualize learning using computer and constructivist focused on the process of individual construction. But learning is not only a individual event but also a social event. Therefore we must take social aspect into account. This is especially important when it comes to computer based learning. So far, mathematics loaming with computer weighed individual aspect of loaming. Even in microworld environment, learning should be mediated by teacher and collaborative learning activities. In this aspect, the roles of teacher and peers are very important and socio-cultural perspective sheds light on the computer based learning. In socio-cultural perspective, the idea of scaffold is very important in learning and students gradually internalize the social dimension and scaffolding is gradually faded. And in the zone of proximal development, teacher and more competent peers guide students to formulate their own understanding. In sum, we must take following points into account. First of all, computer should not be viewed as a medium for individualized teaming. That is, interaction with computer should be catalyst for collaborative activities with peers. So, exploration in computer environment has to be followed by small group activities including small group discussion. Secondly, regardless of the role that computer would play, teacher should play a crucial role in computer based learning. This does not mean teacher should direct every steps in learning process. Teacher's intervention should help student construct actively. Thirdly, it is needed to conceptualize computer in learning situation as medium. This would affect learning situation and result in the change of pre-service and in-service teacher training. Computer to be used effectively in mathematics classroom, researches on assessment of computer based learning are needed.

• 한국콘텐츠학회논문지
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• 제9권1호
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• pp.177-186
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• 2009

가상세계란 컴퓨터를 매개로 하여 2D 혹은 3D로 구현된 가상 환경 속에서 실시간으로 상호작용할 수 있는 영속적 공간으로 이 중 15세 이하의 사용자를 대상으로 하는 가상세계를 어린이용 가상세계라 한다. 가상세계의 교육적 장점으로는 구체적 경험, 현존감, 경험의 공유, 협동 가능성, 유연한 환경을 꼽을 수 있으며 여기에 게임이 가지고 있는 흥미 요소인 명확한 목표, 도전, 협동, 경쟁, 환상을 보탬으로써 교육효과를 높일 수 있다. 한편 가상세계에서의 교육이 효과적으로 이루어지기 위해서는 목표, 동기, 관계, 도움의 네 영역에 속하는 요소들을 두루 고려해야 한다. 이를 기준으로 하여 국내 어린이용 가상세계인 <노리스쿨>, <미스터 텅두>, <아즈로크>를 분석해 본 결과 명확한 목표 제시, 과제의 맥락화, 적절한 강화 제공은 잘 이루어지고 있었으나 준비성, 사회적 설득, 비계 설정 부분의 보완이 필요했다.

• 한국게임학회 논문지
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• 제13권3호
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• pp.141-152
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• 2013

본 연구의 목적은 스마트 기기를 활용한 교수-학습 설계와 학습방법에 대한 새로운 접근 및 방향을 제안하는데 있으며, 첨단 매체를 활용하여 학습자 참여를 촉진하는 게임형태의 주제중심 통합학습 교수설계의 사례를 제시하였다. QR코드를 활용한 주제중심 통합학습의 사례인 퀘스트 기반학습은 학습동기, 경험학습, 사회적 상호작용을 촉진하는 역할을 한다. QR코드를 활용한 설계는 자신의 인지구조를 확장하는데 요구되는 사회적 상호작용 전략, 동기증진 전략, 구성 주의에서 강조하는 복잡한 문제 상황과 스캐폴딩 전략이 포함된 학습자 중심 학습 환경을 지원하였다. 스마트 기기를 이용한 게임형 퀘스트 기반학습을 통해 학습에 대한 흥미 증진, 학습자 중심의 참여 학습, 활동중심, 협력학습, 사회적 상호작용을 통한 지식의 창출 측면에 대한 교수 설계에 창의적인 학습 환경을 제공하는 기회를 확인하였다.

• 한국과학교육학회지
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• 제28권6호
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• pp.592-602
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• 2008

이 연구의 목적은 과학과 교과교육학 지식(PCK)의 의미를 정립하고 수업에서 드러난 과학과 PCK 유형을 도출하는 것이다. 과학과 PCK 구성요소나 유형별 사례를 추출하고 분석하기 위해서, 수업 동영상, 수업분석 협의회 자료, 교사 면담 자료 등을 면밀히 교차 분석하였다. 이어서 교사별 또는 주제별 수업 사례들이 왜 과학을 가르치는 좋은 실천으로 간주되며, 실천의 어떤 측면이 그 수업을 다른 수업과 차별화하며 권장될 만한 것인지를 분석하였다. 즉, 근저 이론(grounded theory)의 연구 방법을 활용하였다. 분석대상으로 한 수업은 중학교 1학년 빛 단원에 해당하는 수업들로, 세명의 과학교사들이 진행한 같은 주제의 차시별 수업을 교차분석하여 과학과 PCK의 유형을 추출하였다. 본 연구에서 도출된 과학과 PCK 유형을 (1) 교육과정을 재구성하는 수업, (2) 주변 자연현상에 대한 학생 나름의 설명 모델을 만들어나가는 수업, (3) 과학이라는 사회적 언어 학습이 일어나는 수업, (4) 연계성을 기초로 학습동기를 유발하는 수업, (5) 스캐폴딩을 제공하여 학습 수요를 낮추는 수업, (6) 학생 이해에서 출발하는 수업, (7) 논증을 통한 탐구가 있는 수업, (8) 추상적인 과학개념을 구체화하는 수업, (9) 소외되는 학생이 없는 과학 수업으로 분류하였다. 각 PCK 유형에 따라 교사 전문성의 특징을 고찰하고, 높은 수준의 PCK를 지닌 교사들이 공유하는 특징을 결론으로 도출하였다.