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      KCI등재

      사물인터넷 기반 건설 프로젝트 성과측정원형 개발

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      다국어 초록 (Multilingual Abstract) kakao i 다국어 번역

      Conventional progress control technique which collects and manages construction progress data manually is involved in inaccurate and omitted information in construction phase. It is time consuming and labor intensive to acquire the construction operation data in detail. It is important to develop the system that analyzes the project performance accurately and control the progress efficiently by keeping track of the progress data at a lower level than the operation. This paper proposes a system prototype which measures project progress at the construction operation level by hybridizing remote-controlled robots (i.e., air-drone and wheel mounted vehicle), smart sensors, and project scheduling and controlling tool. The system is developed into an Internet of Thing(IoT)-based progress measurement system. using robot and information technology. Earned value method-based physical progress measurement method is utilized to compute the quantity of work completed. A test case was performed to confirm that the new system complements the limitation of existing progress control method.
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      Conventional progress control technique which collects and manages construction progress data manually is involved in inaccurate and omitted information in construction phase. It is time consuming and labor intensive to acquire the construction operat...

      Conventional progress control technique which collects and manages construction progress data manually is involved in inaccurate and omitted information in construction phase. It is time consuming and labor intensive to acquire the construction operation data in detail. It is important to develop the system that analyzes the project performance accurately and control the progress efficiently by keeping track of the progress data at a lower level than the operation. This paper proposes a system prototype which measures project progress at the construction operation level by hybridizing remote-controlled robots (i.e., air-drone and wheel mounted vehicle), smart sensors, and project scheduling and controlling tool. The system is developed into an Internet of Thing(IoT)-based progress measurement system. using robot and information technology. Earned value method-based physical progress measurement method is utilized to compute the quantity of work completed. A test case was performed to confirm that the new system complements the limitation of existing progress control method.

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      목차 (Table of Contents)

      • Abstract
      • 1. 서론
      • 2. 선행연구 고찰
      • 3. 건설 프로젝트 성과측정 자동화
      • 4. 사물인터넷기반 건설프로젝트 성과측정시스템
      • Abstract
      • 1. 서론
      • 2. 선행연구 고찰
      • 3. 건설 프로젝트 성과측정 자동화
      • 4. 사물인터넷기반 건설프로젝트 성과측정시스템
      • 5. 시스템 유효성 검증
      • 6. 결론
      • REFERENCES
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      참고문헌 (Reference)

      1 López, J., "WatchBot: A building maintenance and surveillance system based on autonomous robots" 61 (61): 1559-1571, 2013

      2 Briones, L., "Wall-climbing robot for inspection in nuclear power plants" IEEE 1409-1414, 1994

      3 Caldas, C. H., "Using global positioning system to improve materials-locating processes on industrial projects" 132 (132): 741-749, 2006

      4 Ashton, K., "That ‘internet of things’ thing" 22 : 97-114, 2009

      5 Davidson, I. N., "Simulation of automated data collection in buildings" 9 (9): 9-20, 1995

      6 DeVault, J. E., "Robotic system for underwater inspection of bridge piers" IEEE 3 (3): 32-37, 2000

      7 Huston, D., "Robotic and mobile sensor systems for structural health monitoring" 1517 : 2003

      8 Lee, D., "Research of IoT in industrial site" 12 (12): 29-34, 2014

      9 Navon, R., "Research in automated measurement of project performance indicators" 16 (16): 176-188, 2007

      10 Saidi, K. S., "Report of the NIST workshop on data exchange standards at the construction job site" 617-622, 2003

      1 López, J., "WatchBot: A building maintenance and surveillance system based on autonomous robots" 61 (61): 1559-1571, 2013

      2 Briones, L., "Wall-climbing robot for inspection in nuclear power plants" IEEE 1409-1414, 1994

      3 Caldas, C. H., "Using global positioning system to improve materials-locating processes on industrial projects" 132 (132): 741-749, 2006

      4 Ashton, K., "That ‘internet of things’ thing" 22 : 97-114, 2009

      5 Davidson, I. N., "Simulation of automated data collection in buildings" 9 (9): 9-20, 1995

      6 DeVault, J. E., "Robotic system for underwater inspection of bridge piers" IEEE 3 (3): 32-37, 2000

      7 Huston, D., "Robotic and mobile sensor systems for structural health monitoring" 1517 : 2003

      8 Lee, D., "Research of IoT in industrial site" 12 (12): 29-34, 2014

      9 Navon, R., "Research in automated measurement of project performance indicators" 16 (16): 176-188, 2007

      10 Saidi, K. S., "Report of the NIST workshop on data exchange standards at the construction job site" 617-622, 2003

      11 Ko, C. H., "RFID-based building maintenance system" 18 (18): 275-284, 2009

      12 Poirier, C. C., "RFID strategic implementation and ROI: a practical roadmap to success" J. Ross Publishing 2006

      13 Halpin, D. W., "Planning and Analysis of Construction Operation" John Wiley and Sons Inc. 1992

      14 Cheung, S. O., "PPMS: a web-based construction project performance monitoring system" 13 (13): 361-376, 2004

      15 Abdel Aziz, A. M., "Minimum performance bounds for evaluating contractors performance during construction of highway pavement projects" 26 (26): 507-529, 2008

