ABSTRACT
Civil construction has increasingly invested in techniques for quality assurance and control. Service inspection is a key activity in the quality control process and executed by specialized professionals in order to register the quality of services. Through these inspections, it is possible to detect faults during construction. To get an overview of the approaches/techniques of information systems that have been used to support the inspection activity, a systematic mapping of the literature has been done. The literature mapping indicates the use of information systems to collect inspection data, mainly using technologies such as laser scanner, augmented reality, internal positioning and forms. Some works also use previous construction models, generated using BIM and 3D CAD models,to aid the inspection activity. Result analysis indicates that there are signs of immaturity within there search area, and it is recommended that existing systems are complemented with inspection issues tracking and quality control history features.
- Gabriel Luiz Fritz Benachio, Maria do Carmo Duarte Freitas, and Sergio Scheer. 2019. Tecnologias emergentes para o controle de qualidade da construção civil. In II Simpósio Brasileiro de Tecnologia de Informação e Comunicação na Construção, Vol. 2. ANTAC, Porto Alegre, 1–6.Google Scholar
- Letícia Ramos Berr and Carlos Torres Formoso. 2012. Método para avaliação da qualidade de processos construtivos em empreendimentos habitacionais de interesse social. Ambiente Construído 12, 2 (2012), 77–96.Google Scholar
- Ankit Bhatla, Soo Young Choe, Oscar Fierro, and Fernanda Leite. 2012. Evaluation of accuracy of as-built 3D modeling from photos taken by handheld digital cameras. Automation in construction 28 (2012), 116–127.Google Scholar
- Chen Binjin, Yao Shouyan, Yu Xin, Jiang Qichen, and Li Xin. 2018. A Novel Construction Quality Control and Management Method Based on BIM and 3D Laser Scanning Technology. In 2018 International Conference on 3D Immersion (IC3D). IEEE, 1–8.Google ScholarCross Ref
- Frédéric Bosché and Emeline Guenet. 2014. Automating surface flatness control using terrestrial laser scanning and building information models. Automation in construction 44 (2014), 212–226.Google Scholar
- David Budgen, Mark Turner, Pearl Brereton, and Barbara A Kitchenham. 2008. Using Mapping Studies in Software Engineering.. In PPIG, Vol. 8. 195–204.Google Scholar
- Jeferson Spiering Böes, Jeferson Ost Patzlaff, and Marco Aurélio Stumpf González. 2016. Estudo sobre a gestão da informação no controle de qualidade de obras uma análise da aplicabilidade da TIC. In Anais do ENTAC (16 ed.). 4710–4721.Google Scholar
- Marly Carvalho and Edson Paladini. 2012. Gestão da qualidade: teoria e casos. Elsevier Brasil.Google Scholar
- Airton Cattani. 2003. Utilização de recursos da tecnologia da informação para qualificação de trabalhadores da construção civil em leitura e interpretação de plantas. Ambiente Construído 3, 1 (2003), 83–92.Google Scholar
- Elodie Chambonnière, Jacqueline Vacherand-Revel, and Bruno Andrieu. 2018. Transição digital na construção civil: analisar a atividade de levantamento de inconformidades mediada por um aplicativo informático de uma diretora de obra. Laboreal 14, 2 (2018), 45–61.Google ScholarCross Ref
- Fengchen Chen, Huanjing Jiao, Liming Han, Liwei Shen, Wenjia Du, Qing Ye, and Guozhu Yu. 2020. Real-time monitoring of construction quality for gravel piles based on Internet of Things. Automation in Construction 116 (2020), 103228.Google ScholarCross Ref
- LiJuan Chen and Hanbin Luo. 2014. A BIM-based construction quality management model and its applications. Automation in construction 46 (2014), 64–73.Google Scholar
- Yuping Cheng, Yan Chen, Ran Wei, and Hanbin Luo. 2015. Development of a Construction Quality Supervision Collaboration System based on a SaaS private cloud. Journal of Intelligent & Robotic Systems 79, 3-4 (2015), 613–627.Google ScholarDigital Library
- Hung-Lin Chi, Jun Wang, Xiangyu Wang, Martijn Truijens, and Ping Yung. 2015. A conceptual framework of quality-assured fabrication, delivery and installation processes for liquefied natural gas (LNG) plant construction. Journal of Intelligent & Robotic Systems 79, 3-4 (2015), 433–448.Google ScholarDigital Library
