Next Article in Journal
Review of the Role of Building Information Modelling-Based Constructability in Improving Sustainability in Industrial Plant Construction Projects
Previous Article in Journal
Analysis of Seismic Performance for Segmentally Assembled Double-Column Bridge Structures Based on Equivalent Stiffness
Previous Article in Special Issue
Computational Precedent-Based Instruction (CPBI): Integrating Precedents and BIM-Based Parametric Modeling in Architectural Design Studio
 
 
Search for Articles:
Title / Keyword
Author / Affiliation / Email
Journal
Article Type
 
 
Advanced Search
 
Section
Special Issue
Volume
Issue
Number
Page
 
Journals
Buildings
Volume 15
Issue 11
10.3390/buildings15111920
buildings-logo
Submit to this Journal Review for this Journal Propose a Special Issue
Article Menu

Article Menu

share Share announcement Help format_quote Cite question_answer Discuss in SciProfiles
first_page
settings
Order Article Reprints
Font Type:
Arial Georgia Verdana
Font Size:
Aa Aa Aa
Line Spacing:
Column Width:
Background:
Article

Monetizing Digital Innovation in the AEC Industry: Real Estate Value Creation Through BIM and BMS Integration

by
Edison Atencio
1,*,
Costanza Mariani
2,
Riccardo Accettulli
2 and
Mauro Mancini
2
1
School of Civil Engineering, Pontificia Universidad Católica de Valparaíso, Av. Brasil 2147, Valparaíso 2340000, Chile
2
Department of Management, Economics and Industrial Engineering, Politecnico di Milano, Via Lambruschini 4b, Bovisa, 20156 Milan, Italy
*
Author to whom correspondence should be addressed.
Buildings 2025, 15(11), 1920; https://doi.org/10.3390/buildings15111920
Submission received: 2 May 2025 / Revised: 26 May 2025 / Accepted: 27 May 2025 / Published: 2 June 2025
(This article belongs to the Special Issue Architectural Design Supported by Information Technology: 2nd Edition)
Browse Figures
Versions Notes

Abstract

The real estate sector is increasingly recognizing facility management (FM) as a key driver of asset value. Among emerging technologies, Building Information Modeling (BIM) and Building Management Systems (BMSs) stand out for their potential to enhance FM efficiency by integrating design data with building operations across the entire lifecycle, from construction to maintenance, performance monitoring, and renovation. While their technical applications have been widely studied, the financial impact of these tools on FM remains underexplored. This paper addresses that gap by estimating the economic value generated by implementing BIM and BMS in real estate facility management. Based on thirteen semi-structured interviews with professionals from the Italian real estate sector, we identified and quantified cost-saving factors and challenges related to digital adoption. These cost efficiencies, when recurring and quantifiable, can improve net operating income (NOI), thereby supporting higher asset valuations under income-based real estate appraisal methods. The results show that integrating BIM and BMS in facility management may generate average annual cost savings of 5.81% relative to asset value, with coordination improvements alone accounting for up to 3.28% per year. Based on a 30-year simulation, these savings correspond to a positive Net Present Value (NPV), supporting the financial viability of digital FM adoption in real estate. This study offers empirical evidence to support investment decisions in digital FM technologies and contributes to bridging the gap between innovation and financial evaluation in the real estate sector.

1. Introduction

The real estate industry plays a crucial role in boosting domestic development and the worldwide economy. In 2017, worldwide real estate transactions amounted to a value of $873 billion, according to [1]. Further, the global real estate market was valued at approximately $379.7 trillion in 2022, as per [2] in comparison to the global GDP, which stood at around $100.6 trillion in the same year, based on data from the World Bank (2022). The fact that the valuation of the global real estate market is almost four times larger than the global GDP highlights the sheer size and economic significance of the real estate sector. Within this industry, property evaluation stands as a critical factor affecting the operations of the real estate market. It is crucial for valuers to accurately determine property prices, as imprecise valuations can have substantial effects on various stakeholders, including governments, policymakers, banks, investors, insurance companies, real estate developers, and the general public [3,4,5]. The literature indicates that real estate property evaluation is a complex, multi-criteria process involving diverse factors that collectively influence the final valuation. Among these, location is relevant, as it directly influences demand and price; studies by [6,7] have demonstrated the significant impact of location and environmental quality on property values. Additionally, the physical characteristics of the property, including size, age, and architectural design, play crucial roles in determining its value [8,9,10]. Market conditions, reflecting the current economic climate and real estate trends, also heavily influence valuations, a concept originally elaborated by [11] and later studied further by the literature [12,13].
Within the frameworks for defining a property value, some authors have started mentioning facility management (FM) as a possible influencing factor, underlining the importance of maintaining and enhancing the functionality and sustainability of a property to ensure its appeal and longevity [14,15,16]. FM can be broadly defined as the integrated management of an organization’s services and physical infrastructure to optimize the environment and support its primary operations and objectives [17]. It encompasses a broad spectrum of services related to facilities, playing a crucial role in overseeing facility resources, auxiliary services, and the work environment to facilitate the primary operations of an organization over both the short and long-term. FM can be broadly classified into two main categories: ‘hard’ and ‘soft’ services. Hard services refer to the physical and non-removable aspects of a building, such as heating, fire safety, and elevators, while soft services enhance workplace comfort and security, including cleaning, catering, security, and landscaping [18]. Effective facility management can lead to improved operational efficiency, reduced costs, and increased property desirability, likely positively impacting its valuation [19]. Over the last decade, the extant literature has shown that the streamlining of facility management processes has been predominantly linked to innovations in IT, among which Building Information Modeling (BIM) stands out significantly [19,20].
Defined by [21] as generating, storing, managing, exchanging, and sharing building information in an interoperable and reusable format, BIM represents a critical enabler for improving the efficiency and effectiveness of FM processes. By connecting BIM-based structural components with FM work details, the BIM model and FM database can be merged, facilitating easy access and use of information [22]. Maintenance staff can access both FM data and the BIM geometric model, including equipment location, accessibility, and maintainability [19]. Virtualization within the BIM framework can support on-site FM tasks and address the challenge of a skilled workforce shortage. In this study, BIM is considered the central digital infrastructure supporting facility management (FM), while Building Management Systems (BMSs) are treated as complementary technologies that, when integrated with BIM, enhance real-time data acquisition and operational responsiveness, contributing to the creation of a digital twin environment [23].
Earlier studies have highlighted that adopting BIM offers improved collaboration, increased automation, enhanced analytics, and optimized information management [23].
Further, the increasing relevance of BIM integration in FM is also reinforced by broader policy and market trends. In the European context, the Energy Performance of Buildings Directive (EPBD) and the Digital Decade initiative emphasize data-driven building performance and smart infrastructure as strategic priorities. In parallel, the rise of ESG reporting frameworks, including the EU Taxonomy and CSRD [24], encourages real estate owners to demonstrate sustainability, operational transparency, and digital traceability. As a result, the adoption of BIM and BMS is no longer only a matter of efficiency but also a response to evolving compliance requirements and investor expectations in both public and private sectors. However, despite its potential benefits, there has been a noticeable lack of enthusiasm among property owners and facility managers to adopt BIM or to invest in creating interoperability between design, construction models, and maintenance software systems. A primary reason for this reluctance is the perception among these stakeholders that the advantages and return on investment from implementing BIM are not sufficiently compelling [25]. The literature has shown that, despite stakeholder reluctance rooted in doubts about the return on investment, the benefits of implementing Building Information Modeling (BIM) in facility management (FM) are significant and well-documented, emerging through three main lines of inquiry. First, a range of (i) illustrative case studies highlight how BIM has enhanced FM and maintenance processes. For instance, [26] reports that at the Fort Garry campus of the University of Manitoba, BIM enabled facility staff to swiftly respond to temperature-related complaints by providing access to real-time and historical environmental data, as well as detailed operational information about surrounding rooms. Similarly, [26] demonstrates that BIM applications in tunnel FM significantly contribute to safer and more reliable infrastructure operation.
Second, researchers have explored BIM’s potential in FM through (ii) expert interviews to forecast future application areas and benefits. For example, refs. [23,27] identify key use cases such as identifying building components, accessing real-time data, supporting visualization and marketing, and assessing maintainability. Furthermore, refs. [28,29] report anticipated advantages such as improved system maintenance and using BIM as a data source for planning, monitoring, and optimizing maintenance activities. Third, scholars have focused on developing the conceptual models, data frameworks, and technologies necessary to integrate BIM with maintenance management systems. For instance, refs. [30,31] discuss approaches such as defining the critical information required for FM models, designing BIM servers, and creating dedicated repositories for FM-related objects. However, despite these promising developments, a notable gap persists in the existing body of research: few, if any, studies attempt to quantify the financial value generated by BIM implementation in FM. Despite growing interest in the application of BIM and BMS within facility management, the literature remains fragmented and predominantly focused on technical benefits [31], with limited efforts to quantitatively assess their long-term financial impact, integrate expert-based scenario modeling in this evaluation, or explicitly link digital FM practices, intended as the digitally enabled management of facility services, to real estate asset valuation and investor decision-making frameworks.
While the economic benefits of BIM implementation during the construction phase have been well-documented—such as the 15% reduction in direct construction costs reported by [22,32]—there remains, to the best of the authors’ knowledge, a notable lack of studies assessing the financial value of BIM adoption across the entire building lifecycle. In particular, the facility management phase is critically underrepresented in the literature, despite its potential to yield substantial long-term economic returns. This value can be assessed by recognizing that adopting BIM within a company’s real estate portfolio can significantly reduce management costs [27]. Our study aims to fill the gaps in literature by combining expert-based insights with probabilistic financial modeling to quantify the long-term economic impact of BIM/BMS implementation in facility management, linking digitalization not only to operational cost savings but also to real estate asset valuation.
Thus, in line with the proposed objective, we have structured our work around the following research questions:
  • RQ1: what factors, associated with implementing BIM, influence the costs of facility management activities, either by reducing or increasing them?
  • RQ 2: following the investment in BIM implementation, what is the estimated quantification of the impact of these factors on the cash flows of facility management activities?
  • RQ 3: under what conditions can cost reductions and practices specific to BIM-enabled facility management be linked to increased asset value?
We conducted thirteen semi-structured interviews with expert professionals from the Italian real estate sector to address these questions. These interviews provided both an assessment of which BIM-related benefits and implementation costs—previously identified in the literature—are most likely to materialize within their specific business context, as well as an estimation of the expected economic impact of BIM adoption on facility management cash flows. Through the quantification of the value of BIM’s impact on the cash flows of facility management, we were able to estimate a Net Present Value (NPV) that provides a comprehensive financial metric for assessing the viability and profitability of implementing BIM in real estate investments. This NPV calculation incorporates the initial investment costs, the ongoing operational savings, and the enhancements in efficiency brought about by BIM, offering a holistic view of the economic benefits over the facility management building’s lifecycle—an approach that aligns with the FM Value Map in highlighting value creation through operational support and with the Technology-Organization-Environment (TOE) framework in framing digital adoption within organizational and environmental contexts [33,34].
The paper is structured as follows: Section 2 describes the research method, outlining the four-phase framework adopted for the study. Section 3 presents the results, including the literature review on BIM and FM, the design and deployment of the assessment tool, and the findings from expert interviews and financial modeling. Section 4 discusses the results in light of the research questions, highlighting key insights regarding cost impacts, economic implications, and asset valuation. Finally, Section 5 provides the conclusions and outlines recommendations for future research.

