• School Mathematics
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• v.7 no.2
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• pp.193-219
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• 2005

This study looked into the procedures of and the status on the implementation of the new mathematics curriculum at the secondary school level(7th through 10th grades). This study examined schools and the teachers were subjects for the actual implementation of the mathematics classroom. More specifically it examined the degree to which the particular innovation ideas of the 7th mathematics curriculum(i.e., reorganization , student-centeredness, diversification/specialization) were being carried out at every stage of the curriculum implementation. Nationwide survey for teachers including students were conducted along with classroom observation and teacher interviews. For an in-depth study into the process and the product of mathematics curriculum implementation, two provincial boards of education participated in the project as research partners. Detailed documentation on the classroom practices were made in order to provide schools and teachers including policy makers with relevant and practical suggestions for further improvement of mathematics curriculum implementation. It was found that mathematics teachers generally were reconstructing the contents giving the priority to the needs of the learners. The concept of learner-centered-ness was reflected in teaching objectives, contents, instructional methods and evaluation. In most schools observed, emphasis was given to the reorganization of the curriculum contents fitting to the concept of 'student-centered' curriculum. The efforts by teachers to diversity and/or specialize the curriculum contents with consideration of various educational conditions such as student readiness, student abilities, classroom equipment and facilities, school locations and environment were found.

• The Journal of Korean Association of Computer Education
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• v.12 no.2
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• pp.1-12
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• 2009

The number of college-oriented students in vocational high schools is increasing every year. For this reason, it is necessary to revise the curriculum of vocational schools, so that it is properly connected to college level education. In this paper, we try to find problems in computer curriculum by analyzing computer related courses currently taught by information computer departments in commerce information high schools. Based on the findings, we propose a desirable computer curriculum for commercial information high schools. We include the contents of each course, and suggest the way to administer the proposed curriculum in three year course of study.

• Journal for History of Mathematics
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• v.17 no.2
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• pp.53-60
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• 2004

This paper is aimed at studying a meaning of 7-th curriculum in high school mathematics and improvement direction in relation to entrance examinations.

• Journal of Educational Research in Mathematics
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• v.25 no.3
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• pp.449-460
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• 2015

As a main body of a curriculum, a set of sentences stating mathematical contents plays an important role in teaching and learning mathematics. The contents sentences in the $7^{th}$ version, the 2007 version, and the 2009 version of elementary mathematics curricula were analysed. The elementary mathematics curriculum consists of about 200 contents sentences. The final endings of those sentences are the type of ability such as "to be able to ~". The elementary mathematics curriculum would be managed systematically by disassembling and restructuring those contents sentences. We should state students' activities more concretely by varying the final endings in the curriculum.

• Journal of the Korean Data and Information Science Society
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• v.22 no.6
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• pp.1097-1103
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• 2011

The Ministry of Education Science, and Technology proclamated the school curriculum of the republic of Korea at 9 August 2011. The characteristics of this curriculum are as follows; effective learning of student-centered, group of grade, group of category, concentration study, reduction of study subjects, extension of school autonomy, elective curriculum in high school. We investigate the modification of probability and statistics curriculum. And we discuss statistics education in university.

• Proceedings of the Korean Society for Information Management Conference
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• 2002.11a
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• pp.7-20
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• 2002

학교도서관은 그 어느 때보다도 높은 관심 속에서 발전하고 있다. 그림에도 불구하고 학교도서관을 운영할 사서교사의 배치는 난관에 부딪혀 있다. 이에 본고에서는 도서관의 고유한 역할인 참고봉사의 기능을 학교 교육과 연계시켜 한가지 해결책을 제시한다. 도서관 업무의 꽃이라고 하는 참고봉사는 기본 2대 기능이 정보와 교육에 있다. 이중에서 교육 기능의 측면에서 어떻게 사서교사를 학교도서관에 배치할 수 있는가하는 점에 초점을 두고 이 논문을 전개한다. 또 본고에서는 국내외 정보이용 교육과정, 초ㆍ중등학교 정보와 도서관 교육과정의 구성과 기반 이론, 향후 현장 학교도서관과 학계에 미칠 교과교육학의 영향, 정보와 도서관 교육과정의 정책 방향 등에 대해 제시하였다.

