• 인터넷정보학회논문지
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• 제20권4호
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• pp.81-90
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• 2019

정부는 2015년부터 소프트웨어 중심대학 지원 사업을 통하여 미래 인재에 요구되는 소프트웨어 역량 강화에 힘쓰고 있다. 소프트웨어 중심대학으로 선정된 대학에서는 각기 다른 전공지식과 소프트웨어 소양을 겸비한 융합형 인재 양성을 위하여 대학 내 인문, 사회, 공학, 자연과학, 예체능 등 모든 계열에 소프트웨어 기초교육을 실시하고 있다. 본 논문에서는 20개 소프트웨어 중심대학에서 실시하고 있는 비전공자 대상의 소프트웨어 기초교육의 내용을 분석하였다. 분석 결과, 비전공자 학생들에게 실시하고 있는 소프트웨어 기초교육의 대부분은 미래사회에 필요한 컴퓨팅 사고력 중심의 문제해결력 향상과 컴퓨터과학에 기반을 둔 융합 능력 향상 목적으로 실시하고 있었다. 전공별 특성을 반영한 교육 내용과 프로그래밍의 난이도 조정을 위해 블록 기반 교육용 프로그래밍 언어와 텍스트 기반 고급 프로그래밍 언어를 활용하고 있다. 문제해결을 위한 교수 학습 방법으로는 문제 중심 학습(Problem based Learning), 프로젝트 중심 학습(Project Based Learning)과 토의 토론법을 많이 사용하고 있는 것으로 분석되었다. 향 후 이 논문이 비전공자 소프트웨어 기초교육의 체계적 방향 설정에 도움이 되었으면 한다.

• 디지털융복합연구
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• 제15권9호
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• pp.55-64
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• 2017

소프트웨어의 중요성이 널리 인지됨에 따라 대학에서도 소프트웨어 교육이 필수 교과로 지정되어 운영되고 있다. 하지만 비전공 학습자에 대한 충분한 이해가 없는 상태에서 교육이 이루어져, 교육 목표 달성에 어려움이 있다. 따라서 본 논문에서는 소프트웨어 기초 교육 과정을 수강한 인문대학생들의 의견을 분석하여 학생들의 디지털 마인드 변화를 확인하고, 이를 바탕으로 비전공 학생 대상 소프트웨어 기초 교육의 고려 사항을 제안한다. 설문 분석 결과, 입학 전 소프트웨어 교육은 대학에서의 교육에 기여하는 바는 크지 않은 반면, 학생들은 자신이 친숙함을 느끼는 주제를 활용한 실습 위주의 교육에 긍정적인 응답을 보였다. 따라서 비전공 학습자를 대상으로 한 소프트웨어 기초 교육에서는 학습자에게 실습을 바탕으로 한, 보다 많은 소프트웨어 접근 기회를 제공함으로써 학습자 스스로 자연스럽게 디지털 마인드를 함양할 수 있는 환경을 제공하는 것이 바람직하다.

• 한국정보시스템학회지:정보시스템연구
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• 제28권4호
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• pp.403-424
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• 2019

Purpose The objective of this study is to determine the programming language for improving algorithmic thinking of basic software education for non-majors, which has recently been receiving attention to nurture talents needed in the era of the Fourth Industrial Revolution. Design/methodology/approach In this study, Delphi method was used to select the suitable programming language for the features of each of five departments for basic software education for non-majors in order to develop the capability of algorithmic thinking. The survey was conducted three times to 21 experts, and the results were analyzed using quantitative analysis (CVR) values and stability. Findings For the most suitable programming language for each department determined in this study, App Inventor was selected for humanities department, RUR-PLE for natural science department, App Inventor for social science department, Python for engineering department, and Scratch for fine arts department. This is expected to be used as the basis for determining the direction of curriculum and operation of universities starting basic software education through programming language by department proposed in this study.