2. Research Method

Figure 1 presents the research method followed in this research, which is based on four stages.
The diagram presents the methodological framework employed in this study, structured into four main stages. The first stage, State of the Art, involves conducting a literature review to explore the benefits of BIM applications in real estate, the challenges of digitalization in the sector, and the core features and activities associated with FM. This phase results in the identification of existing research gaps, as well as comprehensive lists of FM features and BIM-related benefits. The second stage, Assessment Tool Design, combines qualitative and quantitative methods to develop the instruments needed for data collection. This includes designing the expert interview protocol, defining the composition of the expert panel, and creating the assessment tool. In the third stage, Assessment Deployment, the research team engages with selected experts by conducting interviews and collecting data using the previously designed tools. The collected data is then stored in the assessment tool for subsequent analysis. Finally, in the Analysis stage, both qualitative and quantitative analyses are carried out to extract key insights and simulate the cost-benefit impact of BIM adoption in FM. This comprehensive approach allows for estimating the economic value generated by digital innovations in real estate management.

3. Results

This section presents the results obtained through the application of the Design Science Research Method (DSRM), a problem-solving framework used to develop and evaluate practical solutions [35]. As shown in Figure 1, the process is structured into four main phases: State of the Art, Assessment Tool Design, Assessment Deployment, and Analysis.

3.1. State of the Art

To support the development of our research, we conducted an extensive literature review using Scopus and Web of Science. The primary objective was to identify and extract the key benefits and challenges associated with the application of BIM in facility management (FM). These insights were then used to guide expert interviews, allowing participants to evaluate the potential impact of each benefit and challenge on specific FM activities. This approach enabled a quantitative assessment of both the positive value and the implementation costs of BIM, specifically in terms of their effects on the cash flows generated by FM operations.

3.1.1. BIM Benefits

The literature highlights a broad and transformative spectrum of benefits associated with implementing BIM, extending well beyond the construction phase into the entire lifecycle of a building. Literature shows that through the adoption of BIM, teams experience significant enhancements in efficiency—resulting in streamlined workflows, reduced schedules, and optimized decision-making processes—not only during project delivery but also throughout the entire building lifecycle, from design and construction to operation, maintenance, and eventual decommissioning [36]. BIM’s diverse toolkit equips stakeholders with an array of tools and capabilities that empower them to work cohesively, thereby elevating project and facility management to a higher level of precision and effectiveness [37]. Safety and energy efficiency stand out as key advantages of BIM implementation during a building lifecycle, enabling proactive hazard identification, improved emergency response planning, and adherence to stringent quality standards—contributing to a safer, more energy-efficient, and well-regulated built environment [31]. The literature also highlights the importance of “Quality, Inspection, and Control Improvement”, emphasizing the critical role of BIM and digital twins in raising quality assurance standards. Their precision in modeling and information management enables more rigorous inspections and oversight, leading to enhanced project quality across all phases. This increased level of control benefits the construction process and has a lasting impact on facility management, ensuring that assets are delivered with higher standards of accuracy, reliability, and maintainability throughout their operational life [38]. “Communication improvement” also emerges as a key benefit of BIM, highlighting its crucial role in enhancing information exchange among stakeholders. Beyond facilitating internal team collaboration, BIM enables communication with external factors such as suppliers, clients, and service providers. Ensuring consistent, transparent, and real-time information flow supports a more integrated and cooperative working environment throughout the building lifecycle [29]. Coordination is also widely recognized as a key benefit of BIM, particularly in improving collaboration between contractors and suppliers during construction and facility management [39,40]. According to the extant literature, the integration between BIM and FM offers an end-to-end perspective that extends well into the building’s operational phase. BIM’s ability to bridge the gap between construction and facility management ensures that the value it brings persists well beyond project completion. This integration optimizes maintenance and operational processes, reinforcing BIM’s status as a holistic solution [41].
Table 1 categorizes the benefits associated with the application of BIM across the entire building lifecycle, as identified in the literature. Each category is accompanied by a brief description and relevant references supporting it.

3.1.2. Challenges

In general, the literature places a strong emphasis on exploring the benefits associated with the implementation of BIM practices. Nonetheless, some studies also address the potential drawbacks, while others focus on the challenges posed by digitalization within the AEC (Architecture, Engineering, and Construction) sectors [61]. Cultural resistance within organizations often impedes the adoption of BIM practices. Employees may resist change, especially if they are accustomed to traditional workflows. In such cases, companies must invest substantial effort and resources into training programs to familiarize their workforce with BIM tools and methodologies. Failure to address cultural resistance and adequately train employees can lead to inefficiencies, reduced productivity, and missed opportunities for improvement [51]. On the technology side, the need for systems integration and interoperability is crucial in a BIM-driven environment. Many companies use diverse technological systems for various aspects of their operations. Failure to achieve this integration can result in data silos, increased manual data entry, and a lack of real-time collaboration, all of which undermine the potential benefits of BIM [40]. In parallel, BIM relies heavily on data, and the sheer volume of information generated can be overwhelming. Companies may struggle to manage and maintain data integrity. Poor data quality can lead to inaccuracies in models and analyses, jeopardizing project outcomes. Inadequate data management techniques can result in costly errors, rework, and a failure to capitalize on the benefits of data-driven decision-making [55]. Moreover, BIM thrives on real-time information updates. Outdated data can lead to misinformed decisions, errors in construction, and a lack of alignment between project phases. Companies that do not prioritize information updates risk compromising project quality and efficiency [67]. Also, still in terms of processes and flows inside projects, effective collaboration is fundamental to BIM’s success. In an industry known for its competitiveness, fostering cooperation among stakeholders can be challenging [68]. Imagining construction’s digital future [55]. Finally, from a legal point of view, the absence of BIM standards poses significant challenges. This can result in contractual disputes, increased administrative burdens, and inefficiencies in project delivery [69]. To mitigate these risks, companies must proactively tackle these challenges by fostering a culture of openness to change, investing in training and education, adopting interoperable technologies, promoting collaboration, implementing robust data management strategies, prioritizing timely updates, and advocating for the development and adoption of BIM standards [61]. Similar to the previous categorization of benefits, the identified challenges have been organized into thematic groups based on their nature and characteristics. Specifically, four main categories have been defined as shown in Table 2: people-related challenges, process-related challenges, technology-related challenges, and legal and regulatory challenges.
The final selection of articles for this review reveals a noticeable imbalance between the evaluation of benefits and challenges. As shown in the previous table, five benefit categories appear in approximately 50% of the reviewed documents, whereas challenge categories are represented in no more than 30%. Nevertheless, it is important to highlight that a significant number of articles report reductions in project effectiveness or efficiency due to BIM-related obstacles. For this reason, challenges were included in the framework to account for the increased costs associated with these issues.
Among the identified challenge categories, process-related challenges are the most frequently cited, appearing in 12 articles—accounting for 34% of the total difficulties reported. Technological and people-related challenges follow, each comprising roughly a quarter of the citations. Legal challenges, while the least frequently mentioned, should not be considered less significant. Their potential impact on real estate asset maintenance costs is explored further in this study.
Alongside the literature review, a structured research effort was undertaken to identify the key competencies within facility management, including associated activities, tasks, and roles. Particular attention was paid to ensuring that the identified activities align with digitalization processes and digital twin solutions found in the literature, particularly those classified as potential benefits [72]. Depending on the building, the activities can vary significantly and may not apply to other real estate assets. For this reason, a selection process for activities was undertaken to include in the document only those that are generalizable to the vast majority of commercial or production buildings [73]. This approach allows the analyses presented in the following chapters to be interpreted without the need for exceptions or special cases. Furthermore, given that this article focuses on the Italian market, we consulted public tender guidelines related to maintenance and, more broadly, facility management activities issued by Consip. Consip, a public company under the Italian Ministry of Economy and Finance, is responsible for managing high-value public procurement tenders, ensuring that processes maintain high quality while adhering to established norms, standards, and procedures. Notably, in tenders where BIM is mandatory for AEC projects exceeding one million euros, Consip provides clear guidelines on the classification and assignment of facility management activities and responsibilities. The output of this phase is a comprehensive table listing the activities and tasks relevant to the facility management domain. This list includes the most common and widely applicable responsibilities involved in the management of real estate assets (see Table 3).

3.2. Assessment Tool Design

We adopted a robust methodological approach to estimate the financial impact of implementing BIM in FM: conducting interviews with industry experts. This method was strategically chosen for several reasons, exploiting its advantages in closing the identified gap. In this regard, on the one hand, the following reasons support the choice of the interview method:
  • Access to Expert Insights: interviews provided us with direct access to professionals and experts within the facility management and BIM domains. Industry experts possess a wealth of in-depth knowledge, cultivated over years of hands-on experience [74]. Their careers span various roles in facility management, design, construction, and project management. These professionals bring a level of expertise that extends beyond what is typically found in academic research papers. In particular, under this perspective, the interviews enabled us to tap into the practical wisdom that experts have gained through projects and problem-solving experiences.
  • Real-World Data: by engaging with experts, we gained access to real-world scenarios showcasing the challenges and opportunities faced in actual facility management projects, making our research more grounded and applicable [75]. Facility management practices can vary greatly depending on the type of facility and regional context. Interviews allowed us to gather context-specific insights that contributed to a more holistic understanding of BIM’s financial implications.
  • Tailored Information: the interview approach allowed us to tailor our inquiries to specific areas of interest, ensuring that we gathered pertinent data directly related to our research objectives. By tailoring our questions to their specific knowledge domains, interviewees felt more engaged and valued, leading to richer and more insightful responses. This depth of understanding was pivotal in uncovering information related to cost reductions, information assessments, and digital element value [76].
Data were collected through a structured interview process with industry experts to gain a practical understanding of these challenges and their financial implications. Participants were asked to quantitatively assess the expected impacts—both benefits and costs—of BIM implementation within facility management. This approach allowed us to estimate the value that BIM can generate not only during the construction phase but also across the entire lifecycle of a building, including its operation, maintenance, and long-term asset management. By cross-referencing expert insights with existing literature, we harnessed a triangulation of data sources, bolstering the overall credibility of our study [75,77]. Interviews were conducted via online meeting platforms, and each session was recorded and transcribed to ensure the accuracy and traceability of the collected data.

