Sergey Bolotin, Haitham Bohan, Aldyn-kys Dadar, Khenzig Biche-ool


Introduction: Planning integrated development of a residential area involves determining the composition of the objects to be built and creating an appropriate integration mechanism, backed up by a generalized work schedule. The existing methods of forming integrated work schedules do not use a systemic approach, based on a universal mathematical model, to describe the organizational and technological aspects of construction. Methods: The present study uses the method of uncertain resource coefficients to demonstrate a mechanism for systemically describing organizational and technological construction processes. We present a way of adapting this method to forming a generalized construction schedule during integrated development. The proposed adaptation mechanism is based on managing schedule calculations by rationally influencing the elements of the linear equation system that describes the organizational and technological processes. Results and Discussion: The solutions presented in the paper are fully consistent with the calculations obtained by different flow methods of organizing construction, as well as with the critical path method used in project management programs. The method described in the paper has been implemented in well-known project management software, Microsoft Project, as a macro program in the Visual Basic for Applications programming language, making it possible to form, calculate, and optimize a schedule for integrated territory development using the unified software toolkit.


Calendar construction scheduling, organizational and technological construction plan, temporal collisions of calendar schedules, admissible work scheduling, project management software.

Full Text:



Afanasyev, V. А. (1990). Construction workflow. Moscow: Stroyizdat, 302 p.

Babenko, S. V. (2013). Problems and prospects of implementing complex development concept in capital cities of Russia. Journal of Legal and Economic Studies, No. 2, pp. 137–140.

Bolotin, S. А., Biche-ool, Kh. V. and Dadar, А.-К. Kh. (2019). Scheduling visualization methodology in Autodesk Revit 2018. Bulletin of Civil Engineers, No. 6 (77), pp. 179–185. DOI: 10.23968/1999–5571–2019–16–6–179–185.

Bolotin S. А. and Dadar, А. H. (2020). Methodology of setting priorities in integrated development of territories using BIM software and project management. Real Estate: Economics, Management, No. 1, pp. 57–62.

Bolotin, S. А., Dadar, А. Kh., Meshchaninov, I. Yu. and Oolakaj, Z. Kh. (2011). Energy and resource saving objects’ reconstruction sequence elimination with the regard for heterogenous limitations for the search for optimum. Bulletin of Civil Engineers, No. 3(28), pp. 60–65.

Bolotin, S. А., Klimov, S. E. and Simankina, Т. L. (2005). Optimization of resource distribution under calendar scheduling using the method of uncertain resource coefficients. Scientific Herald of the Voronezh State University of Architecture and Civil Engineering. Construction and Architecture, No. 1, p. 101.

Bovteyev, S. V. and Tsvetkov, A. V. (eds.) (2008). Managing investment construction projects on the basis of Primavera. Moscow, Saint Petersburg: PMSOFT, Saint Petersburg State University of Architecture and Civil Engineering, 455 p.

Bunday, B. (1989). Basic linear programming. Moscow: Radio i Svyaz, 176 p.

Chelnokova, V. М. (2015). Determination of rational priority of project construction in calendar planning of complex development of the territory. Bulletin of Civil Engineers, No. 2 (49), pp. 102–106.

Chelnokova, V. М. (2016). Features of calendar scheduling of complex development of the territory by the development organization. Bulletin of Civil Engineers, No. 3 (56), pp. 136–142.

El-Rayes, K. and Moselhi, O. (1998). Resource-driven scheduling of repetitive activities. Construction Management and Economics, Vol. 16, Issue 4, pp. 433–446. DOI: 10.1080/014461998372213.

Hejducki, Z. and Rogalska, M. (2011). Time coupling methods construction scheduling and time/cost optimization. Wroclav: Oficyna Wydawnicza Politechniki Wroclawskiej, 91 p.

Kupershtein, V. I. (2010). Microsoft Project 2010 in project management. Saint Petersburg: BKhV-Peterburg, 416 p.

Leach, L. (2010). On time and on budget. Critical chain project management. Moscow: Alpina Publisher, 354 p.

Lychkovsky, D. А. and Sayenko, I. А. (2017). Integrated development as a priority for the development of urban areas. Economic Development Research Journal, No. 6, pp. 128–134.

Petrochenko, M. V. (2018). Organization and planning in construction. Fundamentals of lean construction. Part 1. Study guide. Saint Petersburg: Publishing House of Polytechnic University, 208 p.

Repository for legal documents, standards, regulations, and specifications (2021). Construction Rules and Regulations SNiP 1.04.03-85. Norms of construction duration and backlog in the construction of enterprises, buildings, and structures. [online]. Available at: [Date accessed November 21, 2021].

Rogalska, M., Bożejko, W. and Hejducki, Z. (2008). Time/cost optimization using hybrid evolutionary algorithm in construction project scheduling. Automation in Construction, Vol. 18, pp. 24–31.

Selinger, S. (1980). Construction planning for linear projects. Journal of the Construction Division, Vol. 106, Issue 2, pp. 195–205.

Garant (2021). Urban Planning Code of the Russian Federation No. 190-FZ dated December 29, 2004. [online]. Available at: [Date accessed November 21, 2021].

Voronina, N. V. and Fentisova, I. V. (2016). Development of public-private parthership in the complex housing development of territories. In: Kourov, V. F. (ed.) Current Issues in the Economic Development of Enterprises, Industries, Sectors, and Territories. Proceedings of the International Research and Practice Conference. In 2 volumes. Vol. 2. Khabarovsk: Pacific National University, pp. 33–36.



  • There are currently no refbacks.


ISSN: 2500-0055