Dam is a structure with high beneficial values and these include, serving as the source of raw water supply and electrical energy, ensuring flood reduction, tourist attractions, and habitat protection. It is, however, associated with a very complex development process ranging from the planning/design, construction, as well as operation and maintenance. Therefore, there is a need for special attention, accuracy, and good coordination at every stage from the parties involved as well as the integration of all fields starting from the Architecture, Engineering, and Construction (AEC) elements. Moreover, ensuring an effective and efficient construction process presents a serious challenge for the owner/government, designers, consultants and contractors which is now being resolved through the use of a technological innovation known as the Building Information Modeling (BIM).

This study was conducted to determine the scientific developments of BIM for dam management and also to identify further related areas to be researched in the future. Moreover, the analysis was concentrated on the potential added value of the technological innovations on dams, explained its advantages, and assesses the potential challenges hampering its effectiveness in Indonesia. It was discovered that the use of BIM for dam projects is possible as long as there are adequate government regulations and the availability of qualified human resources while the consequence would be an increase in the investment cost. The findings of this research are expected to encourage the use of BIM in dam construction and management in Indonesia and also to increase efficiency and effectiveness in all aspects.

Autodesk, 2019. What is BIM? [Online] Available at: https://www.autodesk.com/solutions/bim

Azhar, S., 2011. Building Information Modeling (BIM): Trends, Benefits, Risks, and Challenges for the AEC Industry. Leadership and Management in Engineering, 11(3), pp. 241–252.

Azhar, S., Khalfan, M., & Maqsood, T., 2012. Building information modeling (BIM): Now and beyond. Australasian Journal of Construction Economics and Building, 12(4), pp. 15–28. https://doi.org/10.5130/ajceb.v12i4.3032

Becerik-Gerber, B., Jazizadeh, F., Li, N., & Calis, G.. 2012. Application areas and data requirements for BIM-enabled facilities management. Journal of Construction Engineering and Management, 138(3), pp. 431–442.

BIM Ministry of Public Works and Housing, 2019a. Bina Marga Bersiap BIM Mandatory 2020. [Online] Available at: http://bim.pu.go.id/berita/baca/34/bina-marga-bersiap-bim-mandatory-2020.html [Accesed 15 September 2019]

BIM Ministry of Public Works and Housing, 2019b. Implementasi BIM di Indonesia Untuk Proyek Bangunan Gedung. [Online] Available at: http://bim.pu.go.id/berita/baca/42/implementasi-bim-di-indonesia-untuk-proyek-bangunan-gedung.html [Accessed 15 September 2019]

Bryde, D., Broquetas, M., & Volm, J. M., 2014. The project benefits of Building Information Modelling (BIM). International Journal of Project Management, 31(7), pp. 971–980.

Coetzee, G. L., 2018. Smart Construction Monitoring of Dams with UAVS - Neckartal dam Water Project Phase 1. Swansea, Smart Dams and Reservoirs - Proceedings of the 20th Biennial Conference of the British Dam Society.

CRC Construction Innovation, 2007. Adopting BIM for facilities management: Solutions for managing the Sydney Opera House. CRC for construction Innovation participants. Brisbane, Australia: Cooperative Research Center for Construction Innovation.

Diaz, P., 2016. Analysis of Benefits, Advantages and Challenges of Building Information Modelling in Construction Industry. Journal of Advances in Civil Engineering, 2(2), pp. 1–11.

Directorate General of Human Settlements, 2018. Kebijakan dan Roadmap Penerapan Building Information Modeling (BIM) Mendukung Konstruksi Digital Indonesia, Semarang.

Eadie, R., Browne, M., Odeyinka, H., McKeown, C., & McNiff, S., 2013. BIM implementation throughout the UK construction project lifecycle: An analysis. Automation in Construction, 36, pp. 145–151.