Interview Structure

The interviews followed a semi-structured protocol organized around four practical objectives (see Table 4), with questions designed to explore both perceived benefits and challenges of BIM/BMS implementation in FM. While not directly anchored to a single theoretical model, the structure was informed by existing literature on digital innovation, facility management, and BIM adoption. Responses were later coded thematically into benefit and challenge categories identified during the literature review, supporting analytical consistency. To validate the insights, a triangulation process was employed: interview data were cross-checked with published studies, sector guidelines, and expert-based quantitative assessments collected via a standardized Excel tool used during the final stage of each interview. This tool also acted as a feedback mechanism, allowing respondents to independently rank and quantify key drivers, reinforcing reliability and alignment across participants.
The first three objectives were pursued during the interview through a structured and exploratory set of questions designed to investigate the topics raised by the interviewees. The fourth objective was addressed separately using an Excel file, prepared in advance and kept identical for all participants.
Table 5 illustrates the structure of the interviews, highlighting their objectives and the corresponding questions.
To enhance transparency regarding the interview design and its role in shaping the cost impact model, it is important to clarify the logic connecting each interview phase with the study objectives. The semi-structured interviews were organized around four main goals, as outlined in Table 4. First, participants were asked to validate the relevance of benefits and challenges identified through the literature review within the Italian real estate context. Then, they were requested to provide quantitative estimates of the expected financial impact of those benefits and challenges, expressed as percentages of FM-related costs. This was followed by open-ended questions aimed at understanding how professionals recognize value creation over time. Finally, participants selected and ranked the most significant items using a structured Excel form. This step enabled the mapping of benefits and challenges to specific FM activities. This workflow ensured that expert insights were not only qualitatively captured but also directly converted into modeling variables used in the simulation phase (see Table 6 and Table 7).

3.3. Assessment Tool Deployment

While the integration of BIM and BMS into FM operations and their associated cost impacts are primarily described through structured narrative and simulation outputs in this study, the underlying workflow follows a sequential logic: from data collection via expert interviews to the categorization of BIM-related benefits and challenges, probabilistic modeling, and scenario-based NPV estimation. This process is analytically represented in Figure 2 and Figure 3, which illustrate the range and uncertainty of modeled financial outcomes. A dedicated visualization of this workflow will be explored in follow-up research with a focus on implementation support tools.

3.3.1. Integration of Expert Knowledge with Financial Modeling

Interview candidates were carefully selected from key roles within the facility management field, divided into operational/logistical and financial/profitability-oriented categories. Additionally, professionals from global service providers, which often manage outsourced facility services, were considered due to their technical and operational expertise. The organizations targeted for interviews included three typologies: financial institutions managing real estate as capital goods, investment firms focused on acquiring and selling upgraded properties, and large enterprises where real estate assets play a central operational role, such as hospitals, hotels, and shopping centers. Correspondingly, the study also categorized real estate assets into three types: capital goods (core operational assets), hold-to-be-sold properties (primarily for future resale), and hold-to-be-rented properties (used to generate rental income). This classification allowed us to account for different FM needs and accounting treatments when assessing the impact of digitalization. Experts were identified through LinkedIn and company websites, and interviews were arranged between August and mid-October 2023. The selected professionals came from institutions such as Generali, AXA, Unicredit, Intesa San Paolo, and COIMA. Participants provided quantitative estimates on the cost impact of BIM and DT adoption. These estimates were modeled using @Risk in Excel, applying a PERT distribution for probabilistic simulation over a 30-year building lifecycle. A total of 13 semi-structured interviews were conducted, a sample size deemed appropriate based on thematic saturation—observed after approximately 10 interviews—and the intentional inclusion of diverse expert profiles spanning finance, operations, and academia to ensure broad representation across roles and asset types in the real estate sector. As the study involved non-sensitive interviews with professionals acting in their institutional capacity, no formal ethical approval was required. All participants were informed of the research objectives and data treatment procedures and gave their explicit verbal consent to participate.
Four variables were considered: initial digital investment, cost savings, cost increases, and ongoing maintenance costs. Simulations explored pessimistic, neutral, and optimistic scenarios, incorporating inflation adjustments and real estate market variations. Results were expressed as percentages of real estate asset value to ensure comparability. Although no discount rate was applied, the model offers a static yet practical framework to assess BIM’s financial impact and can be replicated in future studies or different markets. Table 6 provides an overview of the interviewee participants.

3.3.2. Financial Modeling Approach: From Expert Estimates to Cash Flow Simulation

The data modeling and simulation process began with collecting all relevant data and Excel files generated from the interviews. These files identified frequently mentioned benefits and challenges categories, which were converted into a monetary configuration. Experts were asked to estimate cost variations associated with the benefits, challenges, and specific FM activities. In some cases, interviewees provided company performance indicators that helped quantify differences between digitized and non-digitized buildings. To express these cost variations—particularly savings—the value of the company’s real estate portfolio was adopted as the baseline. This choice aligns with corporate objectives and avoids inconsistencies arising from comparing internal budgets, which vary widely across firms. Using asset value also enhances sector-wide benchmarking, allowing for meaningful comparisons among companies and improving stakeholder understanding of the impact of BIM. Additionally, expressing cost reductions to asset value facilitates more effective communication with investors and other external stakeholders. However, as real estate portfolio value is relatively static while BIM-related savings may fluctuate over time, periodic updates are recommended to track and reflect evolving benefits. Given the diverse backgrounds of the experts, the financial impacts of BIM-related benefits and challenges were modeled using probability distributions with @Risk, an Excel add-in for Monte Carlo simulations and scenario analysis. These distributions accounted for cost savings, additional expenditures from implementation challenges, and the costs associated with adopting BIM in facility management. All values were expressed as percentages of the asset value to ensure comparability. When sufficient data were available, @Risk was used to identify the most appropriate probability distributions. The PERT distribution was applied in cases of limited data, as it requires only three inputs: minimum, most likely, and maximum values [78]. Unlike the triangular distribution, PERT emphasizes the most likely value, making it particularly suitable for subjective estimates based on expert judgment. Its smoother shape and more realistic representation of uncertainty offer a more accurate reflection of the expected outcomes associated with BIM implementation. Once these distributions were defined, values were summed to represent four key components of cash flows: (1) the initial investment in BIM (year zero), (2) cost savings from benefits, (3) cost increases from challenges, and (4) ongoing maintenance costs for digitalized assets. These elements are not considered constant because many external factors influence them over time. For example, greater market maturity may lead to lower implementation costs and enhanced benefits, while initial adoption hurdles in certain corporate cultures may lead to increased costs early in the digitalization journey. To simulate the long-term impact, a 30-year building lifecycle was used, with 30 iterations per year to reflect the variability of each cash flow component. The results formed the basis for three distinct scenarios—pessimistic, neutral, and optimistic—reflecting different assumptions about future adoption rates and efficiencies. Coefficients based on expert judgment and literature were applied to model how benefits and challenges might evolve. The simulation produced aggregated real cash flows for each scenario, providing a dynamic understanding of potential value creation over time. The analysis integrated two external variables to improve accuracy: inflation and commercial property price trends. Converting nominal cash flows into real terms eliminates the impact of inflation, which would otherwise distort comparisons over time. Real cash flows are preferred for long-term planning as they offer consistency, better risk assessment, and support more accurate investment decision-making. Similarly, incorporating real estate price trends helps reflect the changing denominator (asset value) in cost variation calculations. For example, if asset values decline, the same cost savings would represent a larger relative impact, which is relevant when interpreting results. Due to a lack of existing literature quantifying the temporal evolution of BIM-related cost benefits, the modeling provides only a static snapshot of the current state. The simulations do not predict how benefits and challenges will evolve naturally, as no established models link those changes to time-based variables. Therefore, while the results are useful for assessing the current financial potential of digitalization in FM, they should be interpreted as a preliminary approximation. To ensure neutrality and comparability, the analysis excludes the cost of capital and models facility management costs as fixed percentages of asset value, avoiding firm-specific financial assumptions and internal budgeting variations.

3.4. Analysis

Table 7 summarizes interviewees’ opinions on the financial impact of BIM and DT (digital twin) on facility management. Participants indicated whether they viewed the impact as positive (“YES” or “NO”) and whether BIM or DT solutions were currently implemented in their projects (shown in parentheses). Each row lists the respondent’s identification number and their professional role: “O” for operational and “F” for finance.
Overall, there was a stronger understanding and appreciation for digital twin solutions, which are widely adopted in the market—particularly in the context of energy systems. In contrast to BIM, all interviewees expressed a favorable opinion of digital twin technologies. BIM, on the other hand, received two negative responses, as two participants did not consider it essential or financially viable, especially for buildings managed primarily from a facility perspective. While the usefulness of BIM in facility management is acknowledged, its perceived value and applicability varied among respondents. Table 8 and Table A1 (available in Appendix A) present participants’ rankings of BIM-related benefits and challenges. The top-rated benefits were facility management (FM), Decision Support (DS), and Cost Cognition (CC), aligning with the priorities of data-driven professionals. Safety and Sustainability (SS) and Tenant Wellbeing (TW) also scored well, though TW was less emphasized. Human Management (HM) ranked lowest among benefits. On the challenge side, process (PR) and people (PE) were seen as the most critical barriers, reflecting the need for organizational and cultural change. At the same time, technology (TE) was considered less problematic. The results support the view that BIM/DT can deliver financial and organizational value.
The final set of benefits and challenges, shown in Table 8 along with their corresponding values for Criterion 2 and Criterion 3, was derived from the data processing phase. These items form the basis for analyzing cost variations associated with facility management activities.
Among the identified benefits and challenges, experts felt confident providing monetary estimates for only a subset of them, as reported in Table 9, For these items, cash flows were calculated based on a set of defined assumptions. The Net Present Value (NPV) simulation was conducted over a 30-year time horizon, which aligns with the typical lifecycle of commercial real estate assets [7]. To ensure comparability and generalizability across different organizational contexts, all cash flows were modeled in real terms and adjusted for inflation using data from ISTAT [79]. An annual inflation rate (π) of 3.54% was applied, representing the average of the past five years in the Italian market. This relatively high value is attributed primarily to post-pandemic inflationary trends, with peaks reaching 7–8%, which raised the average but was nonetheless accepted to preserve the consistency and interpretability of the results. To isolate the financial effect of implementing BIM/BMS-enabled facility management practices, no explicit discount rate was applied. This approach avoids assumptions about the cost of capital or investor-specific hurdle rates, thereby allowing the analysis to focus on relative impacts. Consequently, the cost of capital (k) was set at 0%. Furthermore, the simulation included expert-based estimates related to initial digital investments, expected cost savings, additional implementation costs, and long-term maintenance. The analysis was carried out using @Risk 7.6 software, applying PERT distributions to account for uncertainty. Additional assumptions included a 0% taxation rate on real estate value (t), consistent with the absence of specific property taxes on transactions or revaluation gains in the Italian context, and a –2.2% annual change in commercial building prices (π_CB), reflecting recent market data from ISTAT.
Although @Risk was unable to fit standard probability distributions to the benefit-related data from the interviews—primarily due to the limited sample size and the qualitative nature of the expert input—the collected estimates still provide valuable insights. These quantifications help to define the boundaries, risks, and opportunities associated with digitalization, including BIM and digital twin solutions. As explained in the methodology section, PERT distributions offer a robust and flexible modeling approach when data availability is limited. In this context, the minimum and maximum values reported by experts were used as distribution limits, while the average of all responses was taken as the most likely value.
Figure 2 shows the @Risk output, clearly visualizing the modeled variables.
Benefits 1, 4, 11, 15, 16, and 17 generate the range of values in Figure 3. The simulation suggests that BIM/BMS-enabled practices may lead to an average annual cost savings equivalent to approximately 5.81% of the asset’s value, with coordination improvements (Benefit 15) emerging as the most influential factor—potentially contributing up to 3.28% annually. These values should be interpreted as expert-informed projections rather than evidence of direct causal relationships.