      16 Eldin, N. N., "Measurement of work progress:Quantitative technique" 115 (115): 462-474, 1989

      17 Howes, N. R., "Managing software development projects for maximum productivity" 1 : 27-35, 1984

      18 Jung, Y., "Knowledge-based standard progress measurement for integrated cost and schedule performance control" 133 (133): 10-21, 2007

      19 Sacks, R., "Interpretation of automatically monitored lifting equipment data for project control" 20 (20): 111-120, 2006

      20 El-Omari, S., "Integrating automated data acquisition technologies for progress reporting of construction projects" 20 (20): 699-705, 2011

      21 Björk, B. C., "Information Technology in Construction–domain definition and research issues" 1 (1): 3-16, 1999

      22 Love, P. E., "Industry-centric benchmarking of information technology benefits, costs and risks for small-to-medium sized enterprises in construction" 13 (13): 507-524, 2004

      23 Lee, B., "Improvement of calculating method of Construction progress and completed amount measurement" Construction Economy Research Institute of Korea 1-59, 1996

      24 Hwang, B. G., "Identifying the critical factors affecting schedule performance of public housing projects" 38 : 214-221, 2013

      25 Peyret, F., "High-precision application of GPS in the field of real-time equipment positioning" 9 (9): 299-314, 2000

      26 Schempf, H., "Grislee: Gasmain repair and inspection system for live entry environments" 22 (22): 603-616, 2003

      27 Finch, E. F., "Electronic document management in construction using auto-ID" 5 (5): 313-321, 1996

      28 Fleming, Q. W., "Earned value project management" Project Mangement Institute 1996

      29 Lin, Y. C., "Developing mobile 2D barcode/RFID-based maintenance management system" 37 : 110-121, 2014

      30 Xu, F., "Design and experiments on a new wheel-based cable climbing robot" IEEE 418-423, 2008

      31 Latham, M., "Constructing the team: joint review of procurement and contractual arrangements in the United Kingdom construction industry" 1994

      32 Sacks, R., "Building project model support for automated labor monitoring" 17 (17): 19-27, 2003

      33 Oh, J. K., "Bridge inspection robot system with machine vision" 18 (18): 929-941, 2009

      34 Bernold, L. E., "Bar code-driven equipment and materials tracking for construction" 4 (4): 381-395, 1990

      35 Bosche, F., "Automated retrieval of 3D CAD model objects in construction range images" 17 (17): 499-512, 2008

      36 Navon, R., "Automated project performance control of construction projects" 14 (14): 467-476, 2005

      37 Turkan, Y., "Automated progress tracking using 4D schedule and 3D sensing technologies" 22 : 414-421, 2012

      38 Wakisaka, T., "Automated construction system for high-rise reinforced concrete buildings" 9 (9): 229-250, 2000

      39 Kim, C., "Automated construction progress measurement using a 4D building information model and 3D data" 31 : 75-82, 2013

      40 Clark, F., "Applied cost engineering" CRC Press 1996

      41 Abdelsayed, M., "An information sharing, Internet-based, system for project control" 16 (16): 211-233, 1999

      42 Love, P. E., "An exploratory study of information technology evaluation and benefits management practices of SMEs in the construction industry" 42 (42): 227-242, 2004

      43 Thomas, H. R., "An analysis of the methods for measuring construction productivity" Construction Industry Institute, University of Texas at Austin 1986

      44 Yoon, S., "A progress measurement method based on characteristics of work types" Graduate school of Sungkyunkwan University 2003

      45 La Rosa, G., "A low-cost lightweight climbing robot for the inspection of vertical surfaces" 12 (12): 71-96, 2002

      46 Ghanem, A. G., "A framework for real-time construction project progress tracking" 188 (188): 2006

      47 Navon, R., "A concept proving prototype of automated earthmoving control" 13 (13): 225-239, 2004

      48 Metni, N., "A UAV for bridge inspection: Visual servoing control law with orientation limits" 17 (17): 3-10, 2007

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      공동연구자 (7)

      유사연구자 (20) 활용도상위20명

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      학술지 이력

      학술지 이력
      연월일 이력구분 이력상세 등재구분
      2022 평가 계속평가 신청대상 (등재유지)
      2017-01-01 등재 우수등재학술지 선정 (계속평가)
      2013-01-01 등재 등재학술지 유지 (등재유지) KCI등재
      2011-03-25 학술지명변경 한글명 : 대한건축학회 논문집(구조계) -> 대한건축학회논문집 구조계
      외국어명 : Journal of the Architectural Institute of Korea(Structure & Construction) -> Journal of the Architectural Institute of Korea Structure & Construction
      KCI등재
      2010-01-01 등재 등재학술지 유지 (등재유지) KCI등재
      2008-01-01 등재 등재학술지 유지 (등재유지) KCI등재
      2006-01-01 등재 등재학술지 유지 (등재유지) KCI등재
      2004-01-01 등재 등재학술지 유지 (등재유지) KCI등재
      2001-07-01 등재 등재학술지 선정 (등재후보2차) KCI등재
      1999-01-01 등재 등재후보학술지 선정 (신규평가) KCI등재후보
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      학술지 인용정보

      학술지 인용정보
      기준연도 WOS-KCI 통합IF(2년) KCIF(2년) KCIF(3년)
      2016 0.35 0.35 0.33
      KCIF(4년) KCIF(5년) 중심성지수(3년) 즉시성지수
      0.29 0.27 0.614 0.04
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