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Article

BIM Roles and Responsibilities in Developing Countries: A Dedicated Matrix for Design-Bid-Build Projects

by
Um E Hani Habib
1,
Abdur Rehman Nasir
1,*,
Fahim Ullah
2,*,
Siddra Qayyum
2,3 and
Muhammad Jamaluddin Thaheem
4
1
Department of Construction Engineering and Management, School of Civil and Environmental Engineering (SCEE), National University of Sciences and Technology (NUST), Islamabad 44000, Pakistan
2
School of Surveying and Built Environment, University of Southern Queensland, Springfield, QLD 4300, Australia
3
School of Built Environment, University of New South Wales, Sydney, NSW 2052, Australia
4
Geelong Waterfront Campus, School of Architecture and Built Environment, Deakin University, Locked Bag 20001, Geelong, VIC 3220, Australia
*
Authors to whom correspondence should be addressed.
Buildings 2022, 12(10), 1752; https://doi.org/10.3390/buildings12101752
Submission received: 25 August 2022 / Revised: 14 October 2022 / Accepted: 17 October 2022 / Published: 20 October 2022
(This article belongs to the Section Construction Management, and Computers & Digitization)
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Abstract

:
Building information modeling (BIM) through data-rich digital representation has revolutionized the architecture, engineering, and construction (AEC) industry. BIM implementation in the AEC industry has noticeably increased over the last decade. Various BIM roles have been discussed in the literature to ease the process of BIM implementation, but the BIM roles related to project delivery methods have not been standardized. Stimulated by this need, this study develops a BIM roles and responsibilities matrix (BIM-R&R) in the context of the design−bid−build (DBB) projects for developing countries. A comprehensive literature review has been conducted, followed by a questionnaire survey comprising 105 responses. The results were analyzed to formulate a BIM-R&R matrix, on which the expert opinion was obtained from the BIM experts. The proposed BIM-R&R matrix describes all the roles and their corresponding responsibilities required along the project life cycle phases of DBB projects. The incorporation of BIM roles in the DBB procurement process will aid in the efficient management of all information and data that may be lost due to the fragmented nature of DBB. BIM roles with enhanced communication and coordination will also help in reducing time and cost overruns while maintaining a high-quality product. This study helps the associated construction industry in its efforts to implement BIM on their projects by providing a method by which to assess which BIM roles are necessary. Moreover, it will provide project and construction managers with a clear understanding of the BIM roles in DBB projects.

1. Introduction

The construction industry is characterized by uncertainty due to the intricate nature of its projects [1]. To deal with the increasing intricacy of construction projects, adopting new and emerging technologies, specifications, contracting, and delivery methods have become essential [2]. Building information modeling (BIM) is among such promising technological developments that have the potential to address the challenges of the construction industry [3]. BIM provides a set of technologies and solutions aimed at improving interorganizational collaboration [4], enhancing construction quality [3,5,6], safety [6,7], sustainability [5,6], and efficiency [6,8]. In addition, BIM results in increased productivity and better design, construction, and maintenance practices [4]. Overall, BIM is a process integrated with software that influences organizational practices [9]. Comprising all the graphical and non-graphical data, BIM ensures integrating information, data management, simulations, and analysis efforts for enhanced coordination and communication among project members [10].
Recently, BIM implementation has noticeably increased in developed countries [11,12]. Compared to other countries, the US and the UK are leading BIM adoption [13]. The adoption rate of BIM in the UK was 13% in 2011 and has increased to 69% by 2019 [11]. BIM implementation in Singapore stands at 50% [14]. In Germany, the adoption rate of BIM has reached 90% [12]. To adopt and implement BIM, international BIM specifications like publicly available specifications [15] and international organization for standardization [16] have been developed to provide specific guidance on project delivery.
Similarly, the BIM knowledge and skills framework developed by the Australian Construction Industry Forum (ACIF) provides information on the necessary skills and education for BIM implementation [17]. Likewise, several guides have been created that define the key BIM roles required for successful BIM implementation [18,19,20,21]. As an example, the New Zealand BIM handbook incorporates the role of the BIM manager [20]. At the same time, BIM-Belgian Guide for the construction industry outlines the role of the BIM process manager and BIM discipline manager [18]. Similarly, Hong Kong BIM project specification indicates BIM project manager as an important role [19]. Furthermore, each guide has developed BIM roles according to their specific usage. However, no similar BIM role title is used in the abovementioned guides. Furthermore, an important role of the BIM modeler is also missing in these guides.
Despite being adopted rapidly in developed countries [22,23], developing countries’ construction industry faces challenges in BIM implementation [5,22]. Among the major challenges involved, rigid traditional work processes [10,22,24], insufficient knowledge of work practices [10,25], and extensive financing in guidance and skill needed for BIM [10,22] are common. Another key challenge is the insufficient understanding of the BIM roles and responsibilities (BIM-R&R) in the construction industries of developing countries [3,10]. Consequently, developing countries are unaware of the relevant BIM-R&R on projects. Furthermore, most developing countries use traditional project delivery methods such as design-bid-build (DBB) instead of adopting new methods [26]. Traditional delivery methods make it harder to deploy BIM because BIM-R&Rs are not defined. Thus, standardization of BIM-R&R for DBB will help better understand BIM actor roles, providing a clearer definition regarding who performs what task and who is responsible for what activity on the project. This will eventually help identify the appropriate BIM personnel for BIM-enabled projects. Consequently, this can be extended to other project types in developing countries.
Worldwide, BIM implementation has caused a change in customary project roles and positions [27]. For example, in BIM-based projects, the client needs to focus their efforts on establishing the BIM process and ways to use BIM while the contractor develops digital models by using BIM tools [28]. Similarly, the architect’s role is also affected due to the use of lifecycle management principles in the design process [29]. Moreover, BIM deployment has also resulted in new work practices, roles, and responsibilities [30]. Accordingly, new roles such as BIM manager, BIM coordinator, model manager, BIM modeler, and BIM technicians have been created.
Several studies have been conducted in the past on various BIM roles. Following a thorough literature review, several BIM-related roles like BIM manager, BIM facilitator, BIM modeler, modeling specialist, etc., were summarized in a study by [31]. Sebastian [29] stressed the need for a model manager as the new role within a BIM project, to provide and maintain the technological solutions required for BIM process, manage the information flow, and help stakeholders to improve their information technology skills. Similarly, Bosch-Sijtsema and Gluch [32] discussed the roles and actions of the BIM coordinator and the BIM manager in the Swedish construction industry to support the use and implementation of BIM. Another corresponding study analyzed various online BIM jobs in which 35 different BIM-related job titles were found to have distinct responsibilities [33]. Furthermore, Davies et al. [34] explained how the BIM actor roles are defined in different BIM guides and handbooks. Overall, the literature has been highly encouraging on establishing new positions such as BIM manager, BIM coordinator, BIM modeler, and BIM strategist [30]. These BIM actors can be part of the client, architect, and contractor firms [3,35]. BSI PAS [15] highlights multiple new roles and their responsibilities for information management, such as task information manager, task team manager, interface manager, and information originator. BIM roles are evolving [27], and numerous BIM titles are available nowadays in different countries [36]. This shows a difference in the development and definition of BIM roles in the industry across countries [30].
Furthermore, BIM-professional roles are being implemented in the AEC industry as envisaged by [34]. However, these newly developed BIM-R&R are contrasting and indistinct, and the BIM professionals’ role description needs to be standardized for holistic adoption [30]. This variation regarding BIM roles causes vagueness and confusion in project teams and organizations [34]. In an attempt to observe the changes that BIM brings in an organization in developing countries, such as the Brazilian construction industry, de Almeida and de Brito [37] indicates that for adopting new technology, a new BIM role such as a BIM manager should be appointed to avoid difficulty in its implementation. The Malaysian building industry’s BIM project guide proposes appointing a BIM manager to handle and manage the associated information [38].
Similarly, Hafeez [39] discussed that no role and responsibilities are defined in the employer’s information requirements (EIR) for construction projects in Qatar. Nevertheless, it can be observed from the abovementioned studies that the role of the BIM manager is primarily identified for developing countries, and the responsibilities of this role are yet to be defined. This helps conclude that the empirical research on BIM roles, tasks, and perceived responsibilities in the AEC industry is lacking in developing countries, particularly with the traditionally used project delivery methods.
To address this gap for developing economies, the present study aims to define the BIM-R&R in traditional project delivery methods, commonly used in most developing economies, i.e., DBB. Research objectives that form the basis of this research study are:
  • to identify and analyze the existing BIM-R&R for developing countries;
  • to determine the BIM-R&R for DBB projects in developing countries; and
  • to develop a matrix for the adoption of relevant BIM-R&R in developing countries.
This research paves the way for BIM adoption in developing countries by providing clarity for the developed BIM roles and their corresponding responsibilities on a project during its lifecycle. This study will help the associated construction industry in its efforts to implement BIM on their projects by assisting them in their practices. This study will provide the construction industry with a method to assess which BIM roles are necessary for projects. Moreover, it will give project and construction managers a clear understanding of the BIM roles on projects.
The BIM actor roles have been discussed in previous studies, either as a review or such roles are defined differently depending upon the industry, region, and country. Similarly, BIM guides are established by the developed economies in accordance with the particular BIM use by the relevant authority for the state or specific projects. Moreover, no study has empirically compiled all the roles employed in a project, nor has any study compiled BIM roles specific to a certain delivery method. Furthermore, no research has been conducted on BIM’s role in developing countries. BIM is gaining interest in developing economies, but they lack the idea of roles and responsibilities associated with BIM. Thus, to close the gap, this study provides BIM-R&R for prevalent project delivery methods in developing countries, which speaks to the novelty of this study.
The rest of the paper is organized as follows. The importance of roles and responsibilities in the construction industry and the roles and responsibilities associated with BIM are discussed in light of the literature and past research in the following section. This is followed by the description of the methodology used, the demonstration of results from the questionnaire survey responses and validation, and the conclusion.