4. Discussion

This discussion integrates and deepens the analysis developed in this study, aiming to answer the three research questions and to contextualize the results within the broader transformation of the real estate and facility management sectors. The qualitative evidence from expert interviews, the literature synthesis, and the probabilistic financial modeling allows us to critically interpret how the implementation of BIM and digital twin (DT) solutions impacts cost dynamics, decision-making processes, and the valuation of real estate assets.
RQ1: What factors, associated with implementing BIM, influence the costs of facility management activities, either by reducing or increasing them?
This study identifies a wide range of factors that influence facility management (FM) costs following the implementation of BIM. On the cost reduction side, key benefits include increased operational efficiency, enhanced coordination among stakeholders, real-time data access, and more structured maintenance planning. BIM enables the digital representation of building elements and their lifecycle behaviors, supporting preventive and predictive maintenance, energy optimization, and the reduction of communication inefficiencies. These advantages are further amplified when the BIM model is continuously updated and integrated with Building Management Systems (BMSs) and sensor networks—forming a comprehensive digital twin ecosystem.
However, the study also highlights several factors that may increase costs or delay returns. These include high upfront implementation expenses, the complexity of retrofitting legacy buildings and processes, and a lack of qualified personnel or organizational readiness. Some interviewees also raised concerns about the risk of underutilization, where digital tools are adopted but not effectively used due to fragmented governance or weak information management systems.
The maturity level of existing FM practices plays a crucial role. In organizations with advanced FM systems, BIM tends to generate incremental improvements, particularly in coordination and reporting. In contrast, in low-maturity environments, digitalization serves as a catalyst for broader process reengineering and governance transformation—offering greater potential benefits but also requiring more substantial organizational change.
RQ2: Following the investment in BIM implementation, what is the estimated quantification of the impact of these factors on the cash flows of facility management activities?
Using a probabilistic model based on three scenarios (optimistic, realistic, and pessimistic), this study estimates that BIM-enabled FM strategies can reduce total facility management expenditures by between 6.42% and 11.32% over a 30-year lifecycle. Considering that FM costs can amount to as much as 720% of an asset’s value over such a period, these savings are substantial. The financial simulation—grounded in expert assessments and scenario-based logic—translates qualitative insights into quantifiable economic impacts.
These savings are not merely theoretical. Interviewees reported that even partial implementations—particularly those involving BMS and structured data models—are already delivering reductions in energy and maintenance costs. Moreover, organizations that have adopted QR-code tracking, asset-specific data catalogs, and integrated monitoring systems have observed tangible improvements in process efficiency and reductions in contractor overhead.
However, the financial impact of BIM implementation varies depending on asset type and organizational model. Assets held for long-term use (instrumental assets) are more likely to justify investment in BIM, given their ongoing FM cost exposure. Conversely, investment properties leased to third parties offer weaker incentives unless BIM deliverables are contractually required or explicitly recognized in the market.
RQ3: Under what conditions can cost reductions and practices specific to BIM-enabled facility management be linked to increased asset value?
This question is central to the study’s value proposition: moving from cost savings to asset valorization. The findings driven from simulations suggest that when digital FM practices generate recurring, certifiable cost reductions, they become financially relevant in valuation models. Discounted cash flow logic implies that lower operational expenditures improve net operating income, thus supporting higher valuations under income-based methods.
In optimistic scenarios, the modeled annual savings of 2.7% can offset the average annual depreciation of 2.2% observed in the Italian commercial real estate market over the last decade. This aligns with the proposition that digitalization can act not only as a driver of operational excellence but also as a financial hedge against macroeconomic depreciation.
Nonetheless, for this value to be market-recognized, it must be formalized. Interviewees emphasized the need for certification mechanisms, similar to ESG frameworks, that quantify and validate FM performance improvements. Such certifications would help investors and buyers differentiate assets based on their digital maturity, fostering a virtuous investment cycle in high-performance buildings.
Importantly, the study notes that value creation does not occur uniformly. It is conditioned by asset governance models, the presence of dedicated FM teams, and the integration of digital tools into daily operations. For publicly owned assets or properties with outsourced FM, a gap remains between potential and realized value. Bridging this gap requires improved role clarity, contract design, and stronger performance monitoring systems.
Overall, this discussion positions digital FM as a technological upgrade and strategic asset management transformation. It reinforces the idea that BIM and DT tools create financial, operational, and market differentiation advantages when properly implemented and governed. The recognition of these advantages, however, remains contingent upon institutional innovations in certification, valuation, and stakeholder alignment. In fact, while the financial projections highlight significant potential for cost savings, it is equally important to acknowledge the risks and organizational barriers associated with digital adoption. These include high initial implementation costs, limited interoperability between BIM and BMS platforms, and internal resistance to process change, particularly in organizations with low digital maturity. Cultural inertia, insufficient training, and unclear ownership of digital processes can delay adoption or lead to suboptimal use of the technology, undermining expected benefits. Furthermore, without robust change management strategies, organizations may experience increased overhead or duplicated effort during the transition period. These risks highlight the need for phased implementation approaches, targeted training programs, and governance mechanisms to ensure alignment between technological capabilities and organizational readiness.
The findings offer practical value for FM professionals and real estate investors by providing a structured framework to quantify the financial impact of digital FM initiatives such as BIM/BMS integration. This framework can support investment appraisal, inform procurement and maintenance planning, and guide asset valuation by linking operational savings to net operating income, thus enabling more informed, data-driven decision-making. For example, a property manager overseeing a hospital or shopping center can use the model to estimate whether the upfront cost of BIM implementation is offset by long-term gains in maintenance efficiency and energy savings, helping justify the investment to internal stakeholders or external investors.

5. Limitations and Conclusions

This study aimed to evaluate whether digital innovation—particularly BIM and DT integration into facility management—can be monetized in the real estate sector, with a focus on the Italian market.
The evidence confirms that digitalization not only reduces operational costs but also enhances asset performance, providing a compelling case for its inclusion in real estate valuation frameworks. Three key conclusions emerge from the findings. First, BIM and DT can generate substantial cost savings over the asset lifecycle, ranging from 6.4% to 11.3% of asset value, depending on the adoption scenario. Second, despite this potential, current market conditions lack mechanisms to formally recognize and capitalize on these digital elements, thereby limiting their diffusion. Third, the misalignment of incentives across stakeholders continues to be a critical barrier, calling for new contractual models and governance structures that ensure shared investment and shared benefit.
From a methodological standpoint, this study makes an original contribution by combining expert-based qualitative research with probabilistic financial modeling to simulate digital value creation in facility management. It introduces a pragmatic framework for linking digital innovation to investment criteria such as Net Present Value (NPV), potentially transforming how digital components are incorporated into financial evaluations.
To address uncertainty in projections, we employed Monte Carlo simulation using PERT distributions, which allowed us to incorporate variability in expert-derived inputs and obtain 90% confidence intervals for key output metrics. This approach captures the combined effects of multiple sources of uncertainty and provides a more realistic estimate of potential outcomes compared to deterministic models.
Nonetheless, certain limitations remain. Future research could build upon this foundation by applying more granular sensitivity analyses, such as variance-based techniques, or by introducing time-dependent stochastic processes to reflect dynamic factors such as market maturity, regulatory changes, or technology adoption trends. Additionally, the relatively small sample size and reliance on expert judgment introduce a degree of subjectivity, and the static nature of the current model limits its ability to reflect temporal evolution in digitalization impacts.
While the study is grounded in the Italian real estate context, the methodological approach, combining expert elicitation, standardized FM activity mapping, and probabilistic financial modeling, is designed to be transferable and can be adapted to other geographic markets with similar asset management structures, regulatory frameworks, and levels of digital maturity. By adjusting context-specific variables such as labor costs, inflation rates, and real estate valuation practices, the simulation model can support cross-market comparisons and inform digital investment decisions in a variety of national settings, particularly within the EU and other OECD countries.
Future research should aim to expand the scope of the analysis to a more diverse set of assets and geographical contexts. Longitudinal studies tracking digital adoption and cost performance over time would be particularly valuable, as would investigations into the integration of digital maturity indicators into investment risk profiles. Additionally, more work is needed to understand how digitalization influences other real estate dimensions, including asset liquidity, user satisfaction, and regulatory compliance. Ultimately, recognizing and monetizing the digital dimension of real estate assets represents both a technical and strategic frontier—one with the potential to redefine value creation in the AEC industry.

Author Contributions

Conceptualization, R.A., C.M., M.M. and E.A.; methodology, R.A., C.M. and E.A.; software, R.A.; validation, R.A., C.M. and E.A.; investigation, R.A., C.M. and E.A.; data curation, R.A.; Writing – Original Draft Preparation, R.A., E.A. and C.M.; writing—review and editing, E.A., C.M. and M.M.; Supervision, M.M.; Project Administration, M.M. All authors have read and agreed to the published version of the manuscript.

Funding

This research received no external funding.

Data Availability Statement

The dataset is available on request from the corresponding author.

Conflicts of Interest

The authors declare no conflicts of interest.

