"Вестник МГСУ"

Megacities like the most massive manifestation of urban settlements, will keep on growing due to the socio-environmental reasons. And the problems of house, industrial and socio-cultural construction will grow under the conditions of vacant land limit. The approaches to the building development of new territories and previously used ones are significantly different. That requires a modification of methodological approaches and the development of new principles of evaluation. In the current situation of understanding of the biogenic processes significance, new territories can be developed in environmentfriendly way. In respect of the previously built-up or polluted areas, the evaluation of the changes in anthropogenic ecosystem should be made.In general, urbanized landscapes are growing, but the territories suitable for urban development do not grow. That dramatically raises the price for land, particularly for the previously undeveloped land. At the same time, the value of previously used for agricultural purposes land within the city or within industrial zones also increases. For any landscape, used or not, should be regarded as non-renewable.The development of technologically polluted areas require significant economic investments. As a result, the development of optimal methods of the area valuation for further investment and construction is important. As commonly cited, soil and land have no value as such, which should be compared with the income. The market price of one square meter finally gives us the value of undeveloped land, and its location, status, and the possibility of further use is of crucial significance. Investors evaluate real estate not only by the location, but also by material, income and profitability. Systematic investigation of these criteria allows us to see the weaknesses and advantages of the land. The cost of real estate can change quickly in case of changes in its pricing factors. A good example is construction of a highway in the neighborhood: positive for industrial construction, negatively for living. Therefore, such signs should be permanently recorded and evaluated.

This article considers building information modeling (BIM) maturity levels as an ability to operate BIM technology both at an individual project and across the enterprise. The main indicator of BIM implementation maturity is the level of technological and organizational changes in a company. 3 levels of BIM maturity according to BIM Task Group are shown. This article shows some basic criteria of effective BIM-technology implementation. The core transformation is process reengineering, which gives a vector to all subsequent changes including conversion of organizational structure and material and technical equipment. In this regard, the early stages of BIM implementation major cost falls on process reengineering, especially on the transition from CAD to BIM. The radical conversion of work processes entails a review of the staff of the company in terms of the structure and qualification. Other types of BIM implementation investments for the subsequent stages of the project consist of the costs on structural changes, staff education, technical provision and infrastructure development. In order to estimate the investment in the process of implementing BIM all of the costs must be presented in monetary equivalent. This process is complicated by the necessity of converting high-quality information and time parameters, so it is advisable to appeal to the expert evaluation of the data. In addition to monetary costs of the implementation process there are some immeasurable ones. It is vital to take into account the losses associated with the absence of employees in the workplace at the time of re-education, as well as the costs of the process of evaluating the effectiveness of BIM.

At the stage of organizational preparation of the concentrated construction the main objective is the formation of the expected directions of territorial development. The result of the information output of this stage is geoinformation data, i.e. regulatory references on the territories of different function: industrial, civil, social, transport schemes, etc.. It is necessary to emphasize that the methodological basis for complex preparation of separate building sites, residential estates in the form of residential districts and buildings of this type of concentrated construction, has already been rather fully stated in the works of many scientists. At the same time such features of the concentrated construction are subject to the research and systematization as: the variety of the types of construction models of multi-purpose objects; preference of various cluster territories in the volumes and terms of investment; combination of separate stages of organizational preparation for the purpose of delivery of the sites within the planned terms of the beginning and the end of construction. The advantage of territorial cluster economy is in the fact that payback periods of infrastructure facilities are much less, than, for example, in case of infill construction. Besides, in case of cluster construction the investment of the preparatory period and the construction period are carried out from different sources and this type allows investors invite not only the state and municipal sources, but also the means of individuals. For effective work of a complex method of the organization of cluster building it is necessary to optimize schedules of investment streams and to lead them to an optimum look. Thus, the effective work of a complex method of a territorial cluster construction requires close cooperation of the participants with each other, with investors, government bodies, banks, consulting organizations, scientific research and educational institutions for further introduction and development of cluster construction. Effective organizational preparation of cluster construction will allow beginning and bringing into operation the cluster objects in due time.