2. Literature Review

2.1. Importance of Roles and Responsibilities in the Construction Industry

Construction projects involve unique and complex processes [40]. Within a project, each activity necessitates a different level of managerial focus and skillsets [41]. The project’s intricacy also increases due to the involvement of different parties and stakeholders who must effectively communicate to achieve the overall project objectives [42]. Thus, the complex construction project delivery comprises various disciplines and roles [29]. Similarly, distinct roles and responsibilities of the project teams are required at each phase of the project lifecycle [43]. A clear definition of the roles and duties of a project team is vital to avoid problems and conflicts and ensure project success through greater collaboration and openness [40,44]. Anantatmula [45] proposes that well-defined roles and responsibilities pave the way for building teamwork, managing conflicts, and improving project performance. According to Hoda and Murugesan [46], effective project team management requires understanding team members’ roles and outlining responsibilities.
Studies show that clearly defined roles and responsibilities of the construction project team significantly impact project outcomes and performance [45,47]. This highlights that unclear roles and responsibilities can lead to conflicts and failure to meet the client’s requirements, ultimately resulting in project failures [48]. Furthermore, Masengesho et al. [49] highlight the roles and responsibilities of project consultants in developing economies that influence the project’s success or failure. Additionally, the project manager’s role is important in achieving the project’s success [50,51]. However, this role is still ambiguous in developing countries [52]. Thus, it is not surprising to see many projects failing in developing countries due to improper allocation and understanding of project roles and responsibilities.

2.2. Design-Bid-Build Project Delivery

The traditional delivery method, design-bid-build, typically entails a process whereby design and contractor teams enters into a separate contract with the client to carry out the design and construction work, respectively [53]. In DBB, each task is completed one after the other without any overlap [54]. By using the competitive bidding, DBB exhibits the better cost performance [55] and is preferred over other delivery methods because of its higher productivity and lower cost [56], and the client’s desire to keep control of the project [55]. However, because of the fragmented approach of the design and construction phases, problems such as design and information issues, cost overruns, and poor project performance can be avoided by using BIM because all the project participants can easily share and reuse various information owing to BIM [57]. In addition, BIM has also helped in minimizing the design change orders and delivering better design [24].

2.3. Building Information Modelling in the Construction Industry

Organizations are increasingly turning toward BIM to improve project performance [28]. Due to its integrated design, construction, and maintenance approach, BIM provides simpler solutions to the complex nature of construction projects [58]. BIM incorporates multiple aspects, disciplines, and structures, making it favorable for most construction stakeholders [7,10]. By using a digital representation of a facility’s physical and functional properties, BIM helps the users share and use design data and requirements between different software applications across a multidisciplinary team [4]. Due to the excessive information exchange between parties, BIM’s support for collaboration has become an important requirement [59].
BIM provides easy sharing and reusing of different types of information between all project parties [57]. For example, the project team collects, manages, and documents graphical and non-graphical data through a single information source by using BIM [15]. Sharing the data in a central place makes the expected result clearer, concise, and understandable for all the team members [60]. Moreover, establishing collaborative practices on construction projects are likely to involve the coordination and integration of complex information, procedures, and systems [61]. Therefore, BIM allows better communication among project stakeholders [32] and influences how they work and collaborate [59].
BIM has benefited developing economies by reducing design change orders and improving design [24]. Al-Ashmori at al. [62] highlighted increased productivity and efficiency as one of the important benefits of implementing BIM in Malaysia. Similarly, as [12] discussed, BIM adoption results in increased profit, reduced cost and time, and improved relationships between the client and customer.

2.4. BIM Roles and Responsibilities

BIM has infiltrated the practices of a large number of interdisciplinary professionals [63]. Studies acknowledge that BIM alters project team members’ roles and responsibilities, including that of the client, designers, and contractors [28,29,63]. Another study highlights that BIM transforms the roles of construction participants due to its significant impact on collaborative processes by modifying information exchange and instigating denser interactions [63]. Sebastian [29] also discussed that the BIM projects demand the continuous emergence of BIM roles for construction professionals and highlight the need to evolve the roles among clients, designers, and contractors.
In addition to evolving with technology, new BIM-R&R have also been established within the construction industry [3]. Jacobsson and Merschbrock [6] state that the appearance of formal BIM professional roles was among the preliminary and noticeable changes observed due to the initiation of BIM. Owing to the increasing adoption of BIM within the construction industry, numerous BIM-related roles have emerged, such as BIM manager (VDC manager), BIM facilitator, BIM coordinator, BIM project manager, design team BIM manager/construction BIM manager, project model manager, BIM process manager, BIM lead coordinator, BIM discipline manager [34]. However, [64] states that the BIM manager, BIM coordinator and BIM modeler roles are considered as the three most important BIM roles required on a BIM-based project, in addition to the numerous BIM roles available. These newly formed roles and responsibilities ensure the organization’s transformation to BIM-based methods and BIM-enabled projects [3].
The US Veterans Affairs BIM Guide [21] defines BIM manager and discipline BIM coordinator’s responsibilities. It indicates that these roles are at the core of every BIM project. Similarly, the Singaporean BIM guide [65] emphasizes that two BIM professional roles, BIM manager and BIM coordinator, are recognized for facilitating the BIM process during the design and construction phases. The Norwegian Home Builders’ Association acknowledges the BIM coordinator as a key BIM role [66]. BSI PAS [15] defines the roles of task information manager, task team manager, interface manager, and information originator for BIM-based information management. Furthermore, the information manager role is also mandated in the Construction Industry Council BIM protocol. Information management is important in the level 2 BIM process [67]. Similarly, BIM roles of BIM manager, BIM coordinator, and BIM modeler are also recognized by [42] for improving the stakeholders’ relationship. Furthermore, Bilge and Yaman [68] explained the significance of information management in BIM and integrated project delivery (IPD) real estate projects. The authors defined the extended responsibilities of the information manager and information coordinator along the project lifecycle.
Though widely focused these days, BIM roles may not be as clear as needed so far. For example, Mathews [36] claimed that the industry is confused about the meaning and interpretation of three BIM roles, i.e., BIM manager, BIM coordinator, and BIM technician. Similarly, Davies et al. [34] studied how BIM specialist roles are defined in different BIM guides, handbooks, manuals, and standards. The study concluded that similar BIM role titles are used to describe different tasks within the project teams, which causes confusion. Other studies show that BIM manager and BIM coordinator roles are blurred, and their tasks are comparable [27,30,32]. Likewise, Zanni et al. [69] indicates that clash detection will be the responsibility of either the BIM manager or BIM coordinator, creating tensions between these roles. Jacobsson and Merschbrock [6] highlight that the BIM coordinator is mainly responsible for clash detection. However, Davies et al. [34] states that the BIM coordinator role is secondary and is led by the BIM manager.
Similarly, whether the BIM coordinator acts as a third party or comes from a design or construction firm, the unique and dedicated role in managing BIM projects is becoming necessary for most projects [59]. Furthermore, Wang et al. [42] noticed that the responsibilities of a BIM modeler are comparable to those of a BIM coordinator. In the information management domain, Bosch-Sijtsema [70] states that BIM facilitators manage the information and communication flow. However, Jacobsson and Merschbrock [6] state that the BIM coordinator is mainly responsible for managing information and communication flows. In comparison, BIM documents emphasize that the information manager is required for information-related activities [15,67]. Thus, there exists a fair confusion between the responsibilities of different BIM roles.
Different interpretations of identical roles are visible depending on the standards followed in each scenario [34]. With the increase in BIM-based projects, BIM-based roles and titles have also increased, which has resulted in increased nomenclature. However, there is still an ambiguity in the industry about the meaning and description of the discussed BIM roles. With so many different positions held by the diverse participants, it has become very important to define BIM roles for successful BIM implementation in the AEC industry [34].
This confusion around the BIM roles may further jeopardize the developing countries’ construction industry, where stakeholders’ clashes and imbalanced responsibilities assignments are common. Moreover, the lack of awareness regarding BIM-R&R in developing countries further adds to the adversities of the failures of BIM-based projects. The increase in BIM-based projects in developing economies necessitates a thorough understanding of the BIM roles. Therefore, BIM roles and responsibilities must be studied and investigated in the context of developing countries providing impetus to this study.