Appendix A

Table A1. Benefits and challenges selection responses.
Table A1. Benefits and challenges selection responses.
Benefits and Challenges by CategoryInterviewees Selection
FM1C2C3C4C5C8C10C11C9C6C7C12C13CCriterion 3Criterion 3%Criterion 2
FM integration into projects even since initial project phases, allowing FM improvement due to a higher level of information. 11 21311121 31 11754%22
Maintenance management, optimization, and maintenance requirements identification.3 112121 21111111 21862%30
Procurement precision, synchronization, and strategy optimization. 31 11 1131431%12
Bill of quantities precision 31 18%2
Lifecycle historical data2 21 1111 4 414 431%17
Elements tracking and specification availability11 4 41 21 323%9
Implementation of external logics and technologies utilization. 00%0
Continuous improvement and progress continuity 21 1131 323%9
Higher process automation 31 18%2
Asset tagging 4141 215%2
Better implementation of lean techniques 00%0
Integrate changes into the life cycle 41 3131 31214 538%11
Pull strategy favoring 00%0
RFiD support 00%0
Space management4 31 18%3
Documents’ quality, contract quality, and precision. 31 4 41 2121 4 431%11
TW
Information storage, exchange, efficiency, and management. Information request reduction and information loss reduction.11213 3 314 1111538%22
Collaboration and teamwork dynamics enhancement21 11114 1121 31 646%21
Communication improvement 21 213 11 323%12
Stakeholder classification, organization, role visualization, and responsibilities identification. 3 4 3 2118%8
Coordination and especially contractor-supplier 2111213 112121 646%22
Real-time information updating31 4 313 214 4 4 323%13
Remote information access 00%0
Quick approvals 00%0
Quick reaction to issues 11 211111 11214 31 754%25
Single source of information414 4 4 4 3 18%7
CC
Cost optimization, auditing, control, and estimation accuracy11111111111111214 112111111292%47
Accounting improvement and better budgeting2131212121312131313131312113100%32
Waste and overhead reduction314 313131213111214 1121311185%31
Results prediction4 214 4 414 4 4 11214 4 41538%20
HM
Marketing improvement, market opening, and competitive advantage gains.214 4 21214 114 3 4 114 4 538%26
Education on the project and a better learning curve112 2 1111113 3 112 2 1111754%44
Higher customer satisfaction and better customer service3 113 4 4 3 4 112 114 3 3 323%29
Staff recruiting improvement 4 00%1
Bid preparation time reduction and detail increase4 3 113 3 2 2 2 3 3 2 21215%30
DS
Real-time decision-making support. Scenario generation, optimization, and simulation.3131112 1131214121312141111292%34
Data analysis and management. Better and more structured data available.114 211121411111 4 1111311077%35
Risk assessment, reduction 11 31 1131 21538%15
Economical provisions and scalability. NPV increase and business value increase.4 21 21 21112141 646%18
Better change management 314 3111 214 431%13
Better use of supply chain knowledge. 4 3 31 18%5
Cloud computing support 4 00%1
Difficulties in anticipation21 4 31 4 215%7
Report generation 31 18%2
Forensic Analysis 00%0
SS
Safety and emergency evacuation improvement.4 21 3121 3 4 212111212 754%28
Energetic analysis tools, energy consumption monitoring, optimization, and savings.11314 4 11112111312111111077%36
Transparency, both internally in the company and with external parties. 4 4 2111314 4 323%13
Sustainability improvement and environmental impact control.211131213121 3 4 11 754%24
Real-time and remote CO2 monitoring.3 11 4 4 3 18%10
Real-time and remote temperature monitoring. 2111113 4 3 3 4 323%19
TM
Schedule reduction, compliance, and real-time schedule estimation/updates.4 3 4 3 21211111 113 21646%29
Planning optimization and work efficiency improvement.11111121 11 213 112121311077%36
4D visualization 21 1131114 114 538%19
Real-time monitoring and process status visualization213 4 4 3 213 3 4 11323%21
Activities visualization and parallelization. 4 112 4 18%9
Faster processes and cycle reduction.3121 3 4 4 31 4 214 431%16
PE
Exploit managers and workers’ knowledge also after the introduction of BIM. Match the new knowledge needed to utilize and exploit BIM with workers’/managers know-how and expertise.3 3 3121 112 3 3 3 323%22
Change of management, different flows of information, and roles and tasks after BIM implementation.2 213 113 3 3121 312 538%26
Top management commitment to the change of strategy and new approach to the facility management.1121 112121 21 21213 11969%32
Cultural resistance and employee training efforts. 1111 31 111111111111211077%37
PR
Large and complex amounts of data that must be managed, cloud solutions, databases, and creation of new specific measures. 2 21 21113 2 3121538%23
Lack of techniques to manage large sets of data and lack of quality in the information that should satisfy BIM implementation requirements or avoid unsatisfying empirical analysis. 31 11215%6
Uneven distribution of profits in the AEC industry at different supply chain stages.31 2 3 18%7
Lack of cooperation and collaboration between parties, which sums to a highly competitive maintenance sector.21 3 2121 113 1111 646%25
Obsolete business models not fully capturing BIM value.1111 1111 31 21 2 1131862%30
Updating of changes and new information. Not doing so might cost errors or sessions to control the correct status of information and data. 3 11313 1121 113 21 646%26
TE
Modeling and managing complex activities and flows. It might require specific software or modeling skills. 11 11 113 112 2 11538%28
System integration, need interoperability to allow dialogue between technological systems with diverse natures and related to different activities.11212 2 1111112111114 862%37
Link between databases, eventually with different formats and rules.3 313 3 3 3 21 313 3 323%21
Specific technology is needed for real-time data and information 2 2 2 2 00%12
Short-term investment magnitude. Hardware and software costs affect the investments.21 11 11 3 3 3 2 323%20
LE
Lack of BIM standards—the situation is improving, but still the government efforts towards a regulated digital facility management industry are not solid. This implies additional work to avoid problems in terms of bureaucracy and in the drafting of contracts.3 11113 3 2 11213 11213 11754%39
The amount of data to be managed is remarkable and often not possible to be hosted locally. It arises then the problem of data ownership and contract management in this perspective.2 3 2 2 2 3 3 3 113 11213 323%35
BIM methodology increases the addressing of responsibilities and specific roles inside projects. However, it is uncertain the coverage of issues and costs related to collaboration, for example, in situations of wrong exchange of data, information sharing, and model authoring. It is then unclear whether traditional contractor insurance policies are sufficient, or they need to be integrated with complete operation insurances to cover any inconvenience.112 3 1111112 11212 3 112 754%43
25 25 25 25 25 25 25 25 25 25 25 25 25
Table A2. Categories selection collected answers.
Table A2. Categories selection collected answers.
IntervieweesBenefitsChallenges
ID InterviewRole12345671234
1Property Sustainability and Process Improvement ManagerTWDSCCTMHMSSFMPRTEPELE
2Acquisition Analyst, Real EstateFMSSCCDSTMTWHMTEPEPRLE
3Head of Real Estate and LogisticsFMDSCCSSTWTMHMPEPRLETE
4Head of Real Estate and LogisticsCCFMSSDSHMTWTMPRPELETE
5Innovation Project ManagerFMCCSSTWTMHMDSPEPRLETE
6Transaction AnalystFMSSCCDSTMTWHMTEPEPRLE
7Project ManagerDSFMCCTWTMSSHMPELEPRTE
8Fund ManagerDSCCTMFMSSTWHMPRPELETE
9Property ManagerFMDSCCSSTWTMHMPRLEPETE
10ProfessorFMDSCCTMSSTWHMPRTELEPE
11ProfessorDSCCFMTWTMSSHMPELEPRTE
12Technical ManagerDSTWCCFMSSTMHMPRLEPETE
13R&D ManagerCSFMTMDSTWHMSSPRPELETE
Table A3. Categories selection scores.
Table A3. Categories selection scores.
BenefitsChallenges
CategoryFMDSCCSSTWTMHMPRPELETE
Score7469654644401942382723
Number of Attributes43332213211