- Chu Chu, Hailu Yang, and Linbing Wang. 2019. Design of a pavement scanning system based on structured light of interference fringe. Measurement 145(2019), 410–418.Google ScholarCross Ref
- Giovani Cecatto Lopes Ribeiro da Costa, Sílvia Haueisen Figueiredo, and Sidnea Eliane Campos Ribeiro. 2015. Estudo comparativo da tecnologia CAD com a tecnologia BIM. Revista de Ensino de Engenharia 34, 2 (2015), 11–18.Google ScholarCross Ref
- Eloisa Dezen-Kempter, Lúcio Soibelman, Meida Chen, and Alexandre Victor Müller Filho. 2015. Escaneamento 3D a laser, fotogrametria e modelagem da informação da construção para gestão e operação de edificações históricas. Gestão & Tecnologia de Projetos 10, 2 (2015), 113–124.Google ScholarCross Ref
- Lieyun Ding, Kaiman Li, Ying Zhou, and Peter ED Love. 2017. An IFC-inspection process model for infrastructure projects: Enabling real-time quality monitoring and control. Automation in Construction 84 (2017), 96–110.Google ScholarCross Ref
- Jeferson Böes e Jeferson Patzlaff. 2016. Tecnologia da Informação e Comunicação (TIC) aplicada ao controle de qualidade de obras – estudo de caso. Revista de Arquitetura IMED 5, 1 (2016), 75–92. https://doi.org/10.18256/2318-1109/arqimed.v5n1p75-92Google ScholarCross Ref
- Chuck Eastman, Paul Teicholz, Rafael Sacks, and Kathleen Liston. 2014. Manual de BIM: um guia de modelagem da informação da construção para arquitetos, engenheiros, gerentes, construtores e incorporadores. Bookman Editora.Google Scholar
- Ching-Lung Fan. 2020. Defect Risk Assessment Using a Hybrid Machine Learning Method. Journal of Construction Engineering and Management 146, 9(2020), 04020102.Google ScholarCross Ref
- Nicolas Jeanclos, Mohammad-Mahdi Sharif, Shang Kun Li, Caroline Kwiatek, and Carl Haas. 2018. Derivation of Minimum Required Model for Augmented Reality Based Stepwise Construction Assembly Control. In Workshop of the European Group for Intelligent Computing in Engineering. Springer, 336–358.Google Scholar
- Vamsi Sai Kalasapudi, Pingbo Tang, and Yelda Turkan. 2017. Computationally efficient change analysis of piece-wise cylindrical building elements for proactive project control. Automation in Construction 81 (2017), 300–312.Google ScholarCross Ref
- T Sri Kalyan, Puyan A Zadeh, Sheryl Staub-French, and Thomas M Froese. 2016. Construction quality assessment using 3D as-built models generated with Project Tango. Procedia Engineering 145(2016), 1416–1423.Google ScholarCross Ref
- Staffs Keele 2007. Guidelines for performing systematic literature reviews in software engineering. Technical Report. Technical report, Ver. 2.3 EBSE Technical Report. EBSE.Google Scholar
- Cláudio Kirner and Romero Tori. 2006. Fundamentos de realidade aumentada. Fundamentos e Tecnologia de Realidade Virtual e Aumentada 1 (2006), 22–38.Google Scholar
- Cibeli Ferrando Leão, Eduardo Luis Isatto, and Carlos Torres Formoso. 2016. Proposta de modelo para controle integrado da produção e da qualidade com apoio da computação móvel. Ambiente Construído 16, 4 (2016), 109–124.Google Scholar
- Mina Lee, Seongki Lee, Soonwook Kwon, and Sangyoon Chin. 2017. A study on scan data matching for reverse engineering of pipes in plant construction. KSCE Journal of Civil Engineering 21, 6 (2017), 2027–2036.Google ScholarCross Ref
- Marco Lee, Yu-Ren Wang, and Chung-Fah Huang. 2019. Design and development of a friendly user interface for building construction traceability system. Microsystem Technologies(2019), 1–13.Google Scholar
- Chien-Liang Lin and Ching-Lung Fan. 2018. Examining association between construction inspection grades and critical defects using data mining and fuzzy logic. Journal of Civil Engineering and Management 24, 4 (2018), 301–317.Google ScholarCross Ref
- Junying Lou, Jiang Xu, and Kun Wang. 2017. Study on construction quality control of urban complex project based on BIM. Procedia engineering 174(2017), 668–676.Google Scholar
- Zhiliang Ma, Shiyao Cai, Na Mao, Qiliang Yang, Junguo Feng, and Pengyi Wang. 2018. Construction quality management based on a collaborative system using BIM and indoor positioning. Automation in Construction 92 (2018), 35–45.Google ScholarCross Ref