• 통합자연과학논문집
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• 제14권4호
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• pp.176-182
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• 2021

We live in the age of artificial intelligence, and big data and artificial intelligence education are no longer just for majors, but are required to be able to handle non-majors as well. Software and artificial intelligence education for non-majors is not just a general education, it creates talents who can understand and utilize them, and the quality of education is increasingly important. Through such education, we can nurture creative talents who can create and use new values by fusion with various fields of computing technology. Since 2015, many universities have been implementing software-oriented colleges and AI-oriented colleges to foster software-oriented human resources. However, it is not easy to provide AI basic statistics education of big data analysis deception to non-majors. Therefore, we would like to present a big data education model for non-majors in big data analysis so that big data analysis can be directly applied.

• 한국컴퓨터정보학회:학술대회논문집
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• 한국컴퓨터정보학회 2008년도 제39차 동계학술발표논문집 16권2호
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• pp.485-492
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• 2009

The purpose of this study is to allow all of the instructors including field instructors to understand relation between school education and computer, generalize and analyze basic data required to acquire basic knowledge to help utilizing the computer for education and seek for understanding. This study intented to present a method to activate computer education focused on utilization education at the elementary education stage. Accordingly, those computer educations on middle/high schools and universities and through social educations have been excluded from the object of the study. In order to conduct fruitful computer education, several supporting systems should be equipped completely such as teachers, facilities, software, etc. Especially, practical experience of using computer is the most important element in the computer education, every school should be equipped with computers to prepare for its generalization. Roles of the teachers have also very important influence on it. Research and development of education software require expert knowledge and enormous time and effort and the developed software should be followed by the systematic evaluation on its quality.

• 정보교육학회논문지
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• 제23권4호
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• pp.329-341
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• 2019

대학에서의 컴퓨터교육은 과거 ICT 활용 중심의 교육에서 최근에는 컴퓨팅적사고 및 프로그래밍 등의 소프트웨어 교육으로 그 내용이 확장되고 전문화되고 있다. 특히 4차 산업혁명이 사회 전 분야에 강조되면서 그 핵심인 소프트웨어 교육이 대학에서 필수적 교양수업으로 도입되는 추세이다. 전교생을 대상으로 하는 기초SW교육을 실시하는 경우 학생들의 전공계열의 특성이 다르기 때문에 그에 적합한 세분화된 교육을 제공할 필요가 있다. 본 연구에서는 서울소재 A대학에서 교양필수 기초SW과목을 운영하고, 약 3년간 수강생 4,927명으로부터 얻은 설문데이터를 분석하여 전공계열을 세분화하고 각 세분화된 그룹에 적합한 교육방식을 탐색하였다. 분석을 통하여 경상계열, 예체능계열, 자유전공 등의 특징있는 그룹들을 발견할 수 있었다. 최종적으로 6개의 세분화된 기초SW교육을 위한 그룹을 제시하였으며, 각 그룹별로 교육에 적합한 프로그래밍 언어 및 난이도 설정 등의 교육방향을 제시하였다.

• 한국컴퓨터정보학회논문지
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• 제24권9호
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• pp.151-160
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• 2019

With the advent of the Fourth Industrial Revolution, software(SW) education has become a necessity, not a choice of those who live in the digital age. Recently, many countries around the world have been actively promoting software education based on Computational Thinking(CT) for K-12 students, so software education in schools has bigger meaning as basic literacy education of future digital generation rather than coding skills. However, the integration of software education as a formal curriculum in schools is still ongoing in even other countries. Korea is also pursuing software education, but it is in the beginning stage. Therefore, we need to study the cases of other countries that have already started software education at the national level. In this paper, we first investigate the software education cases of three countries, e.g., UK, France and China with a respect of background & educational objective, development stage, and curriculum and we suggest education policies that software education can settle in Korea schools to foster a creative talented people.