References

  1. Munawar, H.S.; Qayyum, S.; Ullah, F.; Sepasgozar, S. Big Data and Its Applications in Smart Real Estate and the Disaster Management Life Cycle: A Systematic Analysis. Big Data Cogn. Comput. 2020, 4, 4. [Google Scholar] [CrossRef]
  2. Savills Total Global Value of Real Estate Estimated at $379.7 Trillion—Almost Four Times the Value of Global GDP. Available online: https://www.savills.com/insight-and-opinion/savills-news/352068/total-global-value-of-real-estate-estimated-at-$379.7-trillion---almost-four-times-the-value-of-global- (accessed on 2 May 2025).
  3. Pagourtzi, E.; Assimakopoulos, V.; Hatzichristos, T.; French, N. Real Estate Appraisal: A Review of Valuation Methods. J. Prop. Investig. Financ. 2003, 21, 383–401. [Google Scholar] [CrossRef]
  4. Hong, J.; Choi, H.; Kim, W. A House Price Valuation Based on the Random Forest Approach: The Mass Appraisal of Residential Property in South Korea. Int. J. Strateg. Prop. Manag. 2020, 24, 140–152. [Google Scholar] [CrossRef]
  5. Wang, S.; Zhu, J.; Yin, Y.; Wang, D.; Edwin Cheng, T.C.; Wang, Y. Interpretable Multi-Modal Stacking-Based Ensemble Learning Method for Real Estate Appraisal. IEEE Trans. Multimed. 2023, 25, 315–328. [Google Scholar] [CrossRef]
  6. Chiarazzo, V.; Caggiani, L.; Marinelli, M.; Ottomanelli, M. A Neural Network Based Model for Real Estate Price Estimation Considering Environmental Quality of Property Location. Transp. Res. Procedia 2014, 3, 810–817. [Google Scholar] [CrossRef]
  7. Abidoye, R.B.; Chan, A.P.C. Critical Determinants of Residential Property Value: Professionals’ Perspective. J. Facil. Manag. 2016, 14, 283–300. [Google Scholar] [CrossRef]
  8. Lindenthal, T.; Johnson, E.B. Machine Learning, Architectural Styles and Property Values. J. Real Estate Financ. Econ. 2021, 1–32. [Google Scholar] [CrossRef]
  9. Fuerst, F.; McAllister, P.; Murray, C.B. Designer Buildings: Estimating the Economic Value of ‘Signature’ Architecture. Environ. Plan A Econ. Sp. 2011, 43, 166–184. [Google Scholar] [CrossRef]
  10. Park, B.; Bae, J.K. Using Machine Learning Algorithms for Housing Price Prediction: The Case of Fairfax County, Virginia Housing Data. Expert Syst. Appl. 2015, 42, 2928–2934. [Google Scholar] [CrossRef]
  11. Case, K.E.; Shiller, R.J. Forecasting Prices and Excess Returns in the Housing Market. Real Estate Econ. 1990, 18, 253–273. [Google Scholar] [CrossRef]
  12. Jiang, L.; Phillips, P.C.B.; Yu, J. New Methodology for Constructing Real Estate Price Indices Applied to the Singapore Residential Market. J. Bank. Financ. 2015, 61, S121–S131. [Google Scholar] [CrossRef]
  13. Anenberg, E.; Laufer, S. A More Timely House Price Index. Rev. Econ. Stat. 2017, 99, 722–734. [Google Scholar] [CrossRef]
  14. Coenen, C.; Alexander, K.; Kok, H. Facility Management Value Dimensions from a Demand Perspective. J. Facil. Manag. 2013, 11, 339–353. [Google Scholar] [CrossRef]
  15. Nielsen, S.B.; Sarasoja, A.-L.; Galamba, K.R. Sustainability in Facilities Management: An Overview of Current Research. Facilities 2016, 34, 535–563. [Google Scholar] [CrossRef]
  16. van der Voordt, T. Facilities Management and Corporate Real Estate Management: FM/CREM or FREM? J. Facil. Manag. 2017, 15, 244–261. [Google Scholar] [CrossRef]
  17. Chotipanich, S. Positioning Facility Management. Facilities 2004, 22, 364–372. [Google Scholar] [CrossRef]
  18. Arampatzi, E.; Burger, M. Facility Management Services and Employee Well-Being. J. Facil. Manag. 2020, 18, 109–130. [Google Scholar] [CrossRef]
  19. Aziz, N.D.; Nawawi, A.H.; Ariff, N.R.M. Building Information Modelling (BIM) in Facilities Management: Opportunities to Be Considered by Facility Managers. Procedia Soc. Behav. Sci. 2016, 234, 353–362. [Google Scholar] [CrossRef]
  20. Kassem, M.; Kelly, G.; Dawood, N.; Serginson, M.; Lockley, S. BIM in Facilities Management Applications: A Case Study of a Large University Complex. Built Environ. Proj. Asset Manag. 2015, 5, 261–277. [Google Scholar] [CrossRef]
  21. Kouhestani, S.; Nik-Bakht, M. IFC-Based Process Mining for Design Authoring. Autom. Constr. 2020, 112, 103069. [Google Scholar] [CrossRef]
  22. Kim, S.; Chin, S.; Han, J.; Choi, C.-H. Measurement of Construction BIM Value Based on a Case Study of a Large-Scale Building Project. J. Manag. Eng. 2017, 33, 551. [Google Scholar] [CrossRef]
  23. Becerik-Gerber, B.; Jazizadeh, F.; Li, N.; Calis, G. Application Areas and Data Requirements for BIM-Enabled Facilities Management. J. Constr. Eng. Manag. 2012, 138, 431–442. [Google Scholar] [CrossRef]
  24. Mitera-Kiełbasa, E.; Zima, K. BIM Policy Trends in Europe: Insights from a Multi-Stage Analysis. Appl. Sci. 2024, 14, 4363. [Google Scholar] [CrossRef]
  25. Alam, F.; Ali, J.; Madni, S.; Husnain, H.A. Identifying Barriers to Effective BIM Adoption in the Re-Engineering of Construction Business Practices in Developing Countries. Preprints 2023, 2023051378. [Google Scholar]
  26. Chen, L.; Shi, P.; Tang, Q.; Liu, W.; Wu, Q. Development and Application of a Specification-Compliant Highway Tunnel Facility Management System Based on BIM. Tunn. Undergr. Sp. Technol. 2020, 97, 103262. [Google Scholar] [CrossRef]
  27. Benn, M.; Stoy, C. BIM for CREM: Exploring the Benefit of Building Information Modelling for Facility Management in Corporate Real Estate Management. Buildings 2022, 12, 400. [Google Scholar] [CrossRef]
  28. Doumbouya, L.; Gao, G.; Guan, C. Adoption of the Building Information Modeling (BIM) for Construction Project Effectiveness: The Review of BIM Benefits. Am. J. Civ. Eng. Archit. 2016, 4, 74–79. [Google Scholar] [CrossRef]
  29. Samimpay, R.; Saghatforoush, E. Benefits of Implementing Building Information Modeling (BIM) in Infrastructure Projects. J. Eng. Proj. Prod. Manag. 2020, 10, 123–140. [Google Scholar] [CrossRef]
  30. Hosseini, M.R.; Roelvink, R.; Papadonikolaki, E.; Edwards, D.J.; Pärn, E. Integrating BIM into Facility Management. Int. J. Build. Pathol. Adapt. 2018, 36, 2–14. [Google Scholar] [CrossRef]
  31. Kazado, D.; Kavgic, M.; Eskicioglu, R. Integrating Building Information Modeling (BIM) and Sensor Technology for Facility Management. J. Inf. Technol. Constr. 2019, 24, 440–458. [Google Scholar] [CrossRef]
  32. Sepasgozar, S.M.E.; Costin, A.M.; Karimi, R.; Shirowzhan, S.; Abbasian, E.; Li, J. BIM and Digital Tools for State-of-the-Art Construction Cost Management. Buildings 2022, 12, 396. [Google Scholar] [CrossRef]
  33. Baker, J. The Technology—Organization—Environment Framework. In Information Systems Theory; Springer: New York, NY, USA, 2012; pp. 231–245. [Google Scholar]
  34. Anker Jensen, P. The Facilities Management Value Map: A Conceptual Framework. Facilities 2010, 28, 175–188. [Google Scholar] [CrossRef]
  35. Baskerville, R.; Pries-Heje, J.; Venable, J. Soft Design Science Methodology. In Proceedings of the 4th International Conference on Design Science Research in Information Systems and Technology, Philadelphia, PA, USA, 7–8 May 2009. [Google Scholar] [CrossRef]
  36. Crowther, J.; Ajayi, S.O. Impacts of 4D BIM on Construction Project Performance. Int. J. Constr. Manag. 2021, 21, 724–737. [Google Scholar] [CrossRef]
  37. Li, X.; Zhang, Z.; Jim, C.Y.; Lai, J.; Chen, X. Owner-Based Benefit Evaluation of BIM Applications in China’s Engineering Projects. Eng. Constr. Archit. Manag. 2022, 30, 4387–4414. [Google Scholar] [CrossRef]
  38. BIMVET3. The BIM Methodology Application in Public Procurement Tenders. 2025. Available online: https://bimvet3.eu/courses/bim-tenders-for-projects-and-public-works-and-bim-implementation-processes/lessons/the-bim-methodology-application-in-public-procurement-tenders/ (accessed on 28 May 2025).
  39. Li, S.T.; Chiu, K.C.; Chiu, T.H. An Application on Building Information Model to Procurement Strategy of Copper Raw Material with Big Data Analytics. In Proceedings of the 2020 IEEE International Conference on Industrial Engineering and Engineering Management, Singapore, 14–17 December 2020; pp. 696–700. [Google Scholar] [CrossRef]
  40. Yalcinkaya, M.; Singh, V. Building Information Modeling (BIM) for Facilities Management—Literature Review and Future Needs In Product Lifecycle Management for a Global Market. In Proceedings of the 11th IFIP WG 5.1 International Conference, PLM 2014, Yokohama, Japan, 7–9 July 2014; Fukuda, S., Bernard, A., Gurumoorthy, B., Bouras, A., Eds.; Springer: Cham, Switzerland, 2014; pp. 1–10. [Google Scholar]
  41. Bensalah, M.; Elouadi, A.; Mharzi, H. Overview: The Opportunity of BIM in Railway. Smart Sustain. Built Environ. 2019, 8, 103–116. [Google Scholar] [CrossRef]
  42. Gaur, S.; Tawalare, A. Investigating the Role of BIM in Stakeholder Management: Evidence from a Metro-Rail Project. J. Manag. Eng. 2022, 38, 979. [Google Scholar] [CrossRef]
  43. Chahrour, R.; Hafeez, M.A.; Ahmad, A.M.; Sulieman, H.I.; Dawood, H.; Rodriguez-Trejo, S.; Kassem, M.; Naji, K.K.; Dawood, N. Cost-Benefit Analysis of BIM-Enabled Design Clash Detection and Resolution. Constr. Manag. Econ. 2021, 39, 55–72. [Google Scholar] [CrossRef]
  44. Lima, C.M.; Ferreira, E.A.M.; Calmon, J.L. Bim and Iot Integration To Support Management Processes: An Application for Precast Concrete Systems. J. Mod. Proj. Manag. 2021, 10, 237–251. [Google Scholar] [CrossRef]
  45. Bensalah, M.; Elouadi, A.; Mharzi, H. Optimization of Cost of a Tram Through the Integration of Bim: A Theoretical Analysis. Int. J. Mech. Prod. Eng. 2017, 5, 138–142. [Google Scholar]
  46. Yilmaz, G.; Akcamete, A.; Demirors, O. BIM-CAREM: Assessing the BIM Capabilities of Design, Construction and Facilities Management Processes in the Construction Industry. Comput. Ind. 2023, 147, 103861. [Google Scholar] [CrossRef]
  47. Sanchez, A.; Joske, W. Benefits Dictionary; Routledge: London, UK, 2016; pp. 103–204. ISBN 978-1-138-11899-7. [Google Scholar]
  48. European Innovation Council and SMEs Executive Agency (EISMEA). Calculating Costs and Benefits for the Use of Building Information Modeling in Public Tenders—Methodology Handbook; European Commission: Brussels, Belgium, 2021; ISBN 9789294606440. [Google Scholar]
  49. Azhar, S. Building information modeling (BIM): Trends, benefits, risks, and challenges for the AEC industry. Leadersh. Manag. Eng. 2011, 11, 241–252. [Google Scholar] [CrossRef]
  50. Neelamkavil, J.; Ahamed, S. The Return on Investment from BIM-Driven Projects in Construction. Natl. Res. Counc. Canada 2012, 1–28. [Google Scholar] [CrossRef]
  51. Love, P.E.D.; Simpson, I.; Hill, A.; Standing, C. From Justification to Evaluation: Building Information Modeling for Asset Owners. Autom. Constr. 2013, 35, 208–216. [Google Scholar] [CrossRef]
  52. McGraw Hill Construction. The Business Value of BIM in North America; McGraw Hill Construction: Hamilton Township, NJ, USA, 2012; ISBN 1800591446. [Google Scholar]
  53. Sompolgrunk, A.; Banihashemi, S.; Hosseini, M.R.; Golzad, H.; Hajirasouli, A. An Integrated Model of BIM Return on Investment for Australian Small- and Medium-Sized Enterprises (SMEs). Eng. Constr. Archit. Manag. 2022, 30, 2048–2074. [Google Scholar] [CrossRef]
  54. Myungdo, L.; Ung-Kyun, L. A Framework for Evaluating an Integrated Bim Roi Based on Preventing Rework in the Construction Phase. J. Civ. Eng. Manag. 2020, 26, 410–420. [Google Scholar] [CrossRef]
  55. Jin, R.; Hancock, C.M.; Tang, L.; Wanatowski, D. BIM Investment, Returns, and Risks in China’s AEC Industries. J. Constr. Eng. Manag. 2017, 143, 04017089. [Google Scholar] [CrossRef]
  56. Lu, K.; Deng, X.; Jiang, X.; Cheng, B.; Tam, V.W.Y. A Review on Life Cycle Cost Analysis of Buildings Based on Building Information Modeling. J. Civ. Eng. Manag. 2023, 29, 268–288. [Google Scholar] [CrossRef]
  57. Zeng, N.; Ye, X.; Liu, Y.; König, M. BIM-Enabled Kanban System in Construction Logistics for Real-Time Demand Reporting and Pull Replenishment. Eng. Constr. Archit. Manag. 2023, 31, 3069–3096. [Google Scholar] [CrossRef]
  58. Yu, J.; Wang, J.; Hua, Z.; Wang, X. BIM-Based Time-Cost Optimization of a Large-Span Spatial Steel Structure in an Airport Terminal Building. J. Facil. Manag. 2022, 20, 469–484. [Google Scholar] [CrossRef]
  59. João, M.; Silva, F.; Couto, P. Methodology Asset Management; Springer International Publishing: Berlin/Heidelberg, Germany, 2021; ISBN 9783030355333. [Google Scholar]
  60. Jofre, C.; Muñoz La Rivera, F.; Atencio, E.; Herrera, R.F. Implementation of Facility Management for Port Infrastructure through the Use of UAVs, Photogrammetry and BIM. Sensors 2021, 21, 6686. [Google Scholar] [CrossRef]
  61. Munir, M.; Kiviniemi, A.; Jones, S.; Finnegan, S. BIM Business Value for Asset Owners: Key Issues and Challenges. Int. J. Build. Pathol. Adapt. 2021, 39, 135–151. [Google Scholar] [CrossRef]
  62. Wang, Z.; Ma, J. Understanding the Effects of BIM Implementation in Corporation Finance: An Empirical Study in China. Organ. Technol. Manag. Constr. 2021, 13, 2484–2495. [Google Scholar] [CrossRef]
  63. Chen, X.; Qi, W.; Hu, W. Cost-Effective Analysis and Calculation of Energy Performance Using Insight Tool in BIM. In Proceedings of the 2022 IEEE 2nd International Conference on Electronic Technology, Communication and Information, Changchun, China, 27–29 May 2022; pp. 889–891. [Google Scholar] [CrossRef]
  64. Pedral Sampaio, R.; Aguiar Costa, A.; Flores-Colen, I. A Discussion of Digital Transition Impact on Facility Management of Hospital Buildings. Facilities 2023, 41, 389–406. [Google Scholar] [CrossRef]
  65. Collantes, R.; Portilla, J.; Rodriguez, S.; Garcia, F. Time and Cost Reduction in the Production Chain of Construction Projects through Collaborative Computer Systems. In Proceedings of the 2020 Congreso Internacional de Innovación y Tendencias en Ingeniería, Bogota, Colombia, 30 September–2 October 2020. [Google Scholar] [CrossRef]
  66. Bereman, M.; Fitzgerald, B.; Blanco, J.L.; Mattik, I.; Sjödin, E. Building Products in the Digital Age: It’s Hard to ‘Get Smart’. 2022. Available online: https://www.mckinsey.com/industries/engineering-construction-and-building-materials/our-insights/building-products-in-the-digital-age-its-hard-to-get-smart#/ (accessed on 28 May 2025).
  67. Rodrigues, H.; Gaspar, F.; Fernandes, P.; Mateus, A. (Eds.) Sustainability and Automation in Smart Constructions. Advances in Science, Technology & Innovation; Springer International Publishing: Cham, Switzerland, 2021; ISBN 978-3-030-35532-6. [Google Scholar]
  68. Agarwal, G.; Chandrasekaran, S.; Sridhar, M. Imagining Construction’s Digital Future. Cap. Proj. Infrastruct. 2016. [Google Scholar]
  69. Asare, K.A.B.; Issa, R.R.A.; Liu, R.; Anumba, C. BIM for Facilities Management: Potential Legal Issues and Opportunities. J. Leg. Aff. Disput. Resolut. Eng. Constr. 2021, 13, 502. [Google Scholar] [CrossRef]
  70. Mckinsey: Blanco, J.L.; Rockhill, D.; Sanghvi, A.; Torres, A. From Start-up to Scale-up: Accelerating Growth in Construction Technology. 2023. Available online: https://www.mckinsey.com/industries/private-capital/our-insights/from-start-up-to-scale-up-accelerating-growth-in-construction-technology#/ (accessed on 28 May 2025).
  71. Apel, F.; Boland, B.; de la Motte, H.; Moore, A.; Reiter, S.; Sjödin, E. Accelerating Green Growth in the Built Environment. Available online: https://www.mckinsey.com/capabilities/operations/our-insights/accelerating-green-growth-in-the-built-environment#/ (accessed on 30 May 2025).
  72. Arayici, Y.; Onyenobi, T.; Egbu, C. Building Information Modelling (BIM) for Facilities Management (FM). Int. J. 3-D Inf. Model. 2012, 1, 55–73. [Google Scholar] [CrossRef]
  73. Atkin, B.; Brooks, A. Total Facility Management; Wiley: Hoboken, NJ, USA, 2021; ISBN 9781119707967. [Google Scholar]
  74. Rowley, J. Conducting Research Interviews. Manag. Res. Rev. 2012, 35, 260–271. [Google Scholar] [CrossRef]
  75. Alshenqeeti, H. Interviewing as a Data Collection Method: A Critical Review. Engl. Linguist. Res. 2014, 3, 1–7. [Google Scholar] [CrossRef]
  76. Rosenthal, M. Qualitative Research Methods: Why, When, and How to Conduct Interviews and Focus Groups in Pharmacy Research. Curr. Pharm. Teach. Learn. 2016, 8, 509–516. [Google Scholar] [CrossRef]
  77. Mathers, N.J.; Fox, N.J.; Hunn, A.; Group, T.F. Using Interviews in a Research Project; NHS Executive, Trent: London, UK, 1998; p. SE-31. [Google Scholar]
  78. Palisade @RISK 8—Guía de Inicio ¡Bienvenido. Available online: https://help.palisade.com/v8_2/es/Guides/@RISK-Getting-Started-Guide.pdf (accessed on 2 May 2025).
  79. ISTAT Instituto Nazionale di Statistica. Available online: https://www.istat.it/ (accessed on 19 May 2025).
Buildings 15 01920 g001
Figure 1. Research method.
Figure 1. Research method.
Buildings 15 01920 g001
Buildings 15 01920 g002
Figure 2. @Risk output for the different variables.
Figure 2. @Risk output for the different variables.
Buildings 15 01920 g002
Buildings 15 01920 g003
Figure 3. Benefits cost reduction.
Figure 3. Benefits cost reduction.
Buildings 15 01920 g003
Table 1. Benefits’ categories.
Table 1. Benefits’ categories.
Benefit CategoryDescriptionRelated Articles