- Leonardo Ribeiro Machado, Francisco J da Silva, Alex Barradas, Davi Viana, Ariel Teles, and Luciano Coutinho. 2020. Product Quality for Smart Cities Applications: A Mapping Study. In XVI Brazilian Symposium on Information Systems. 1–8.Google Scholar
- Mohammad Nahangi and Carl T Haas. 2014. Automated 3D compliance checking in pipe spool fabrication. Advanced Engineering Informatics 28, 4 (2014), 360–369.Google ScholarDigital Library
- Zhiguo Pan, Yihong Zhou, Chunju Zhao, Chao Hu, Huawei Zhou, and Yong Fan. 2019. Assessment Method of Slope Excavation Quality based on Point Cloud Data. KSCE Journal of Civil Engineering 23, 3 (2019), 935–946.Google ScholarCross Ref
- Carla dos Santos de Oliveira Passos, Larissa da Silva Paes Cardoso Cardoso, and Herman Augusto Lepikson. 2018. Estudo Exploratório Das Tecnologias De Controle Da Qualidade na Construção Civil, Automatizadas e Integradas Ao BIM. In Anais do IV SIINTEC & VIII PTI(1 ed.).Google Scholar
- Kai Petersen, Sairam Vakkalanka, and Ludwik Kuzniarz. 2015. Guidelines for conducting systematic mapping studies in software engineering: An update. Information and Software Technology 64 (2015), 1–18.Google ScholarDigital Library
- Da Sheng, Lieyun Ding, Botao Zhong, Peter ED Love, Hanbin Luo, and Jiageng Chen. 2020. Construction quality information management with blockchains. Automation in Construction 120 (2020), 103373.Google ScholarCross Ref
- Polina Sherstobitova, Marina Petrochenko, Sergej Nasypajko, Inna Prohorova, Romero Marcelo de Andrade, and Margarita Matskina. 2019. Monolithic Constructions Quality Assessment with Laser Scanning. In International Scientific Conference on Energy, Environmental and Construction Engineering. Springer, 705–713.Google Scholar
- Roberto de Souza and Geraldo Mekbekian. 1996. Qualidade na aquisição de materiais e execução de obras. Pini.Google Scholar
- Patricia Tavares, Simone Bacellar Leal Ferreira, Luiz Agner, and Eliane Pinheiro Capra. 2014. A Influência de Ambientes de Uso Adversos na Coleta de Dados Estatísticos Utilizando Dispositivos Móveis. iSys-Brazilian Journal of Information Systems 7, 1 (2014), 66–88.Google Scholar
- Ercio Thomaz. 2001. Tecnologia, gerenciamento e qualidade na construção. Pini.Google Scholar
- Stefan Wagner. 2013. Software product quality control. (2013).Google Scholar
- Jun Wang, Weizhuo Sun, Wenchi Shou, Xiangyu Wang, Changzhi Wu, Heap-Yih Chong, Yan Liu, and Cenfei Sun. 2015. Integrating BIM and LiDAR for real-time construction quality control. Journal of Intelligent & Robotic Systems 79, 3-4 (2015), 417–432.Google ScholarDigital Library
- Jie Xu, Lieyun Ding, Hanbin Luo, Elton J Chen, and Linchun Wei. 2019. Near real-time circular tunnel shield segment assembly quality inspection using point cloud data: A case study. Tunnelling and Underground Space Technology 91 (2019), 102998.Google ScholarCross Ref
- Qinwu Xu and George K Chang. 2016. Adaptive quality control and acceptance of pavement material density for intelligent road construction. Automation in Construction 62 (2016), 78–88.Google ScholarCross Ref
- Zhao Xu, Ting Huang, Bingjing Li, Heng Li, and Qiming Li. 2018. Developing an IFC-based database for construction quality evaluation. Advances in Civil Engineering 2018 (2018).Google Scholar
- Walid Yazigi. 2009. A técnica de edificar(10 ed.). Pini/SindusCon-SP, São Paulo.Google Scholar
- Tan Yiqiu, Wang Haipeng, Ma Shaojun, and Xu Huining. 2014. Quality control of asphalt pavement compaction using fibre Bragg grating sensing technology. Construction and Building Materials 54 (2014), 53–59.Google ScholarCross Ref
- Cheng Zhang, Vamsi Sai Kalasapudi, and Pingbo Tang. 2016. Rapid data quality oriented laser scan planning for dynamic construction environments. Advanced Engineering Informatics 30, 2 (2016), 218–232.Google ScholarDigital Library
- Denghua Zhong, Xiaochao Li, Bo Cui, Binping Wu, and Yuxi Liu. 2018. Technology and application of real-time compaction quality monitoring for earth-rockfill dam construction in deep narrow valley. Automation in Construction 90 (2018), 23–38.Google ScholarCross Ref
Index Terms
- Information System applied in Construction Quality Control: A Mapping Study
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