The main source for the development of construction projects with energy-efficient technologies in use is investments. The traditional approaches of risk management: insurance, diversification and redundancy only raise the cost of the construction project, which has a negative impact on the investor’s decision to invest. In order to solve this problem an information system has been developed, which is based on the principle of insightful analysis of the potential “pure” risks and a list of recommendations of risk management. This tool allows identifying all the weaknesses of a construction project, improving the organizational and technological reliability, and imparting an understanding to the investor / a customer of the resources required for the project implementation.

This article discusses the methods and models based on the principles of logistics of construction, connected with sustainable (balanced and optimal) development of construction investment and construction activity. Based on the performance taking place in the sphere of investment of the main and auxiliary construction processes, logistics, a new approach to dealing with the notion of a homeostatic state is proposed - the notion of dynamic optimum. With this approach, the objective of sustainable development investment and construction activities and its subsystems is to sustain its optimal trajectory. This definition implies the optimum identification and verification of industry and corporate level. The authors propose the variety of links between subsystems of construction investment, as well as between its areas of growth, which are only part of overall sustainable development providing optimal development of the individual subsystems. In order to determine the trajectory of sustainable development it is necessary to accurately delineate using the methods of logistics space border of construction investment, which can be reached at set time intervals. Knowing these boundaries is of particular importance for the development of long-term forecasts, operational and production plans, and for the effective management of subsystems.

The modern transport system is a complex integrated object, which includes various road pavements, different technical means to provide vehicles motion, organizational systems of traffic management. In the contemporary conditions of construction industry functioning the task to create vehicle systems is of a great economic importance. Great labour and material resources are used for production of transport means for providing construction works and operation of these means. The authors consider the questions of theoretical and informational foundation development for the formation of the criteria basis of investment optimization task during construction of automatical and informational systems for increase of traffic safety in transport systems, providing zero accident rate.

The management of state-funded building programmes has a very high value in the present-day
volatile market. State budget proceeds cover the vast majority of construction projects. Improvement
of efficiency of interaction between the parties involved in this process is critical to the economic stability.
Federal programmes and projects managed by public corporations are among the main tools
applied to these investments. In this regard, the author identifies the areas of interaction and analyses
the link between the supervisory and executive elements of building programmes on the basis of the
principle of the feedback assessment. Feedback is an essential concept of the systems theory.
According to the results of this analysis, the author proposes methods of identification and
elimination of drawbacks in the operation of planning authorities. The planning procedure is to be
based on the scientific research with account for the main objectives of programmes and ancillary
servicing processes, material, human and financial resources. The findings of the author are applied
as the basis for the proposals designated for the improvement of investment management systems,
if funded from federal and regional budgets.

The technology of artificial intelligence is actively being mastered in the world but there is not much talk about the capabilities of artificial intelligence in construction industry and this issue requires additional elaboration. As a rule, the decision to invest in a particular construction project is made on the basis of an assessment of the organizational and technological reliability of the construction process. Artificial intelligence can be a convenient quality tool for identifying, analyzing and subsequent control of the “pure” risks of the construction project, which not only will significantly reduce the financial and time expenditures for the investor’s decision-making process but also improve the organizational-technological reliability of the construction process as a whole. Subject: the algorithm of creation of artificial intelligence in the field of identification and analysis of potential risk events is presented, which will facilitate the creation of an independent analytical system for different stages of construction production: from the sketch to the working documentation and conduction of works directly on the construction site. Research objectives: the study of the possibility, methods and planning of the algorithm of works for creation of artificial intelligence technology in order to improve the organizational-technological reliability of the construction process. Materials and methods: the developments in the field of improving the organizational and technological reliability of construction were studied through the analysis and control of potential “pure” risks of the construction project, and the work was also carried out to integrate the technology of artificial intelligence into the area being studied. Results: An algorithm for creating artificial intelligence in the field of identification of potential “pure” risks of construction projects was presented. Conclusions: the obtained results are useful for working out practical steps for mastering the technology of artificial intelligence in order to improve the organizational and technological reliability of the construction process.