3. Research Methodology

A three-step process has been adopted in this study, as displayed in Figure 1. The subsequent sections thoroughly explain the research methodology.

3.1. Identification of BIM Tasks and Roles

To address the research gap and identify the BIM-based roles and responsibilities, a two-step literature review was carried out. In the first step, the BIM guides, standards, and handbooks were searched online on Google & Microsoft Bing search engines by using the keywords “BIM guides”, “BIM standards”, “BIM Handbooks” and “National BIM guides/standards/handbooks” until the present. The idea was to gather the maximum data possible for the study. This resulted in a total of 52 retrieved BIM guides/handbooks. As a screening step, their introduction and contents were read to identify the roles and responsibilities within, reducing it to 29 relevant documents. In the second step, published articles were searched online by using keywords including “Building Information Modelling”, “BIM”, “BIM roles”, “BIM responsibilities”, “BIM professional roles” and “BIM tasks” by using the ASCE, Web of Science, and Scopus libraries, Science Direct, Google Scholar, Taylor and Francis Online, and Emerald Insight following [55,71]. The search strings were formalized by combining the word “construction” with the Boolean operators AND/OR. The research publications only in the English language were considered in this study. Initially, 113 papers were retrieved related to BIM roles in the construction industry from 2010 to 2022, out of which 48 duplicated papers were eliminated and were counted only once. Furthermore, 25 papers were removed that were not related to BIM roles and responsibilities and focused on other aspects of BIM roles such as competencies, leaving 37 papers focused on BIM roles. To extract the most relevant papers, the keywords mentioned above were used in the search string of articles to look up the discussion regarding BIM roles and tasks. The papers having information about BIM-R&R were scrutinized and accessed individually, which resulted in the 26 shortlisted articles being analyzed further. Therefore, 29 BIM guides and 26 shortlisted research papers resulted in 55 relevant documents utilized in this study as shown in Figure 2.
The BIM-based tasks and their roles were extracted from the BIM documents and the published articles and then scrutinized in two steps. In the first step, extracted tasks were arranged alongside the project lifecycle phases used in BIM-based projects: initiation, planning and design, construction, monitoring and control, and operation and maintenance as envisaged by multiple BIM studies [9,72,73,74,75]. As a result, 555 BIM-based tasks were identified in five project phases. Upon scrutiny, the identical tasks were merged, resulting in 125 shortlisted BIM tasks. Depending on their significance, these BIM tasks were then classified into primary and secondary tasks. The primary category contained more exclusive tasks in terms of BIM and was performed by BIM personnel. Whereas the tasks and roles that are part of the project phases, even without BIM implementation, were placed in the secondary category. This exercise identified 82 BIM tasks in the primary category and 43 tasks in the secondary category.
In the second step, BIM roles were identified for each corresponding task depending on their frequency of appearance in the shortlisted documents. A maximum of the top three roles was selected for a task. The same role was selected for the tasks where only one role was mentioned in the literature. However, the most frequently used (top three) roles were chosen for the tasks with multiple roles. It was observed that approximately 50 tasks have only one role identified. This was because the tasks have only appeared once in the literature, or only one role has appeared frequently for that task. All these identified tasks are important concerning BIM, and it is also important to identify their correct role in context with DBB. Consequently, the BIM roles were separated for the design and construction phases considering the DBB project delivery method. All the selected roles and primary tasks formed the basis for the questionnaire development, as shown in Table 1.

3.2. Data Collection and Primary Analysis

Data in this research were collected through a questionnaire that was developed by using the identified BIM tasks and their relevant roles from both the published articles and BIM guides. The questionnaire aimed to identify BIM roles for the BIM-based tasks in construction projects using the DBB project delivery method in developing countries.
The questionnaire has two sections. The first section inquires about the respondent’s demographic and organizational information, such as their role, country of organization, designation, and experience. The second section identifies the most appropriate BIM role for each BIM task. For the tasks where more than one role was identified from the literature, respondents were asked to choose from the given roles or to mention any other role. However, for the tasks for which only one role was identified through the literature, an option was given to either select the same role or to mention another deemed appropriate by the respondents. Thus, the respondents had a choice in selecting the role for each task. The questionnaire was circulated in the construction industry of developing and developed economies. The reason for approaching both developed and developing countries is that developed countries are more experienced in implementing BIM and have a better understanding of the BIM process. Furthermore, DBB methods are still used for some projects in developed countries, so their opinion is relevant. It was also important to get the point of view from developing countries, as they have begun implementing BIM in line with the main aim of this study. The targeted respondents from the construction industry include BIM managers, project and construction managers, BIM coordinators, and BIM modelers.
Additionally, employees from the consultant and contractor firms were approached with a minimum of three years of BIM experience for more credible responses. The questionnaire was circulated online via official organizational emails and professional networks such as LinkedIn for four months between July 2021 and October 2021. As a result, 105 valid responses were obtained from the 200 professionals contacted to fill the questionnaire, yielding a response rate of 52 percent.
Following the statistics mentioned by [95], a sample size of 105 responses was considered adequate to represent a population of 200 million. The demographic information of the respondents is mentioned in Table 2.
The highest number of responses were received from Asia (58%), as shown in Figure 3. Moreover, the maximum number of responses were received from India in the Asian continent. Similarly, the top countries from the continents where the majority of responses were obtained are Egypt from Africa (corner of Africa and Asia), France from Europe, Canada from North America, Ecuador from South America, and Australia from Oceania. According to the findings of the [96] study, BIM adoption in Asia is perceived to be comparable to that of any other developed continent, which confirms the higher response rate from Asia in this study.
It can be clearly seen in Table 2 that most of the respondents were working with consultants (40%), followed by the contractor organizations (27%) as they are the primary stakeholders and are more familiar with implementing BIM. Moreover, BIM manager (41%) and BIM coordinator (27%) were the key BIM positions held by these respondents. Thus, the respondents held important BIM positions in their respective organizations. Furthermore, 34% of the respondents worked in technical BIM jobs like BIM modeler and management jobs such as project manager and construction manager. Furthermore, 83% of the respondents had less than 10 years of experience. The main reason is that BIM is a relatively new technology gaining experience with time [97]. Consequently, most of the direct BIM experience is expected to be limited [55].
Responses were then analyzed to get the most appropriate BIM role for each identified BIM task. Each role mentioned by the respondents was analyzed, and the frequency with which it was identified was noted. The role with the highest frequency was selected for each task.

