• Journal of The Korean Association of Information Education
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• v.18 no.3
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• pp.443-452
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• 2014

In this study, robot curriculum was developed to fulfill systematic robot education in elementary and middle schools. For literature research, robot curriculum cases in the UK, the US, and Korea were surveyed to choose and organize robot education contents. The robot curriculum developed is categorized into five areas-robot basic course, sensor, structure/motion, control, and problem-solving-and consist of four step-robot experience, robot creation, robot exploration, and robot control. Stepwise learning contents reflected difficulty and sequence to let students experience intensive repetitive activity. This study will lay the foundation for applying systematic robot education to elementary and middle school students. In the future, it is expected to study the development and application of various programs on the basis of the developed robot curriculum.

• Journal of Digital Contents Society
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• v.14 no.3
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• pp.333-341
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• 2013

Robot education has the favorable influence on creativity and problem-solving ability of students. Therefore, it is commonly known to elementary school students, their parents and teacher through robot education for after school and contests. However, it has not been actively taught at university of education students because of the lack of systematic education program. In this paper, we have developed robot education program using problem-based learning and educational robot for pre-service elementary teachers. We have examined their recognition on robot education and education program after applying the developed program. Interviews for improving robot education program were also conducted. We find out robot education program has the favorable influence on the recognition, satisfaction and effectiveness for robot education. In particular, we know that education will related to robot was augmented by this education program.

• Journal of The Korean Association of Information Education
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• v.19 no.4
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• pp.481-488
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• 2015

Lately, the importance of robot education is rising in elementary schools, because of STAEM education. In this study, robot and convergence activity curriculum in software education was developed to robot education for elementary school. We suggested robot education framework based on the Rainbow system, which is repeatable and progressive. The framework is divided into 7 steps, 14 criteria. So, their students can be promoted to the higher level when they complete the lower level, regardless of their grade. It is necessary for robot education in elementary schools to develop the contents and programs according to suggested curriculum.

• Journal of Gifted/Talented Education
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• v.19 no.3
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• pp.669-695
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• 2009

In the 21st century, there will be a robot revolution. Only several years ago, industrial robots were the mainstream in the robot market; however, diverse type of robots are currently entering into our daily lives for various purposes, and the robot that thinks and behaves very similarly to human will appear in the near future. However, there is a critical view about the robot period. This means that the robot revolution will change even the framework of our entire society and human life style, and it is necessary to have robot education. It is necessary to start robot education in the elementary school curriculum with a view to enhancing interest in basic science and scientific technology and cultivating creative talents who may adapt themselves to a robotic society. However, there is no systematic robot curriculum owing to insufficient perception of the need of robot education and the educational utilization of robots. Under these circumstances, robot education is largely dependent on education for students with special talents and aptitudes run by private organizations. This paper conducted the following research in order to develop a robot curriculum in education for the gifted elementary students of computer science. First, the paper identified problems by analyzing the robot curriculum from a micro perspective after selecting three organizations that are relatively well perceived out of private organizations that operate robot education for the gifted elementary students of computer science. Second, the paper developed a robot curriculum in education for the gifted elementary students of computer science based on the framework of a robot curriculum run by private sector. Third, the validity of the robot curriculum developed in this paper was verified by a professional group comprising mainly persons in charge of robot curriculum development at private sector and lecturers for robot education for the gifted elementary students of computer science.

• Journal of Korean society of Dental Hygiene
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• v.18 no.5
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• pp.729-740
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• 2018

Objectives: The purpose of this study was to investigate the factors affecting robot utilization in the education of pre-dental hygienists. Methods: A self-reported questionnaire was completed by 238 dental hygiene students studying in the Daejeon, Chungcheong, and Jeolla provinces during the period March 1-31, 2017. Results: Future oral health education media had high selection of 'movies,' 'video,' '3D printer,' 'robot,' and 'drone' In general education and oral health education, robots were appropriate as educators, assistant teachers, and media. This group had high levels of interest, experience, attitude, and learning scope of robots. Robot utilization education showed a significant positive correlation with the 'interest,' 'experience,' 'attitude,' and 'learning' subfactors (p<0.01). Factors influencing robot utilization education were the relationships among actual experience of robot, learning of robot production, social influence of robot, emotional exchange with robot, and the predictive power was 25.5% (p<0.05). Conclusions: Oral health education curricula using robots should be developed considering the emotional exchange and social influence between educator and learner.

• Journal of The Korean Association of Information Education
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• v.22 no.3
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• pp.335-344
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• 2018

In this study, we examine the effects of SW education using robot on flow in elementary school. In order to achieve the purpose of this study, SW education using robot was conducted to 155 students. In addition, we examined mean difference using matched pair t-test and ANCOVA. Our results show that SW education using robot significantly improved flow. Further, flow was not associated with gender. This study was investigated effects of the SW education using robot and identify differences depending on gender, and expanded the understanding of the SW education using robot.

• Journal of The Korean Association of Information Education
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• v.22 no.3
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• pp.307-316
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• 2018

In this study, we conduct SW education using robot in elementary school, to examine the effects of SW education using robot and identify differences dependeing on the presence of assistance teacher. In order to achieve the purpose of this study, SW education using robot was conducted to 29 students. After collecting data, we examined mean difference using matched pair t-test and ANCOVA. Our results show that SW education using robot significantly improved CT and attitudes toward robots. CT, however, was not significantly improved in control group. Further, although improvement in attitudes toward robots was not associated with presence of assistance teacher, presence of assistance teacher did play a role in improvement of CT. This study was investigated effects of the SW education using robot and identify differences depending on the presence of assistant teacher, and expanded the understanding of the SW education using robot.

• Journal of The Korean Association of Information Education
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• v.24 no.1
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• pp.99-106
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• 2020

In this paper, we analyzed the units related to robot education in the Practical Arts textbooks according to the 2015 revised curriculum. As a result, all textbooks had a common system of introduction, development, and organization, and all of them showed a similar flow. Learning objectives were presented in all textbooks, but no affective goals were presented except cognitive and functional goals. The contents of robot learning suggest the meaning and type of robots, the structure and sensors of robots, and the activities of making robots, but the contents of robot ethics, the production and activities of various robot works, and the use of robots in the problem solving process are not presented. The assembly robot and the infrared sensor are used in common, and it consists of presenting robot production and control training materials in experience activities and arranging units through evaluation, and the A, C, and F textbooks also provide the unit auxiliary data. In the future, it will be necessary to include the contents of robot ethics education centered on the design/manufacturer and user-oriented robot ethics such as the recognition of the limits of robots, the principles of using robots correctly, safety education, personal information and privacy protection.

• Journal of The Korean Association of Information Education
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• v.14 no.2
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• pp.209-218
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• 2010

Robot Curriculum based education in Insects Robot help elementary school students better understand how a robot works. This robot curriculum is aimed at elementary school students in fifth grade. This study progressed with LEGO(R) MINDSTORMS(R) NXT, departed 6 groups, reached the insect's movement, designed robot like insects. This curriculum enhanced discussion prowess and improved the ability of building robot. During this study, most of the students were attracted to the action of the robot-like insect's movement.

• Journal of Practical Engineering Education
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• v.6 no.2
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• pp.85-89
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• 2014

A variety of robot education comes out. However, robot associated with the image processing is insufficient. And it is difficult to various education through a robot. Image processing educational robot that is proposed is made by module type hardware, so it's convenient to assemble according to educational purposes with the robot. In image processing, the robot recognizes color and pattern and calculates angle and control four motors. Using the robot, you can learn image processing, how to use MCU and Encoder, related programs and motor control.