• 한국진공학회:학술대회논문집
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• 한국진공학회 2005년도 제29회 학술발표회 초록집
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• pp.74-74
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• 2005

• 한국자기학회:학술대회 개요집
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• 한국자기학회 2008년도 Asian Magnetics Conference
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• pp.264.1-264.1
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• 2008

• 공학교육연구
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• 제17권6호
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• pp.12-19
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• 2014

Failure is an important part of engineering practice. Engineers utilize all of their competences and resources in order for their products or processes to meet the initial intention and purpose, and not to fail. However, the technological products sometimes end up with failure. The failure, in many cases, is related to non-technological factors or systems, not just limited to technological factors. Moreover, the evaluation of failure is performed by a variety of agents, including consumers, civic groups, government as well as professional groups. Thus, this study raises an issue that the existing concept of failure, which focuses on the operation of function, is not sufficient enough to properly cover the success or failure of technology required by the modern society. In the recent trends of engineering, new concepts and methods have been developed by expanding the traditional concept or introducing a new perspective of failure, so that engineering failure can be better understood in the mutual relationship between technology and society. This research attempts to suggest a methodology of how the failure of engineering can be utilized and properly combined in the major education, design education and engineering ethics education. Also, it aims to contribute to the quality improvement of engineering education to train engineers who can lead the society with responsibility as well as professional competence.

• 공학교육연구
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• 제16권6호
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• pp.38-44
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• 2013

This study has the purpose to identify the correlation of engineering education major college students' technological problem solving tendency between technological problem solving capability. To that end, the technological problem solving tendencies of 79 students enrolled in engineering education related department in college of education, 'C' University located in Daejeon metropolitan city were examined, and the correlation of technological problem solving tendency between technological problem solving capability was analyzed through measurement of technological problem solving capability. As for the correlation among problem solving confidence a sub-element of technological problem solving tendency and technological problem solving capability, positive correlation was found in result 3, result 4 and result average. As for the correlation among approach-avoidance tendency a sub-element of technological problem solving tendency and technological problem solving capability, positive correlation was found in result 5 and result average. As for the correlation among self-control recognition degree the sub-element of technological problem solving tendency and technological problem solving capability, positive correlation was found in result 1, result 3 and result average. As for the correlation among problem solving tendency and technological problem solving capability, positive correlation was found in result 3, result 4, result 5 and result average.

• 공학교육연구
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• 제26권5호
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• pp.17-28
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• 2023

Generative AI has arrived and it's here. Education, research, industry, and labor are all on edge about the changes it will bring. It is noteworthy that while there is a wide range of optimistic and pessimistic predictions about the impact of generative AI, there is more concern than hope when it comes to education. This paper focuses on the lack of discussion on the impact of AI in higher education. First, we reviewed the process of the emergence of generative AI and introduced how the impact of AI is being understood from various perspectives. Second, we classified work areas based on expertise and efficiency and analyzed the impact of AI on work in each area. Finally, the study found that the educational perception of generative AI and the way it is perceived for engineering education purposes can be very different. It also argued that there is a lack of active discussion and debate on areas that need to be specifically discussed around generative AI. This has led to a phenomenon known as professors' delayed indifference. We emphasized that it is time for a serious and realistic discussion on the connection and integration of AI and education.

• 공학교육연구
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• 제20권3호
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• pp.32-41
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• 2017

The $4^{th}$ industrial revolution refers to an era where machines capable of outperforming humans are created. In light of the 4th industrial revolution, university students are demanded problem solving abilities, critical thinking abilities, and problem discovering abilities as general and basic abilities. The need for changes in the university level communication education for engineering students remains imperative in this constantly changing social environment. The era where education is conducted only in classrooms is over. This paper discusses the need for diversified education such as the integration of online and offline education, the reinforcement of learning outside of the classroom as well as an education model that transcends formal and informal education such as games and activities that induce self-learning, both intentional and non-intentional learning, and the utilization of mass media and social networking systems. Through providing an education model that assesses and utilizes the data gained from the learning process provided above, this paper widens the perception of future education methods in the 4th industrial revolution.

• 수산해양교육연구
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• 제24권2호
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• pp.346-354
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• 2012

In this paper, we argue that for general education in engineering, humanistic education is important, thus we propose an illustration of course outline. Recent general education for engineering is focused on only more practical, socially oriented courses, for example, business, law, economics, and entrepreneurship. While these courses are helpful for engineering students, humanistic education is more fundamental for improving the students' capacity for insight, originality and constructing the holistic view. We propose a course "Philosophy of Time and Space" as an example which fit this purpose.

• 공학교육연구
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• 제15권3호
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• pp.59-65
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• 2012

The skill that meets the intellectual and technical requirements in workplace is called hard skill. The counter part of it is 'softskills' which enhances an individual's interactions, job performance and career prospects. It becomes more necessary skill as society changes. In this paper we first show the demand for the softskill improvement education for engineering major students. Then we introduce a 'softskill improvement education' program developed by the "Center for innovative engineering education" in a University. The contents of the program are chosen by the needs of society, companies that hire our students, ABEEK educational objectives and consulting from professors. To improve the skills we used various activities as tools which are mentioned and introduced. The evaluation of the program results are discussed. We suggest some ways to improve the program.

• 공학교육연구
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• 제14권4호
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• pp.83-87
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• 2011

In this paper, the present state of the experiments in the mechanical engineering education is analyzed and the improving methods of the experimental education are presented. Data at twelve universities are collected. In spite of the general understanding of the importance of the experiments, the portion of the experiments is less than 10%. It shows the need to increase the experiments. Experiments for basic mechanics are fairly well performed, but experiments for applied subjects would be strengthened. Several improving methods such as systematic support for experiments, use of the exclusive assistants for experiments, and so on are discussed.

• 공학교육연구
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• 제24권2호
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• pp.61-67
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• 2021

The creative problem-solving becomes one of the most important cognitive skills in the engineering education. As AI and automation technology(of 4th Industrial Revolution) penetrate our everyday life, its role as a human ability is highlighted. In this paper, we examine the relation between the creative problem-solving and the critical thinking, and the usefulness of the latter in the engineering education. To sum up, the critical thinking is the pre-conditon of the creative problem-solving.