4. Matrix Development for BIM Roles and Responsibilities (BIM-R&R)

The collected data was used to develop a matrix for implementing BIM-R&R on a BIM-based DBB project. To do this, research articles were explored to get an idea of how a process map for implementing BIM-R&R can be developed. This was done to identify the key groups and relate them to the tasks in the project lifecycle phases of BIM. It was found that three project focus groups, i.e., process, people, and technology (PPT), are widely accepted and help improve the overall organizational efforts [98,99,100]. The implementation of new technologies requires considerable changes in the construction process. Therefore, it becomes crucial to define the process and to hire and train the right people [101]. Dawood and Vukovic [102] also used PPT to classify BIM information flow during the project lifecycle processes. Davies et al. [34] also used the same categorization to classify the BIM activities. These articles assist in getting an idea about how the groups of PPT can be used to classify BIM tasks. A detailed overview of the PPT groups, project participants, and tasks associated with different project phases is provided in the Supplementary excel sheet attached as Supplementary Data to this article.
Following this, a BIM-R&R matrix is developed along the project lifecycle phases by using the PPT groups, as shown in Figure 4. While categorizing the tasks, it was ensured that all the tasks were placed in the correct PPT group. The distinct groups along which BIM tasks are classified are represented horizontally and vertically. Project lifecycle phases are shown horizontally, and focus groups are shown vertically. BIM tasks are grouped between the vertical and horizontal categories. Different color combinations are used to distinguish between different BIM personnel to whom BIM tasks are assigned. These include BIM manager (design), BIM manager (construction), BIM coordinator (design), BIM coordinator (construction), information manager (design), information manager (construction), model manager, and BIM modeler. The task number represents the tasks presented in Table 1, whereas the coloring represents the BIM person responsible for performing these tasks. For example, T1 represents task number for “Facilitate the development of a project BIM brief,” and its color, “light yellow,” shows that the BIM manager (design) will perform this task. Some tasks were assigned to more than one BIM professional and were placed in succession to eliminate confusion.

5. Results

This paper presents a matrix to define BIM-R&R for DBB construction projects in developing countries. The study highlights that the BIM roles have been developed without uniformity over the past years due to the development of multiple BIM guides. In contrast, no study has been conducted for applying BIM-R&R to a DBB project in developing countries. To develop roles for DBB projects, the survey responses in the current study show that certain roles need to be bifurcated between design and construction teams, wherein the roles of BIM manager, BIM coordinator, and information manager are prevalent. The survey results indicate that the BIM manager (design), BIM manager (construction), BIM coordinator (design), BIM coordinator (construction), information manager (design), information manager (construction), model manager, and BIM modeler are the key roles on a BIM project for implementing BIM-based activities.

6. Discussion

According to the results, the BIM managers for design and construction have different roles, depending on the project phase and the party they represent. The matrix shows that most of the tasks related to planning and design fall under the responsibility of the BIM manager (design), whereas the tasks related to execution fall under the responsibility of the BIM manager (construction). Thus, the BIM manager (design) and BIM manager (construction) are responsible for certain important managerial tasks such as defining, completing, and updating the BIM execution plan (T2) and creating the BIM execution plan in coordination with the design team (T31), respectively. These findings can be verified from [76,103], which outlines the BIM manager (design) responsible for defining the BIM Execution Plan (BEP) for all the planning, design, and supervision activities related to a project. On the other hand, Florida International University (FIU) [84] assigns the BEP creation for the project’s construction phase to the BIM manager (construction), who oversees all aspects of construction. This shows the harmony of the obtained responses with the published sources.
Similarly, some important technical tasks for BIM managers (design) and (construction) include overseeing the fully integrated set of project models from all disciplines (T20) and integrating and coordinating the construction schedule with developed models (T34), respectively. Most of the technical tasks are identical to the tasks defined in various BIM guides and articles that fall under the responsibility of the BIM manager [31,83,84,104]. The results of the current study clarify this confusion by correctly assigning the tasks to the BIM manager of the design and construction teams.
There were also instances in which a certain task is defined as the responsibility of differing BIM personnel in the literature. For example, the literature suggests a task for assisting in preparing project outputs to be the responsibility of the BIM manager [34] or information manager [105]. Because the responses are provided for DBB projects which bifurcates the responsibilities of the consultant and the contractor, this confusion is also negated. Accordingly, most respondents believe it to be the responsibility of the BIM manager (design), which seems logical because the BIM manager will be in a more commanding position to lead this task. Although the decision of task assignment to different roles lies with the project stakeholders, this survey will help the stakeholders assign the roles with more clarity on their projects.
In this study, information management tasks are also divided between the Information manager (design) and the information manager (construction). According to [34], the information manager is responsible for the information requirements of the project. This is reflected in the findings of the present study as the information manager (design) and the information manager (construction) are declared responsible for the information requirements of projects in their respective phase. Furthermore, the results also show that the information manager (construction) is responsible for archiving the project information models in addition to maintaining the information requirements during execution. This result also coincided with the literature, as Bilge and Yaman [68] mentioned this task to be among the fundamental responsibility of the information manager at the end of the project.
The results further reveal that the BIM coordinator (design) is mostly responsible for managing graphical and non-graphical activities (T15) along with clash detection of models (T24). According to [21,69], the BIM coordinator is in charge of these tasks, which aligns with the current study’s results. Furthermore, the task of a BIM coordinator (construction) includes the creation of construction and as-built models (T43). Building and Construction Authority (BCA) [65] while describing the roles of the BIM coordinator (construction), states that the BIM coordinator (construction) is responsible for these activities, thus supporting the findings of the current study.
According to the literature, a model manager is responsible for conducting interdisciplinary checks and dealing with internal model reviews and possible interoperability issues [29]. This is also supported by the survey results, which show broad agreement among respondents. Furthermore, according to [35,42,89], the tasks such as model development and construction drawing development are the responsibility of the BIM modeler, corresponding to the survey results.
Furthermore, the CIC BIM protocol suggests that the information manager be in charge of assisting in the preparation of project outputs [105]. The respondents, however, contrarily believe it to be the responsibility of the BIM manager (design). This makes sense as the task will be more effectively led by the BIM manager. Additionally, the roles for information management are also suggested by PAS as being crucial for the project [15]. This study includes the information manager role as well, but due to the DBB’s bifurcated nature, it is divided into the Information manager (design) and the information manager (construction).
Furthermore, it is observed that in contrast to the literature of developed economies, where multiple roles such as BIM manager, BIM coordinator, and information coordinator are identified for tasks such as define, complete, and update the BIM execution plan (T2), the respondents of the study clearly choose BIM manager (design) for this job in developing countries. Similarly, for the task of carrying out clash detection and resolution activities (T23), the literature identifies BIM manager, BIM coordinator, and model manager, whereas survey respondents select BIM coordinator (design) for DBB projects in developing countries. Thus, apart from the differences in BIM roles for a task, the study clearly identifies BIM roles needed for DBB projects in developing economies.
Additionally, due to the human resource challenges, which might be financial or resource availability, it may be considered that some BIM roles identified in this study can be merged with the existing roles on the construction project. It is not recommended for the role of the BIM manager, as it is the sole responsibility of the BIM manager to manage the entire BIM process. However, other identified roles can be merged, considering that the person in this role has BIM knowledge.