Fanning, B., Clevenger, C., Ozbek, M., & Mahmoud, H., 2014. Implementing BIM on Infrastructure: Comparison of Two Bridge Construction Projects. Practice Periodical on Structural Design and Construction, 20, pp. 4014044.

Hidayah, D. N., Latief, Y., & Riantini, L. S., 2018. Development of work breakdown structure standard based on risk for safety planning on dam construction work. IOP Conference Series: Materials Science and Engineering, 420(1).

Jiao, Y., Zhang, S., Li, Y., Wang, Y., & Yang, B., 2013. Towards cloud Augmented Reality for construction application by BIM and SNS integration. Automation in Construction, 33, pp. 37–47.

Ju, K. B., & Seo, M. B., 2012. A Study on the Issue Analysis for the Application of BIM Technology to Civil Engineering in Korea. Creative Education, 3(7), pp. 21–24.

Kacprzyk, Z., & Kępa, T., 2014. Building information modelling-4D Modelling technology on the example of the reconstruction stairwell. Procedia Engineering, 91(TFoCE), pp. 226–231.

Kivits, R. A., & Furneaux, C., 2013. BIM: Enabling sustainability and asset management through knowledge management. The Scientific World Journal, 2013(5).

Matt, B, 2013. Model-based Design Powers China Dam Construction, West Allis : Informed Infrastructure.

McArthur, J. J., 2015) A Building Information Management (BIM) Framework and Supporting Case Study for Existing Building Operations, Maintenance and Sustainability. Procedia Engineering, 118, pp. 1104–1111.

McGraw Hill Construction, 2014. The Business Value of BIM for Owners. SmartMarket Report. (Harvey M. Bernstein, Ed.), Bedford.

Ministry of Public Works and Housing, 2017. BIM Roadmap Indonesia. [Online] Available at: http://bim.pu.go.id/assets/files/ROADMAP_KONSTRUKSI_DIGITAL_INDONESIA_140917.pdf

Mulyono, J., 2017. Konsepsi Keamanan Bendungan dalam Pembangunan dan Pengelolaan Bendungan. Jurnal Infrastruktur, 3(01), pp. 62–69.

Paul, S, 2018. BIM adoption around the world: how good are we? [Online] Available at: https://www.geospatialworld.net/article/bim-adoption-around-the-world-how-good-are-we/

Ratajczak, J., Marcher, C., Schimanski, C. P., Schweikopfler, A., Riedl, M., & Matt, D. T., 2019. BIM-based augmented reality tool for the monitoring of construction performance and progress. Chania, Proceedings of the 2019 European Conference for Computing in Construction.

Rozy, N., 2015. Pengaruh Jenis dan Susunan Armada Alat Berat Pekerjaan Tanah Terhadap Optimasi Biaya dan Waktu. Jurnal Logika, XIII(1), pp. 96–206.

Russell, S., & Jackson, T., 2014. Construction of a pre-cast concrete service reservoir using BIM. Belfast, Maintaining the Safety of Our Dams and Reservoirs - Proceedings of the 18th Biennial Conference of the British Dam Society.

Schurer, J., Wilkinson, E., Norfleet, J., Sciver, J. Van, Huntington, C., Lee, C., & Rogers, A., 2002. Dam Safety Manual (3th ed.). Colorado: Members of the Colorado Division of Water Resources.

Succar, B., 2009. Building information modelling framework: A research and delivery foundation for industry stakeholders. Automation in Construction, 18(3), pp. 357–375.

U.S. Department of Homeland Security., 2007. Dams Sector Security Awareness Handbook.

Wang, K. C., Wang, S. H., Kung, C. J., Weng, S. W., & Wang, W. C., 2018. Applying BIM and visualization techniques to support construction quality management for soil and water conservation construction projects. Berlin, ISARC 2018 - 35th International Symposium on Automation and Robotics in Construction and International AEC/FM Hackathon: The Future of Building Things, (Isarc).

World Commission on Dams (WCD)., 2001. Dam-building decisions. Environmental Health Perspective, 109(2), pp. 81–83.