• Korean Architects
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• s.568
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• pp.120-125
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• 2016

오랜만에 지난 작업들을 뒤돌아 볼 기회가 생겼습니다. 누구에게나 인생의 큰 흐름에 영향을 미치는 사건이 일어나기 마련인데요, 저의 경우는 지난 근 십년간 함께 해온 파라메트릭 디자인을 접하게 된 일이 그러한 사건들 중 하나였다고 생각이 됩니다. 그런 의미에서 트레이싱지 위에 로트링펜으로 선을 처음 그었던 그 강렬했던 기억 이후로 건축 설계를 해오면서 가장 기억에 남는 한 사건을 꼽으려고 한다면 단연히 Cornell 건축 대학원 재학 당시 처음 접하게 되었던 GenerativeComponents 수업을 이야기 하고 싶습니다. 연재를 시작하면서 잠시 언급한 바가 있었던 것 같은데요, 파라메트릭 디자인이라는 미지의 영역을 알게 해준 것이 바로 Bentley 사에서 만든 GenerativeComponents 라는 파라메트릭 디자인 툴 입니다. Microstation은 Autocad와 함께 건축설계 시장에서 많은 사용자층을 확보 하였던 캐드 툴 중 하나 이었으며 자체적으로 BIM 및 파라메트릭 툴을 위한 패키지가 Rhino의 Grasshopper의 출현 이전부터 존재하여 왔을 정도로 발전된 자동화 설계 플랫폼이었습니다. 현재도 특정 건축사사무소들이 Microstation을 꾸준히 사용하고 있으며 특히 Infra structure, plant나 civil engineering 등의 건축 외 설계 분야에서는 여전히 폭넓은 사용자층을 확보하고 있습니다. 하지만 건축 시장에서는 Rhino를 바탕으로 하는 플러그인 패키지 및 Autodesk의 건축설계 통합 패키지 등에 밀려서 사용자층이 얇아진 편입니다.

• Smart Media Journal
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• v.13 no.2
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• pp.145-155
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• 2024

As the importance of software and artificial education is emphasized on the digital transformation era, various educational materials are being developed and distributed. To achieve the purpose of software education, various software education programs suitable for school settings need to be provided. In this paper, we developed a software education program using self-driving that can be applied to secondary school software education and applied it to secondary school students. The developed software education program is a physical computing program consisting of various motion control programs such as object detection, line tracing using various sensors, focusing on experience and practice. As a result of the survey, students' attitudes and career orientation toward software and artificial intelligence, and satisfaction with software education were over 90%, and satisfaction with the proposed program was over 95%.

• Economic and Environmental Geology
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• v.54 no.2
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• pp.233-245
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• 2021

Many studies on the microstructures in rocks have been conducted using experimental methods with various equipment as well as natural rock studies to see the development of microstructures and understand their mechanisms. Grain boundary migration of mineral aggregates in rocks could cause grain growth or grain size changes during metamorphism or deformation as one of the main recrystallization mechanisms. This study suggests improved ways regarding the analog material experiments with reformed equipment to see sequential observations of these grain boundary migration. It can be more efficient than the existing techniques and carry out an appropriate microstructure analysis. This reformed equipment was implemented to enable optical manipulation by mounting polarizing plates capable of rotating operation on a stereoscopic microscope and a deformation rig capable of experimenting with analog materials. The equipment can automatically control the temperature and strain rate of the deformation rig by microcontrollers and programming and can take digital photomicrographs with constant time intervals during the experiment to observe any microstructure changes. The composite images synthesized using images by rotated polarizing plates enable us to see more accurate grain boundaries. As a rock analog material, norcamphor(C7H10O) was used, which has similar birefringence to quartz. Static grain growth and simple shear deformation experiments were performed using the norcamphor to verify the effectiveness of the equipment. The static grain growth experiments showed the characteristics of typical grain growth behavior. The number of grains decreases and the average grain size increases over time. These case experiments also showed a clear difference between the growth curves with three temperature conditions. The result of the simple shear deformation experiment under the medium temperature-low strain rate showed no significant change in the average grain size but presented the increased elongation of grain shapes in the direction of about 53° regarding the direction perpendicular to the shearing direction as the shear strain increases over time. These microstructures are interpreted as both the plastic deformation and the internal recovery process in grains are balanced by the deformation under the given experimental conditions. These experiments using the reformed equipment represent the ability to sequentially observe changing the microstructure during experiments as desired in the tests with the analog material during the entire process.