6.1. Validation of the Matrix through Expert Opinion

To determine the applicability of the proposed matrix, three experts from the industry with BIM experience were contacted to validate the proposed matrix by using the triangulation technique. Due to the length of the matrix, it was not feasible to conduct interviews. Experts have to critically analyze the placement of each task in project phases as well as in PPT. Due to a large number of tasks, the experts were sent a PDF file. The idea was to ensure the reliability of the validation achieved. Thus, the construction industry experts having significant experience and an in-depth understanding of BIM were contacted. The experts approached were informed about the study in detail and the intention of validating the matrix. After receiving their consent to validate the matrix, the PDF file was provided to them to give their opinion on it. Accordingly, an expert from one developed and two developing countries are engaged in the validation. Table 3 shows the demographics of the consulted experts.
All experts agreed on the placement of the tasks in the project phases and PPT, and no changes were recommended. Likewise, they also agreed on the roles for each task assigned through the questionnaire’s responses. However, a few concerns were raised that are discussed below.
One of the concerns raised by the experts was that no modeling-related BIM modeler task is present in the construction phase. The modeling-related tasks of the BIM modeler are present in the monitoring and control phase of the matrix. However, it should be noted that the monitoring and control phase responsibilities must be carried out during both the planning and construction phases of the project’s lifetime. Consequently, the initial task is correct, and its placement was not changed.
Similarly, one of the respondents argued that they have only three roles for BIM management, i.e., model manager, BIM coordinator, and BIM manager. Therefore, the information manager role does not exist, and its tasks can be delegated to the BIM manager. However, it is to be noted that the roles identified in this study are the result of a thorough review of the existing literature, and BIM publications stress the importance of having an information manager in charge of all information-related tasks as supported by relevant studies in different countries of the world [15,67]. Such requirements are more pronounced in developed countries where information management is considered a high-priority task. Therefore, such a position is retained in the current study to have a holistic matrix. Moreover, one respondent recommended the representation of the proposed BIM-R&R in the form of a matrix. The said BIM-R&R matrix is developed to address this suggestion, and its expansion is provided in the Supplementary File with this article.

6.2. Study Implications and Contributions

This study has proposed a BIM-R&R matrix that will explain all the BIM roles and responsibilities required for the DBB project delivery methods along the project life cycle phases of BIM in construction projects of developing countries. The BIM-R&R matrix will help with a better understanding of BIM actor roles, providing a clearer definition regarding who performs what task and who is responsible for what activity on the BIM-based project. Moreover, the BIM-R&R matrix will eventually help in identifying the right and appropriate BIM personnel for BIM-enabled projects. Furthermore, this matrix will assist managers in training their employees for the required role, if necessary.

7. Conclusions

Worldwide, BIM implementation has not only caused a change in traditional project roles and responsibilities but also has created new BIM roles on BIM-based projects. With the increase in BIM implementation in developed economies, multiple BIM roles have been created to address the BIM process. To systematize the contrasting and indistinct BIM-R&R description, this research investigated how BIM roles are defined in the literature and policy documents. This study highlights the BIM roles required for successfully implementing BIM on DBB projects, which will help developing countries better understand the BIM roles and implementation. Insights on what BIM tasks are performed by which BIM roles were gained through the questionnaire survey.
The survey results help selects appropriate BIM roles for the BIM tasks. The BIM roles identified through this study are BIM manager (design), BIM manager (construction), BIM coordinator (design), BIM coordinator (construction), information manager (design), information manager (construction), model manager, and BIM modeler.
The current study humbly attempts to uplift the BIM implementation status in developing countries by providing a definition and matrix to assign tasks to different BIM experts and roles in DBB projects. It will help the relevant construction and project managers assign tasks, duties, and responsibilities to the BIM professionals and achieve more stakeholders’ satisfaction through transparent, clearer, and well-defined information-sharing mechanisms.
The current study is limited by its number of respondents, more focus on developing countries, and a single type of project delivery (DBB). In the future, this can be extended to include other more advanced and collaborative project types such as public–private partnerships, alliances, and joint ventures. In addition, this study examined BIM guides and articles along with survey data. Furthermore, researchers can conduct detailed interviews with the field BIM practitioners of developing economies to get more precise results.

Supplementary Materials

The following supporting information can be downloaded at: https://www.mdpi.com/article/10.3390/buildings12101752/s1. The attached Excel sheet provides the detailed BIM-R&R matrix representing the proposed BIM-based roles and their corresponding responsibilities.

Author Contributions

Conceptualization, U.E.H.H. and A.R.N.; data curation, U.E.H.H.; formal analysis, U.E.H.H.; investigation, U.E.H.H.; methodology, U.E.H.H., A.R.N., F.U., S.Q. and M.J.T.; project administration, U.E.H.H. and A.R.N.; resources, U.E.H.H., A.R.N. and F.U.; supervision, A.R.N.; validation, U.E.H.H.; visualization, U.E.H.H.; writing—original draft, U.E.H.H.; writing—review and editing, A.R.N., F.U., S.Q. and M.J.T. All authors have read and agreed to the published version of the manuscript.

Funding

This research received no external funding.

Institutional Review Board Statement

Not applicable.

Informed Consent Statement

Informed consent was obtained from all respondents involved in the study.

Data Availability Statement

The data are available with the first author and can be shared upon reasonable request.

Conflicts of Interest

The authors declare no conflict of interest.