• 산경연구논집
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• 제10권11호
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• pp.71-80
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• 2019

Purpose: The purpose of this study is to design the curriculum of Basic College Software Programming to develop creative and logical-thinking. This course is guided by algorithmic thinking and logical thinking that can be solved by computing for problem-solving, and it helps to develop by software through basic programming education. Through the stage of problem analysis, abstraction, algorithm, data structure, and algorithm implementation, the curriculum is designed to help learners experience algorithm problem-solving in various areas to develop diffusion thinking. For Learners aim to achieve the balanced development of divergent and convergent-thinking needed in their creative problem-solving skills. Research design, data and methodology: This study is to design a basic software education for improving algorithm-thinking for non-major. The curriculum designed in this paper is necessary to non-majors students who have completed the 'Creative Thinking and Coding Course' Design Thinking based are targeted. For this, contents were extracted through advanced research analysis at home and abroad, and experts in computer education, computer engineering, SW education, and education were surveyed in the form of quasi-openness. Results: In this study, based on ADD Thinking's algorithm thinking, we divided the unit college majors into five groups so that students of each major could accomplish the goal of "the ability to internalize their own ideas into computing," and extracted and designed different content areas, content elements and sub-components from each group. Through three expert surveys, we established a strategy for characterization by demand analysis and major/textbook category and verified the appropriateness of the design direction to ensure that the subjects and contents of the curriculum are appropriate for each family in order to improve algorithm-thinking. Conclusions: This study helps develop software by enhancing the ability of students who practice various subjects and exercises to explore creative expressions in various areas, such as 'how to think like a computer' that can implement and execute their ideas in computing. And it helps increase the ability to think logical and algorithmic computing based on creative solutions, improving problem-solving ability based on computing thinking and fundamental understanding of computer coding and development of logical thinking ability through programming.

• 한국컴퓨터정보학회논문지
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• 제24권1호
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• pp.239-246
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• 2019

In this paper, we propose an effective software education donation model for the social care class. The types of software education for elementary, middle, and high school for the social care class are in the order of after school classes, club activities, creative experiences, and regular classes. In elementary school students, it is effective to precede visual programming education based on block coding and to conduct curriculum convergence with SW and HW at the beginning, and high school students are carrying out text programming education like Python. Software education for social care class The contribution activity model can be classified into five types such as geographically difficult area, multicultural family areas, orphanage, reformatory, and basic livelihood security recipient. In addition, the survey results show that the students' interest in software education and their satisfaction are all very high at 96%. Effective software education for the social care class In the donation model, the lecturers consist of responsible professors, lecturers, and assistant instructors. Software training for the social care class is effective on a year-by-year basis, so that students can feel authenticity and trust. Software education contents focus on visual programming and physical computing education in elementary or middle school, and text programming and physical computing education in high school. It is necessary to construct a software education donor matching system that helps efficient management of software education donations by efficiently matching schools (consumers: elementary, middle, high school) and software education donors(suppliers).

• 정보교육학회논문지
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• 제25권3호
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• pp.449-457
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• 2021

교육부는 최근 2025년부터 초중고에 인공지능교육을 도입한다고 발표하였고 언론에서는 인공지능교육 도입에 대한 우려를 나타내는 기사들을 내보내고 있다. 본 연구에서는 초등학교에서 실제 인공지능교육을 담당할 교사를 대상으로 인공지능교육 도입에 대한 인식을 분석하는데 주안점을 두고 소프트웨어와 관련된 학습경험이 많은 교사와 학습경험이 적은 교사로 구분하여 조사하였다. 분석결과, 학습경험이 많은 교사는 인공지능교육 도입에 100% 찬성의 입장을 나타내었고 학습경험이 적은 교사는 80%가 긍정적 의사를 나타내었다. 학습경험이 적은 교사의 20%가 반대하는 원인 중에는 현재의 실과 교과에 포함된 소프트웨어 단원으로도 충분하다가 높은 비율로 나타났다. 학습경험이 많은 교사와 학습경험이 적은 교사 모두 적절한 교육시기로 5-6학년을 가장 많이 선택했고 교육시수는 주당 1시간을 가장 적절한 시수로 보았다. 교과 구성 형식은 학습경험이 많은 교사의 75%가 소프트웨어교육을 독립교과로 하고 그 안에 인공지능교육을 포함시키는 방안을 선택하였고 학습경험이 적은 교사의 54%가 인공지능교육을 독립교과로 하거나 소프트웨어교육을 독립교과로 하고 인공지능교육을 그 안에 포함시키는 방안을 선택하였다. 교육내용의 선호도는 인공지능 프로그래밍 기초, 인공지능 개념 원리, 인공지능 윤리 순으로 나타났다.