Improved Construction ManagementBIM significantly enhances the construction phase through precise control of sequencing, material requirements, and on-site operations. It enables proactive clash detection and quality assurance from the design stage, reducing rework and elevating deliverable quality. It supports real-time monitoring and resource optimization—improving material logistics, minimizing shortages and waste, and expediting compliance reviews. It prevents delays, reduces errors, and ensures alignment with project specifications.[29,31,39,41,42,43,44,45,46,47,48,49,50,51,52,53,54,55,56,57,58]
Improved Facility ManagementBIM transforms facility management by embedding detailed specifications and historical data into the asset model from project inception. This enables automated maintenance through asset tagging and sensor integration, facilitating localization, monitoring, and condition-based interventions. BIM integration supports predictive and preventive maintenance planning, optimizes long-term operations, and ensures traceability of interventions.[29,31,36,39,41,42,44,45,47,48,49,51,52,57,59,60,61]
Costs CognitionBIM improves cost awareness and control by enhancing estimation accuracy, forecasting capabilities, and financial tracking. It has the ability to store and process large datasets, supports waste reduction, overhead management, and detailed budget analysis. This leads to more reliable project accounting and improved lifecycle cost optimization.[29,37,39,41,42,43,45,47,48,49,50,51,52,53,55,56,57,58,62,63,64,65]
TeamworkBIM fosters strong collaboration across multidisciplinary teams by providing a shared information environment. BIM further supports collaboration by offering centralized data repositories with real-time and remote access. Stakeholders can be clearly assigned roles and responsibilities, improving coordination and responsiveness across all lifecycle stages.[29,31,36,37,41,42,43,44,47,48,50,52,53,55,56,57,58,59,60,64]
Time ManagementBIM enables integrated scheduling and real-time project monitoring through 4D modeling. By aligning timelines with critical milestones and constantly updating data, it reduces cycle times, mitigates delays, and identifies process bottlenecks. This leads to improved on-time delivery and proactive deadline management.[29,36,41,42,45,47,48,49,50,51,52,53,54,55,57,62,65,66]
Decision Support BIM enhances decision-making by providing structured, real-time data and analytics. It supports scenario modeling, risk analysis, and investment evaluations (e.g., NPV). Documented decision histories improve future planning and enable more adaptive, data-driven management throughout the building lifecycle.[36,37,39,41,44,47,48,50,57,59,60,63]
Sustainability and SafetyBIM enables advanced monitoring of energy performance and indoor environmental quality all over the building lifecycle. Sensors embedded in the built environment track emissions, temperature, and energy consumption. BIM introduces transparency and traceability into project development, reinforcing ESG goals and improving health and safety protocols.[31,37,41,44,47,48,49,50,53,54,55,56,63]
Human and Stakeholder ManagementBIM supports stakeholder engagement by improving user satisfaction and service quality through personalized data insights. It facilitates targeted communication, employee development, and knowledge transfer. It supports outside accountability. Internally, it boosts team morale and supports continuous learning, contributing to workforce retention and competence.[3,12,15,17,20,25,31]
Table 2. Challenge categories.
Table 2. Challenge categories.
Challenge CategoryDescriptionRelated Articles
Challenges related to peopleThe shift to BIM requires a fundamental rethinking of roles, responsibilities, and communication flows. Digitalization reduces interpersonal interactions, flattens hierarchies, and calls for updated leadership and management models. A key challenge is cultural resistance from employees accustomed to traditional workflows, often resulting in reluctance to adopt new tools. [41,42,49,51,52,55,60,61,70]
Challenges related to processesBIM disrupts conventional operations processes, especially in data and information management. The volume and complexity of data require new workflows, skill sets, and systems for processing, querying, and visualization. Inadequate data handling can lead to inefficiencies, errors, and costly rework. Furthermore, achieving full value from BIM requires collaboration among stakeholders—often hindered by siloed mindsets, lack of trust, and imbalanced value distribution along the supply chain. These issues are especially critical in later lifecycle phases such as operations and FM, where data continuity is essential but underfunded.[42,45,49,51,52,55,59,60,61,66,70,71]
Challenges related to technologyBIM requires integration of multiple technological components to ensure interoperability, data standardization, and real-time communication. Challenges include ensuring compatibility between software systems, implementing cloud-based platforms, and securing sufficient computational infrastructure. For large or complex projects, additional technologies such as sensors or IoT devices may be needed. The cost of acquiring and maintaining these tools, particularly for SMEs, represents a significant short-term barrier to adoption.[42,45,49,51,52,55,59,60,61,66,70,71]
Challenges related to legal issuesThe use of BIM introduces greater role clarity but also raises legal uncertainties around data ownership, liability, and insurance coverage. Issues such as model authorship, data misuse, or flawed information exchanges create contractual ambiguities—especially relevant during collaboration across stakeholders. In countries lacking standardized BIM regulations, these concerns are amplified. Drafting clear and comprehensive contracts that explicitly address responsibilities, risks, and data governance is essential, particularly for long-term use cases in facility management.[41,46,49,51,55,69,70,71]
Table 3. Activities and tasks related to the facility management field.
Table 3. Activities and tasks related to the facility management field.
IDActivity
1Inspection and maintenance of building structures (concrete, steel, beams, wood, floors, stairs, etc.)
2Inspection and maintenance of facades and enclosures (windows, doors, insulation, roofing, siding, flooring, etc.)
3Electrical system inspection and maintenance
4Inspection and maintenance of elevators and/or hoists, automated systems/escalators
5Thermal system control and maintenance (heating, air conditioning, maintaining specific temperatures, etc.)
6Inspection and maintenance of water and sanitation systems (tanks, pipes, sewers, downspouts, etc.)
7Gas system inspection and maintenance
8Inspection and maintenance of security systems
9Inspection and maintenance of fire protection systems
10Inspection and control of seismic systems
11Control and maintenance of surveillance systems (video cameras, surveillance, alarms, sensors, etc.)
12Management and control of resources and objects’ movements within the building
13Accesses, authorizations, and personnel management
14Production machinery control and maintenance (resources related to primary activities)
15Office material procurement
16Procurement of specific production materials (raw materials, machine consumables, etc.)
17Management and control of ordinary and extraordinary activities related to warehouse and storage space
18Cleaning spaces (ordinary, extraordinary, technical spaces, pest control, possibly sanitization and sterilization, etc.)
19Outdoor space maintenance management
20Special waste management and control
21Establishment and management of workstations and furniture
22Progressive space upgrade and renovation (not primary items but related to progressive improvement as needed. New computers, newer instrumentation, and replacement of components even if working to improve spaces, etc.)
23Information systems control and management
24Utility management and optimization
25Customer contact management and control (call center, front desk, services, etc.)
Table 4. Interviews’ objectives.
Table 4. Interviews’ objectives.
ObjectiveDescription
1Digitalization’s main benefits and challengesThe first objective was to validate the relevance of benefits and challenges identified in international literature within the Italian market context, which remains underrepresented in existing research. This phase helped assess which digitalization impacts are experienced by professionals and if any new specific themes emerged.
2Benefits and challenges’ financial impact estimationExperts were asked to quantify the economic value of selected benefits and challenges, expressed as a percentage of facility management-related costs. This aimed to estimate potential cost savings and value loss resulting from the use or non-use of BIM in the operational phase of real estate assets.
3Value recognitionThis phase explored how professionals perceive the value created by BIM implementation and which internal metrics or processes they use to identify and assess this value over time.
4Benefits and challenges’ final sample selectionFinally, participants were asked to select and rank the most significant benefits and challenges using a standardized Excel tool. This helped narrow down the wide range of items from the literature to a manageable and relevant set of variables for further analysis.
Table 5. Interview’s question structure.
Table 5. Interview’s question structure.
SectionObjectiveKey Topics/Questions
1. General informationContextualize respondent profile
-
Name, education, job role, and digitalization/BIM/DT experience
2. Digitalization maturityUnderstand current and planned digital adoption
-
Maturity level of digitalization, types of BIM/DT solutions, and FM processes involved
3. Reported benefits/challengesIdentify experienced impacts (positive or negative)
-
Benefits or challenges encountered, key affected processes, and economic impact areas
4. Benefit seekingAssess needs and expectations from digitalization
-
Target processes for digitalization, data availability goals, and expected benefits
5. Challenges to overcomePinpoint remaining digitalization obstacles
-
Unavailable or insufficient data, process inefficiencies, and organizational barriers
6. Economic impactQuantify potential/realized financial impacts
-
Cost reduction % impact on FM, link to asset valuation, and forecasts on ROI
7. Selection and prioritizationRank most relevant benefits and challenges
-
Excel-based scoring of benefits/challenges and final sample selection for further analysis
Table 6. Candidates’ roles.
Table 6. Candidates’ roles.
Total Number of Interviews13
Finance RolesOperation RolesAcademics
3–23%8–62%2–15%
Fund ManagerHead of Real Estate and LogisticsProfessor
Transaction AnalystProperty Sustainability and Process Improvement Manager
Acquisition AnalystInnovation and R&D Project Manager
Project Manager
Property Manager
Technical Manager
Table 7. Experts’ opinion summary.
Table 7. Experts’ opinion summary.
CandidateDT SolutionsBIMCombination of BIM and DT
1 - OYES - (YES)YES - (NO)PLUS—opportunities for current activities
2 - FYES - (NO)YES - (NO)PLUS—new opportunities
3 - OYES - (YES)NO - (NO)NO CHANGE—support to different activities
4 - OYES - (YES)YES - (NO)PLUS—new opportunities and improvements
5 - OYES - (YES)YES - (NO)PLUS—new opportunities and improvements
6 - FYES - (NO)NO - (NO)PLUS—information and support quality
7 - OYES - (YES)YES - (NO)PLUS—opportunities for current activities
8 - FYES - (YES)YES - (YES)PLUS—real advantage
9 - OYES - (YES)YES - (YES)PLUS—real advantage
10 - AYES - (YES)YES - (YES)PLUS—new opportunities and improvements
11 - AYES - (YES)YES - (YES)PLUS—new opportunities and improvements
12 - OYES - (YES)YES - (YES)PLUS—real advantage
13 - OYES - (YES)YES - (YES)PLUS—real advantage
Table 8. Final sample of benefits and challenges.
Table 8. Final sample of benefits and challenges.
Benefits and Challenges’ VoicesCriterion
33%2
FM1Maintenance management, optimization, and maintenance requirements identification.862%30
2FM integration into projects even since initial project phases, allowing FM improvement due to a higher level of information.754%22
3Integrate changes into the life cycle.538%11
4Lifecycle historical data.431%17
DS5Real-time decision-making support. Scenario generation, optimization, and simulation.1292%34
6Data analysis and management. Better and more structured data available.1077%35
7Economical provisions and scalability. NPV increase and business value increase.646%18
CC8Accounting improvement, better budgeting.13100%32
9Cost optimization, auditing, control, and estimation accuracy.1292%47
10Waste and overhead reduction.1185%31
SS11Energetic analysis tools, energy consumption monitoring, optimization, and savings.1077%36
12Safety and emergency evacuation improvement.754%28
13Sustainability improvement and environmental impact control.754%24
TW14Quick reaction to issues.754%25
15Coordination, especially contractor-supplier.646%22
TM16Planning optimization and work efficiency improvement.1077%36
17Schedule reduction, compliance, and real-time schedule estimation/updates.646%29
HM18Education on the project and a better learning curve.754%44
PR19Obsolete business models not fully capturing BIM value.862%30
20Updating of changes and new information. Not doing so might cost errors or sessions to control the correct status of information and data.646%26
21Lack of cooperation and collaboration between parties, which sums to a highly competitive maintenance sector.646%25
PE22Cultural resistance and employee training efforts.1077%37
23Top management commitment to the change of strategy and new approach to the facility management.969%32
LE24BIM methodology increases the addressing of responsibilities and specific roles inside projects. However, it is uncertain the coverage of issues and costs related to collaboration, for example, in situations of wrong exchange of data, information sharing and model authoring. It is then unclear whether traditional contractor insurance policies are sufficient, or they need to be integrated with complete operation insurances to cover any inconvenience.754%43
TE25System integration, needs interoperability to allow dialogue between technological systems with diverse natures and related to different activities.862%37
Table 9. Quantified benefits and challenges.
Table 9. Quantified benefits and challenges.
Facility Management ActivitiesBenefit or Challenge Voice Number
14111516172022
Inspection and maintenance of building structures (concrete, steel, beams, wood, floors, stairs, etc.)XX XXX X
Inspection and maintenance of facades and enclosures (windows, doors, insulation, roofing, siding, flooring, etc.)XX XXX X
Electrical system inspection and maintenanceXX XXX X
Inspection and maintenance of elevators and/or hoists, automated systems/escalatorsXXXXXX X
Thermal system control and maintenance (heating, air conditioning, maintaining specific temperatures, etc.)XXXXXX X
Inspection and maintenance of water and sanitation systems (tanks, pipes, sewers, downspouts, etc.)XX XXX X
Gas system inspection and maintenanceXXXXXX X
Inspection and maintenance of security systemsXX XXX X
Inspection and maintenance of fire protection systemsXX XXX X
Inspection and control of seismic systemsXX XXX X
Control and maintenance of surveillance systems (video cameras, surveillance, alarms, sensors, etc.)XX XXX X
Management and control of resources and objects’ movements within the building X XXX X
Accesses, authorizations and personnel management X XX X
Production machinery control and maintenance (resources related to primary activities) X XXX X
Office materials procurement X XX X
Procurement of specific production materials (raw materials, machine consumables, etc.) X XX X
Management and control of ordinary and extraordinary activities related to warehouse and storage space X XX X
Cleaning spaces (ordinary, extraordinary, technical spaces, pest control, possibly sanitization and sterilization, etc.) X XXX X
Outdoor space maintenance managementXX XXX X
Special waste management and control X XXX X
Establishment and management of workstations and furnitureXX X X
Progressive space upgrade and renovation (items not primary but related to progressive improvement as needed. New computers, newer instrumentation, and replacement of components even if working to improve spaces) X XX X
Information systems control and management X XXX X
Utility management and optimization XXXX X
Customer contact management and control (call center, front desk, services, etc.) X X X
Disclaimer/Publisher’s Note: The statements, opinions and data contained in all publications are solely those of the individual author(s) and contributor(s) and not of MDPI and/or the editor(s). MDPI and/or the editor(s) disclaim responsibility for any injury to people or property resulting from any ideas, methods, instructions or products referred to in the content.