References

  1. Ahmad, Z.; Thaheem, M.J.; Maqsoom, A. Building Information Modeling as a Risk Transformer: An Evolutionary Insight into the Project Uncertainty. Autom. Constr. 2018, 92, 103–119. [Google Scholar] [CrossRef]
  2. Soltani, Z.; Anderson, S.; Kang, J. The Challenges of Using BIM in Construction Dispute Resolution Process. In Proceedings of the 53rd ASC Annual International Conference Proceedings, Associated Schools of Construction, Seattle, WA, USA, 5–8 April 2017; pp. 771–776. [Google Scholar]
  3. Akintola, A.; Venkatachalam, S.; Root, D. New BIM Roles’ Legitimacy and Changing Power Dynamics on BIM-Enabled Projects. J. Constr. Eng. Manag. 2017, 143, 04017066. [Google Scholar] [CrossRef]
  4. Ghaffarianhoseini, A.; Tookey, J.; Ghaffarianhoseini, A.; Naismith, N.; Azhar, S.; Efimova, O.; Raahemifar, K. Building Information Modelling (BIM) Uptake: Clear Benefits, Understanding Its Implementation, Risks and Challenges. Renew. Sustain. Energy Rev. 2017, 75, 1046–1053. [Google Scholar] [CrossRef]
  5. Malik, Q.; Nasir, A.R.; Muhammad, R.; Thaheem, M.J.; Ullah, F.; Khan, K.I.A.; Hassan, M.U. BIMp-Chart—A Global Decision Support System for Measuring BIM Implementation Level in Construction Organizations. Sustainability 2021, 13, 9270. [Google Scholar] [CrossRef]
  6. Jacobsson, M.; Merschbrock, C. BIM Coordinators: A Review. Eng. Constr. Archit. Manag. 2018, 25, 989–1008. [Google Scholar] [CrossRef] [Green Version]
  7. Takim, R.; Harris, M.; Nawawi, A.H. Building Information Modeling (BIM): A New Paradigm for Quality of Life within Architectural, Engineering and Construction (AEC) Industry. Procedia-Soc. Behav. Sci. 2013, 101, 23–32. [Google Scholar] [CrossRef] [Green Version]
  8. Bradley, A.; Li, H.; Lark, R.; Dunn, S. BIM for Infrastructure: An Overall Review and Constructor Perspective. Autom. Constr. 2016, 71, 139–152. [Google Scholar] [CrossRef]
  9. Eadie, R.; Browne, M.; Odeyinka, H.; McKeown, C.; McNiff, S. BIM Implementation throughout the UK Construction Project Lifecycle: An Analysis. Autom. Constr. 2013, 36, 145–151. [Google Scholar] [CrossRef]
  10. Arroteia, A.V.; do Amaral, G.G.; Kikuti, S.Z.; Melhado, S.B. BIM Knowledge Assessment: An Overview among Professionals. A Surv. AEC Ind. Sao Paulo Braz. 2020, 2, 315–324. [Google Scholar] [CrossRef]
  11. Georgiadou, M.C. An Overview of Benefits and Challenges of Building Information Modelling (BIM) Adoption in UK Residential Projects. Constr. Innov. 2019, 19, 298–320. [Google Scholar] [CrossRef]
  12. Bhatti, I.A.; Abdullah, A.H.; Nagapan, S.; Bhatti, N.B.; Sohu, S.; Jhatial, A.A. Implementation of Building Information Modeling (BIM) in Pakistan Construction Industry. Eng. Technol. Appl. Sci. Res. 2018, 8, 3199–3202. [Google Scholar] [CrossRef]
  13. Hamma-adama, M.; Kouider, T. Comparative Analysis of BIM Adoption Efforts by Developed Countries as Precedent for New Adopter Countries. Curr. J. Appl. Sci. Technol. 2019, 36, 1–15. [Google Scholar] [CrossRef]
  14. Othman, I.; Al-Ashmori, Y.Y.; Rahmawati, Y.; Mugahed Amran, Y.H.; Al-Bared, M.A.M. The Level of Building Information Modelling (BIM) Implementation in Malaysia. Ain Shams Eng. J. 2021, 12, 455–463. [Google Scholar] [CrossRef]
  15. BSI PAS 1192-2; Specification for Information Management for the Capital/Delivery Phase of Construction Projects Using Building Information Modelling. BSI Group: London, UK, 2013; Volume 1, pp. 1–44. Available online: https://knowledge.bsigroup.com/products/specification-for-information-management-for-the-capital-delivery-phase-of-construction-projects-using-building-information-modelling/standard/details (accessed on 18 October 2022).
  16. ISO 19650-1; Organization and Digitization of Information about Buildings and Civil Engineering Works, Including Building Information Modelling (BIM)-Information Management Using Building Information Modelling. BSI: London, UK, 2018; Volume 1, pp. 1–34. Available online: https://www.iso.org/standard/68078.html (accessed on 18 October 2022).
  17. Ali, K.N.; Mustaffa, N.E.; Keat, Q.J.; Enegbuma, W.I. BIM Knowledge and Skills Framework: An Introduction Strategic Forum for the Australasian Building and Construction Industry. BIM Knowl. Ski. Framew. Introd. Strateg. Forum Australas. Build. Constr. Ind. 2017, 1, 1–32. [Google Scholar]
  18. Denis, F. Building Information Modelling–Belgian Guide for the Construction Industry, 1st ed.; ADEB-VBA: Brussel, Belgium, 2015. [Google Scholar]
  19. HKIBIM. Hong Kong Institute of Building Information Modelling BIM Project Specification, 3rd ed.; Hong Kong Institute of Building Information Modelling: Hong Kong, China, 2011. [Google Scholar]
  20. NZ. The New Zealand BIM Handbook a Guide to Enabling BIM on Built Assets 2019, 3rd ed.; Building and Construction Productivity Partnership: Judgeford, New Zealand, 2019; Volume 5. [Google Scholar]
  21. VA. The VA BIM Guide, 1st ed.; Department of Veterans Affairs: Washington, DC, USA, 2010. [Google Scholar]
  22. Girginkaya Akdag, S.; Maqsood, U. A Roadmap for BIM Adoption and Implementation in Developing Countries: The Pakistan Case. Archnet-IJAR 2020, 14, 112–132. [Google Scholar] [CrossRef]
  23. Babatunde, S.O.; Ekundayo, D.; Adekunle, A.O.; Bello, W. Comparative Analysis of Drivers to BIM Adoption among AEC Firms in Developing Countries: A Case of Nigeria. J. Eng. Des. Technol. 2020, 18, 1425–1447. [Google Scholar] [CrossRef] [Green Version]
  24. Ismail, N.A.A.; Chiozzi, M.; Drogemuller, R. An Overview of BIM Uptake in Asian Developing Countries. AIP Conf. Proc. 2017, 1903, 1–8. [Google Scholar] [CrossRef] [Green Version]
  25. Bui, N.; Merschbrock, C.; Munkvold, B.E. A Review of Building Information Modelling for Construction in Developing Countries. Procedia Eng. 2016, 164, 487–494. [Google Scholar] [CrossRef]
  26. Kaini, I. Implementation of Integrated Project Delivery (IPD) and Building Information Modelling (BIM) in the Construction Industry. J. Teknol. 2013, 1, 69–73. [Google Scholar]
  27. Hosseini, M.R.; Martek, I.; Papadonikolaki, E.; Sheikhkhoshkar, M.; Banihashemi, S.; Arashpour, M. Viability of the BIM Manager Enduring as a Distinct Role: Association Rule Mining of Job Advertisements. J. Constr. Eng. Manag. 2018, 144, 1–11. [Google Scholar] [CrossRef]
  28. Latiffi, A.A.; Brahim, J.; Fathi, M.S. Roles and Responsibilities of Construction Players in Projects Using Building Information Modeling (BIM). In Proceedings of the IFIP International Conference on Product Lifecycle Management, Doha, Qatar, 19–21 October 2015. [Google Scholar] [CrossRef] [Green Version]
  29. Sebastian, R. Changing Roles of the Clients, Architects and Contractors through BIM. Eng. Constr. Archit. Manag. 2011, 18, 176–187. [Google Scholar] [CrossRef]
  30. Bosch-Sijtsema, P.M.; Gluch, P.; Sezer, A.A. Professional Development of the BIM Actor Role. Autom. Constr. 2019, 97, 44–51. [Google Scholar] [CrossRef] [Green Version]
  31. Barison, M.B. An Overview of BIM Specialists Roles and Responsibilities. In Proceedings of the ICCCBE2010, Nottingham, UK, 30 June–2 July 2010; pp. 141–147. [Google Scholar]
  32. Bosch-Sijtsema, P.; Gluch, P. Challenging Construction Project Management Institutions: The Role and Agency of BIM Actors. Int. J. Constr. Manag. 2021, 21, 1077–1087. [Google Scholar] [CrossRef] [Green Version]
  33. Uhm, M.; Lee, G.; Jeon, B. An Analysis of BIM Jobs and Competencies Based on the Use of Terms in the Industry. Autom. Constr. 2017, 81, 67–98. [Google Scholar] [CrossRef]
