• Kyungpook Mathematical Journal
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• 제26권1호
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• pp.67-72
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• 1986

• 품질경영학회지
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• 제50권4호
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• pp.793-810
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• 2022

Purpose: As improving the search performance of aviation security equipment is considered essential, this study proposes the need for research on how to find an optimized test sequence that can reduce test time and operator power during the search function test of explosive detection systems. We derive the weights and work difficulty adjustment factor required to find the optimized test order. Methods: First, after setting the test factors, the time of each test and the difficulty scale determined by the worker who performed the test directly were used to derive weights. Second, the work difficulty adjustment coefficient was determined by combining the basic weight adjustment factor and corresponding to the body part used by the test using objective rating. Then the final standard time was derived by calculating the additional weights for the changeability of the test factors. Results: The order in which the final standard time is minimized when 50 tests are performed was defined as the optimized order. 50 tests should be conducted without duplication and the optimal order of tests was obtained when compared to previously numbered tests. As a result of minimizing the total standard time by using Excel's solver parameters, it was reduced by 379.14 seconds, about 6.32 minutes. Conclusion: We tried to express it in mathematical formulas to propose a method for setting an optimized test sequence even when testing is performed on other aviation security equipment. As a result, the optimal test order was derived from the operator's point of view, and it was demonstrated by minimizing the total standard time.

• Nuclear Engineering and Technology
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• 제54권10호
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• pp.3620-3630
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• 2022

The diagnosis of abnormalities in a nuclear power plant is essential to maintain power plant safety. When an abnormal event occurs, the operator diagnoses the event and selects the appropriate abnormal operating procedures and sub-procedures to implement the necessary measures. To support this, abnormality diagnosis systems using data-driven methods such as artificial neural networks and convolutional neural networks have been developed. However, data-driven models cannot always guarantee an accurate diagnosis because they cannot simulate all possible abnormal events. Therefore, abnormality diagnosis systems should be able to detect their own potential misdiagnosis. This paper proposes a rulebased diagnostic validation algorithm using a previously developed two-stage diagnosis model in abnormal situations. We analyzed the diagnostic results of the sub-procedure stage when the first diagnostic results were inaccurate and derived a rule to filter the inconsistent sub-procedure diagnostic results, which may be inaccurate diagnoses. In a case study, two abnormality diagnosis models were built using gated recurrent units and long short-term memory cells, and consistency checks on the diagnostic results from both models were performed to detect any inconsistencies. Based on this, a re-diagnosis was performed to select the label of the second-best value in the first diagnosis, after which the diagnosis accuracy increased. That is, the model proposed in this study made it possible to detect diagnostic failures by the developed consistency check of the sub-procedure diagnostic results. The consistency check process has the advantage that the operator can review the results and increase the diagnosis success rate by performing additional re-diagnoses. The developed model is expected to have increased applicability as an operator support system in terms of selecting the appropriate AOPs and sub-procedures with re-diagnosis, thereby further increasing abnormal event diagnostic accuracy.

• Bulletin of the Korean Chemical Society
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• 제28권10호
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• pp.1705-1708
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• 2007

Geometric manipulation of molecules is an essential elementary component in computational modeling programs for molecular structure, stability, dynamics, and design. The computational complexity of transformation of internal coordinates to Cartesian coordinates was discussed before.1 The use of rotation matrices was found to be slightly more efficient than that of quaternion although quaternion operators have been widely advertised for rotational operations, especially in molecular dynamics simulations of liquids where the orientation is a dynamical variable.2 The discussion on computational efficiency is extended here to a more general case in which bond angles and sidechain torsion angles are allowed to vary. The algorithm of Thompson3 is derived again in terms of quaternions as well as rotation matrices, and an algorithm with optimal efficiency is described. The algorithm based on rotation matrices is again found to be slightly more efficient than that based on quaternions.

• ETRI Journal
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• 제40권1호
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• pp.51-60
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• 2018

In Long Term Evolution (LTE) cellular networks, the transmit power control (TPC) mechanism consists of two parts: the open loop (OL) and closed loop. Most cellular networks consider OL/TPC because of its simple implementation and low operation cost. The analysis of OL/TPC parameters is essential for efficient resource management from the cellular operator's viewpoint. In this work, the impact of the OL/TPC parameters is investigated for homogeneous small cells and heterogeneous small-cell/macrocell network environments. A mathematical model is derived to compute the transmit power at the user equipment, the received power at the eNodeB, the interference in the network, and the received signal-to-interference ratio. Using the analytical platform, the effects of the OL/TPC parameters on the system performance in LTE networks are investigated. Numerical results show that, in order to achieve the best performance, it is appropriate to choose ${\alpha}_{small}=1$ and $P_{o-small}=-100dBm$ in a homogenous small-cell network. Further, the selections of ${\alpha}_{small}=1$ and $P_{o-small}=-100dBm$ in the small cells and ${\alpha}_{macro}=0.8$ and $P_{o-macro}=-100dBm$ in the macrocells seem to be suitable for heterogeneous network deployment.

• 직업교육연구
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• 제35권4호
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• pp.131-153
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• 2016

NCS의 성공은 직업능력개발훈련 기관인증평가자의 역할과 역량에 달려 있다. 이 연구는 NCS기반 직업능력개발훈련 기관인증을 위한 평가자의 역할과 역량을 도출하는 데 목적이 있다. 델파이 기법을 적용하여 평가자의 구체적 역할을 다각적으로 탐색하고, 필요한 지식과 기술, 태도 그리고 특성을 도출하여 그 타당성을 검증하고자 하였다. 이를 위해 교육훈련 전문가와 심사평가 전문가를 패널로 선정하여 3차에 걸친 델파이 연구를 진행하였다. 연구 결과, 평가자의 역할은 총 8개로 운영자, 조정 중재자, 협력자, 분석가, 검증가, 기관평가자, 기관컨설턴트, 학습자로 분류되었고, 각 역할에 따른 역량은 총 25개로 도출되었다. 지식 영역은 HRD 지식, NCS 지식, 직업능력개발훈련 지식, 훈련기관인증평가 지식의 총 4개의 역량이 포함되었다. 기술 영역은 갈등관리 능력, 대인관계 능력, 문서작성 능력, 문제해결 능력, 분석 능력, 사전준비 능력, 시간관리 능력, 의사결정 능력, 정보이해 활용 능력, 종합적사고 능력, 직업훈련기관에 대한 이해 능력, 커뮤니케이션 능력, 피드백 능력, 핵심파악 능력의 총 14개의 역량으로 구성되었다. 태도영역은 객관성 및 공정성, 서비스 마인드, 소명의식, 윤리의식, 자기개발, 책임감, 팀워크의 총 7개로 정리됐다. 이 연구의 결과로 도출된 역할과 역량은 평가자가 일정한 요건을 갖추어 공정하고 체계적으로 인증평가할 수 있도록 평가자 대상 교육프로그램을 설계하고 운영하는 데 유용할 것이다. 특히, 평가자의 경험과 역할에 따라 기초교육 및 향상 교육을 실시할 수 있도록 역량별 교육 프로그램을 모듈별로 설계하고, 지속적으로 평가자의 품질을 관리하는 데 기초자료로 활용될 것으로 기대된다.