Share and Cite

MDPI and ACS Style

Atencio, E.; Mariani, C.; Accettulli, R.; Mancini, M. Monetizing Digital Innovation in the AEC Industry: Real Estate Value Creation Through BIM and BMS Integration. Buildings 2025, 15, 1920. https://doi.org/10.3390/buildings15111920

AMA Style

Atencio E, Mariani C, Accettulli R, Mancini M. Monetizing Digital Innovation in the AEC Industry: Real Estate Value Creation Through BIM and BMS Integration. Buildings. 2025; 15(11):1920. https://doi.org/10.3390/buildings15111920

Chicago/Turabian Style

Atencio, Edison, Costanza Mariani, Riccardo Accettulli, and Mauro Mancini. 2025. "Monetizing Digital Innovation in the AEC Industry: Real Estate Value Creation Through BIM and BMS Integration" Buildings 15, no. 11: 1920. https://doi.org/10.3390/buildings15111920

APA Style

Atencio, E., Mariani, C., Accettulli, R., & Mancini, M. (2025). Monetizing Digital Innovation in the AEC Industry: Real Estate Value Creation Through BIM and BMS Integration. Buildings, 15(11), 1920. https://doi.org/10.3390/buildings15111920

Note that from the first issue of 2016, this journal uses article numbers instead of page numbers. See further details here.

Article Metrics

Back to TopTop