  34. Davies, K.; Wilkinson, S.; McMeel, D. A Review of Specialist Role Definitions in Bim Guides and Standards. J. Inf. Technol. Constr. 2017, 22, 185–203. [Google Scholar]
  35. Barison, M.B.; Santos, E.T. An Overview of BIM Specialists. In Proceedings of the 2010 International Conference on Computing and Civil and Building Engineering, Nottingham, UK, 30 June–2 July 2010. [Google Scholar]
  36. Mathews, M. Defining Job Titles and Career Paths in BIM. CITA BIM Gather. 2015, 33–38. [Google Scholar]
  37. de Almeida, G.; de Brito, L.C.B. Analysis of Organizational Culture in Brazilian Building Companies to Evaluate Changes Required by BIM Technology. Bus. Manag. Dyn. 2017, 7, 1–16. [Google Scholar]
  38. CIDB. BIM Guide 5-BIM Project Guide; CIDB: Kuala Lampur, Malaysia, 2019. [Google Scholar]
  39. Hafeez. Investigating the Potential of Delivering Employer Information Requirements in BIM Enabled Construction Projects in Qatar. In Proceedings of the IFIP International Conference on Product Lifecycle Management, Doha, Qatar, 19–21 October 2015. [Google Scholar] [CrossRef] [Green Version]
  40. Elbarkouky, M.M.G.; Fayek, A.R. Fuzzy Similarity Consensus Model for Early Alignment of Construction Project Teams on the Extent of Their Roles and Responsibilities. J. Constr. Eng. Manag. 2011, 137, 432–440. [Google Scholar] [CrossRef]
  41. Adami, V.S.; Verschoore, J.R.; Antunes Junior, J.A.V. Effect of Relational Characteristics on Management of Wind Farm Interorganizational Construction Projects. J. Constr. Eng. Manag. 2019, 145, 05018019. [Google Scholar] [CrossRef]
  42. Wang, Y.; Thangasamy, V.K.; Hou, Z.; Tiong, R.L.K.; Zhang, L. Collaborative Relationship Discovery in BIM Project Delivery: A Social Network Analysis Approach. Autom. Constr. 2020, 114, 103147. [Google Scholar] [CrossRef]
  43. Beckers, F.; Silva, E.; Chiara, N.; Flesch, A.; Maly, J.; Stegemann, U. A Risk-Management Approach to a Successful Infrastructure Project. McKinsey Work. Pap. Risk 2013, 18. Available online: https://www.mckinsey.com/capabilities/operations/our-insights/a-risk-management-approach-to-a-successful-infrastructure-project (accessed on 18 October 2022).
  44. Davis, K. An Empirical Investigation into Different Stakeholder Groups Perception of Project Success. Int. J. Proj. Manag. 2017, 35, 604–617. [Google Scholar] [CrossRef] [Green Version]
  45. Anantatmula, V.S. Project Manager Leadership Role in Improving Project Performance. EMJ-Eng. Manag. J. 2010, 22, 13–22. [Google Scholar] [CrossRef]
  46. Hoda, R.; Murugesan, L.K. Multi-Level Agile Project Management Challenges: A Self-Organizing Team Perspective. J. Syst. Softw. 2016, 117, 245–257. [Google Scholar] [CrossRef]
  47. Feger, A.L.R.; Thomas, G.A. A Framework for Exploring the Relationship Between Project Manager Leadership Style and Project Success. Int. J. Manag. 2012, 1, 1–19. [Google Scholar]
  48. Ahmed, R.; Anantatmula, V.S. Empirical Study of Project Managers Leadership Competence and Project Performance. EMJ—Eng. Manag. J. 2017, 29, 189–205. [Google Scholar] [CrossRef]
  49. Masengesho, E.; Wei, J.; Niyirora, R.; Umubyeyi, N. Relationship between Project Consultants’ Performance and Project Success in the Rwandan Construction Industry. World J. Eng. Technol. 2021, 9, 138–154. [Google Scholar] [CrossRef]
  50. Doloi, H. Cost Overruns and Failure in Project Management: Understanding the Roles of Key Stakeholders in Construction Projects. J. Constr. Eng. Manag. 2013, 139, 267–279. [Google Scholar] [CrossRef]
  51. Ogunde, A.; Olaolu, O.; Afolabi, A.; Owolabi, J.; Ojelabi, R. Challenges Confronting Construction Project Management System for Sustainable Construction in Developing Countries: Professionals Perspectives (a Case Study of Nigeria). J. Build. Perform. 2017, 8, 1–11. [Google Scholar]
  52. Shibani, A.; Sukumar, D. The Role of the Project Manager in Construction Projects in India. Chinese Bus. Rev. 2015, 14. [Google Scholar] [CrossRef] [Green Version]
  53. Ghadamsi, A.; Braimah, N. The Impact of Design-Bid-Build Procurement Methods on Project Performance in Libya. J. Constr. Eng. Proj. Manag. 2016, 6, 16–23. [Google Scholar] [CrossRef]
  54. Zhong, Q.; Tang, H.; Chen, C. A Framework for Selecting Construction Project Delivery Method Using Design Structure Matrix. Buildings 2022, 12, 443. [Google Scholar] [CrossRef]
  55. Arshad, M.F.; Thaheem, M.J.; Nasir, A.R.; Malik, M.S.A. Contractual Risks of Building Information Modeling: Toward a Standardized Legal Framework for Design-Bid-Build Projects. J. Constr. Eng. Manag. 2019, 145, 04019010. [Google Scholar] [CrossRef]
  56. Park, J.; Hoon, Y. Science Direct Design-Bid-Build (DBB) vs. Design-Build (DB) in the US Public Transportation Projects: The Choice and Consequences. Int. J. Proj. Manag. 2017, 35, 280–295. [Google Scholar] [CrossRef]
  57. 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]
  58. Namlı, E.; Işıkdağ, Ü.; Kocakaya, M.N. Building Information Management (BIM), A New Approach to Project Management. J. Sustain. Constr. Mater. Technol. 2019, 4, 323–332. [Google Scholar] [CrossRef]
  59. Liu, Y.; van Nederveen, S.; Hertogh, M. Understanding Effects of BIM on Collaborative Design and Construction. An Empirical Study in China. Int. J. Proj. Manag. 2017, 35, 686–698. [Google Scholar] [CrossRef]
  60. Dubas, S.; Pasławski, J. The Concept of Improving Communication in BIM during Transfer to Operation Phase on the Polish Market. Procedia Eng. 2017, 208, 14–19. [Google Scholar] [CrossRef]
  61. Alreshidi, E.; Mourshed, M.; Rezgui, Y. Factors for Effective BIM Governance. J. Build. Eng. 2017, 10, 89–101. [Google Scholar] [CrossRef] [Green Version]
  62. Al-Ashmori, Y.Y.; Othman, I.; Rahmawati, Y.; Amran, Y.H.M.; Sabah, S.H.A.; Rafindadi, A.D.; Mikić, M. BIM Benefits and Its Influence on the BIM Implementation in Malaysia. Ain Shams Eng. J. 2020, 11, 1013–1019. [Google Scholar] [CrossRef]
  63. Papadonikolaki, E.; Van Oel, C. The Actors’ Perceptions and Expectations of Their Roles in BIM-Based Collaboration. In Proceedings of the 32nd Annual ARCOM Conference, Manchester, UK, 5–7 September 2016; pp. 93–102. [Google Scholar]
  64. Biabani, F.; Kim, J.H.; Ham, N. Qualitative Assessment of Collaborative Behavior Based on Self-Perception Personality Tests for BIM Staff. Buildings 2022, 12, 1–22. [Google Scholar] [CrossRef]
  65. BCA. Singapore BIM Guide, 2nd ed.; BIM Guide Workgroup: Singapore, 2013. [Google Scholar]
  66. BoligBIM. Norwegian Home Builders’ Association Bim User Manual, 1st ed.; Norwegian Home Builders Association: Oslo, Norway, 2012. [Google Scholar]
  67. CIC. Building Information Modelling (Bim) Protocol, 2nd ed.; Construction Industry Council: London, UK, 2018. [Google Scholar]
  68. Bilge, E.C.; Yaman, H. Information Management Roles in Real Estate Development Lifecycle: Literature Review on BIM and IPD Framework. Constr. Innov. 2021, 21. [Google Scholar] [CrossRef]
  69. Zanni, M.A.; Soetanto, R.; Ruikar, K. towards a BIM-Enabled Sustainable Building Design Process: Roles, Responsibilities, and Requirements. Archit. Eng. Des. Manag. 2017, 13, 101–129. [Google Scholar] [CrossRef] [Green Version]
  70. Bosch-Sijtsema, P. New ICT Changes Working Routines in Construction Design Projects. Nord. Acad. Manag. 2013, 1–9. Available online: https://publications.lib.chalmers.se/records/fulltext/179131/local_179131.pdf (accessed on 18 October 2022).