• Journal of vocational education research
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• v.36 no.4
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• pp.57-78
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• 2017

This study aimed to make proposals to develop an apprenticeship program and organize the apprenticeship curriculum by conducting an overall analysis of how vocational education and training high schools participating in the apprenticeship system(apprenticeship schools) organized the apprenticeship program in the school curriculum. To that end, the study analyzed the current state of the apprenticeship curriculum of 33 apprenticeship schools and came up with the following results: First, the apprenticeship class and the general class had a similar relevance between 'departments' and 'areas and goals of student training' and between 'departments' and 'qualifications,' while the apprenticeship class had a higher relevance between 'areas and goals of student training' and 'qualifications' than the general class. Second, both the required and optional competency units of the apprenticeship program were relatively evenly included in the Off-JT and OJT. Third, the competency units of the apprentice program were included in the technical subjects of the 2009 revised curriculum as well as the NCS practical subjects of the 2015 revised curriculum. Fourth, although most of the competency units of the apprenticeship program have a high correlation with the technical subjects of the school curriculum, there were also many schools showing a low correlation. Fifth, although the hierarchy of organizing the competency units of the apprenticeship program by semester was mostly high, there were a considerable number of schools with a low hierarchy. As a result, this study made the following policy proposals: granting a grace period for approval of the changes in the curriculum of the apprenticeship, distributing the matching table before and after the revision of the NCS competency units, organizing subjects not included in the national curriculum, creating subjects specialized for companies, and monitoring and consulting the curriculum of the apprenticeship schools.

• Journal of the Korean earth science society
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• v.25 no.7
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• pp.576-585
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• 2004

This study was conducted to analyze the relationships between terms, learning concepts and inquiries in ocean unit, the National Common Basic Curriculum. The several science textbooks were selected to use for study, written in accordance with the 7 current national curriculum for the fourth grade of elementary school, the seventh of middle school and the tenth of high school. The higher the school level becomes, the frequencies of using terms related with ocean region get. The explanation of terms, however, has a tendency to be less frequent in the high school level. In the perspective of learning concept, there are more concrete concepts than formal concepts regardless of school level. Pure scientific context appears most often in inquiry contest through the whole course of every school level. In respect to inquiry process, the frequency of integrative inquiry process is on the increase as the school level gets higher. From the viewpoint of inquiry activity, there have been a lot of discussions, experiments and investigations in every school level, while high school does not the present any field study and project. Through these result, it is considered that the explanation of main terms is inevitable in the textbooks as basic educational material without regard to school level. In learning concept and inquiry context, a well-rounded learning is needed in relation to students' cognitive development and science-technology-society. Especially for the inquiry activity of earth science education, the educational effect is remarkable through field study; its appropriate application is required, accordingly.

• Journal of the Korea Society of Computer and Information
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• v.28 no.1
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• pp.201-208
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• 2023

As the demand for AI education increases, AI education is actively conducted in the educational field, but it is difficult to internalize AI education due to securing time, difficulty in organizing class contents, and lack of curriculum. As a way to solve this problem, there is a school autonomous course. The school autonomous course allows schools to have autonomy and discretion throughout the curriculum, such as adjusting the number of hours in the subject group and restructuring the use of achievement standards. In this study, in order to enhance AI education, the effect was analyzed by developing and applying an AI education immersion course using a school autonomous curriculum. In the AI education immersion course, students continuously experience AI education in a dense manner within a limited time, so substantial AI education can be achieved. After the AI curriculum, it was found that students' overall AI literacy and self-determination learning motivation improved. It is expected that this study will be able to present a direction to internalize AI education using school autonomous curriculum.

• Journal of the Korean School Mathematics Society
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• v.17 no.4
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• pp.613-627
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• 2014

Elementary textbook ${\ll}Mathematics\;4-2{\gg}$ first published in 2014 according to the 2009 elementary mathematics curriculum has been dealing with concave polygons which were not treated in elementary textbooks according to the previous curriculum. However, n the present paper, to show that there is a need to reconsider the handling of the concave polygons, after discussions about the polygon, problems in handling the concave polygons were discussed in next two viewpoints: Does 2009 elementary mathematics curriculum allow handling of the concave polygons? are there any logical leaps in handling of the concave polygon? And the following reasons to reconsider the handling of the concave polygons are presented as conclusions. First, there was no process of publicizing the handling of the concave polygon. Second, the evidences that will justify the handling of the concave polygon can not be found in 2009 elementary mathematics curriculum. Third, there are logical leaps in the handling of the concave polygons. Fourth, there is no consistency in handling the concave polygons.