  71. Bukhari, H.; Thaheem, M.J.; Musarat, M.A.; Alaloul, W.S.; Altaf, M. Are Pakistani Construction Professionals Truly Happy? A Benchmarking Approach. Ain Shams Eng. J. 2021, 12, 3579–3591. [Google Scholar] [CrossRef]
  72. Ma, X.; Xiong, F.; Olawumi, T.O.; Dong, N.; Chan, A.P.C. Conceptual Framework and Roadmap Approach for Integrating BIM into Lifecycle Project Management. J. Manag. Eng. 2018, 34, 05018011. [Google Scholar] [CrossRef] [Green Version]
  73. Muller, M.F.; Esmanioto, F.; Huber, N.; Loures, E.R.; Canciglieri, O. A Systematic Literature Review of Interoperability in the Green Building Information Modeling Lifecycle. J. Clean. Prod. 2019, 223, 397–412. [Google Scholar] [CrossRef]
  74. Hussain, Z. Using BIM for Sustainability Monitoring and Management over the Building Life Cycle. Master’s Thesis, Birmingham City University, Birmingham, UK, 2020. Available online: https://www.researchgate.net/publication/341481221 (accessed on 18 October 2022).
  75. Fadeyi, M.O. The Role of Building Information Modeling (BIM) in Delivering the Sustainable Building Value. Int. J. Sustain. Built Environ. 2017, 6, 711–722. [Google Scholar] [CrossRef]
  76. NATSPEC. National BIM Guide, 1st ed.; NATSPEC: Sydney, Australia, 2016. [Google Scholar]
  77. USF. BIM Project Execution Plan Template for Architects, Engineers and Contractors; University of South Florida: Tampa, FL, USA, 2018. [Google Scholar]
  78. v4.2; LACCD Building Information Modeling Standards. LACCD: Los Angeles, CA, USA, 2017.
  79. COBIM. Common BIM Requirements, 1st ed.; Senate Properties: Helsinki, Finland, 2012. [Google Scholar]
  80. CoD. BIM Guide-Protocols and Project Execution Plan; College of the Desert: Palm Desert, CA, USA, 2011. [Google Scholar]
  81. NYC-DDC. BIM Guidelines; New York City Department of Design and Construction: New York, NY, USA, 2012. [Google Scholar] [CrossRef]
  82. Massport. BIM Guidelines for Vertical and Horizontal Construction; Massachusetts Port Authority: Boston, MA, USA, 2015. [Google Scholar]
  83. Wu, W.; Issa, R.R.A. BIM Education and Recruiting: Survey-Based Comparative Analysis of Issues, Perceptions, and Collaboration Opportunities. J. Prof. Issues Eng. Educ. Pract. 2014, 140, 1–9. [Google Scholar] [CrossRef]
  84. FIU. Building Information Modeling (BIM) Standard and Guide, 1st ed.; Florida International University: Miami, FL, USA, 2014; Available online: https://facilities.fiu.edu/Documents/Forms_Standards/FIU_BIM_Standard_120814.pdf (accessed on 18 October 2022).
  85. Merschbrock, C.; Munkvold, B.E. Effective Digital Collaboration in the Construction Industry-A Case Study of BIM Deployment in a Hospital Construction Project. Comput. Ind. 2015, 73, 1–7. [Google Scholar] [CrossRef]
  86. Li, W.; Leite, F. Comparison of Experienced and Novice BIM Coordinators in Performing Mechanical, Electrical and Plumbing (MEP) Coordination Tasks. Constr. Res. Congr. 2014, 2014, 140–149. [Google Scholar]
  87. Guerriero, A.; Kubicki, S.; Hua, D.; Lamb, S.; Jacquemart, S.; Daher, E. Classification of Bim Curriculum in Eu and Bim Actor Competence Matrix. BIM4VETA 2017, 1, 6–32. [Google Scholar]
  88. Kaneta, T.; Furusaka, S.; Tamura, A.; Deng, N. Overview of BIM Implementation in Singapore and Japan. J. Civ. Eng. Archit. 2016, 10, 1305–1312. [Google Scholar] [CrossRef]
  89. Joseph, J. BIM Titles and Job Descriptions: How Do They Fit in Your Organizational Structure? Autodesk University: New Orleans, LA, USA, 2011. [Google Scholar]
  90. v1.1; Building Information Modeling (BIM) Project Delivery Standards. The Ohio State University: Columbus, OH, USA, 2020.
  91. USC. Building Information Modeling Guidlines; University of South California: Los Angeles, CA, USA, 2012; Available online: https://www.scribd.com/document/291080545/BIM-Guidelines-Ver1-6-USC-2012 (accessed on 18 October 2022).
  92. Jin, X.; Zhang, G.; Liu, J.; Feng, Y.; Zuo, J. Major Participants in the Construction Industry and Their Approaches to Risks: A Theoretical Framework. Procedia Eng. 2017, 182, 314–320. [Google Scholar] [CrossRef]
  93. Boton, C.; Forgues, D. Practices and Processes in BIM Projects: An Exploratory Case Study. Adv. Civ. Eng. 2018, 2018, 1–12. [Google Scholar] [CrossRef] [Green Version]
  94. SEC Group. First Steps to BIM Competence—A Guide for Specialist Contractors; University of Northumbria: Northumbria, UK, 2017; Available online: https://www.thebesa.com/media/2899/bim-competence-final.pdf (accessed on 18 October 2022).
  95. Dillman, D.A.; Smyth, J.D.; Christian, L. Internet, Phone, Mail, and Mixed-Mode Surveys the Tailored Design Method, 4th ed.; John Wiley & Sons: Hoboken: NJ, USA, 2014. [Google Scholar]
  96. Jung, W.; Lee, G. The Status of BIM Adoption on Six Continents. Int. J. Civil Struct. Constr. Archit. Eng. 2015, 9, 406–410. [Google Scholar]
  97. Gerges, M.; Austin, S.; Mayouf, M.; Ahiakwo, O.; Jaeger, M.; Saad, A.; El Gohary, T. An Investigation into the Implementation of Building Information Modeling in the Middle East. J. Inf. Technol. Constr. 2017, 22, 1–15. [Google Scholar]
  98. Javaid, M.I.; Iqbal, M.M.W. A Comprehensive People, Process and Technology (PPT) Application Model for Information Systems (IS) Risk Management in Small/Medium Enterprises (SME). In Proceedings of the 2017 International Conference on Communication Technologies (ComTech), Rawalpindi, Pakistan, 19–21 April 2017; pp. 78–90. [Google Scholar] [CrossRef]
  99. Prodan, M.; Prodan, A.; Purcarea, A.A. Three New Dimensions to People, Process, Technology Improvement Model. Adv. Intell. Syst. Comput. 2015, 353, III–IV. [Google Scholar] [CrossRef] [Green Version]
  100. Nadim, W.; Goulding, J.S. Offsite Production: A Model for Building down Barriers A European Construction Industry Perspective. Eng. Constr. Archit. Manag. 2011, 18, 82–101. [Google Scholar] [CrossRef]
  101. Arayici, Y.; Coates, P.; Koskela, L.; Kagioglou, M.; Usher, C.; O’Reilly, K. Technology Adoption in the BIM Implementation for Lean Architectural Practice. Autom. Constr. 2011, 20, 189–195. [Google Scholar] [CrossRef]
  102. Dawood, N.; Vukovic, V. Challenges and Opportunities for Whole Lifecycle Information Flow Underpinned By Bim: Technology, Process, Policy and People. In KIBIM Magazine; Teesside University: Middlesbrough, UK, 2015; Volume 7, pp. 1–7. [Google Scholar]
  103. Panagiotidou, N.; Pitt, M.; Lu, Q. Building Information Modelling Execution Plans: A Global Review. Smart Infrastruct. Constr. 2022, 1, 1–22. [Google Scholar] [CrossRef]
  104. Doukari, O.; Seck, B.; Greenwood, D. The Creation of Construction Schedules in 4D BIM: A Comparison of Conventional and Automated Approaches. Buildings 2022, 18, 1145. [Google Scholar] [CrossRef]
  105. CIC. Building Information Modelling (Bim) Protocol, 1st ed.; Beale and Company: London, UK, 2013. [Google Scholar]
Buildings 12 01752 g001 550
Figure 1. Research methodology.
Figure 1. Research methodology.
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Buildings 12 01752 g002 550
Figure 2. Identification of BIM tasks and roles though literature.
Figure 2. Identification of BIM tasks and roles though literature.
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Figure 3. Demographic information of respondents.
Figure 3. Demographic information of respondents.
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Figure 4. Proposed BIM-R&R matrix. Please note the different colors correspond to the color of the BIM roles and responsibilities provided in the legend section under the matrix.
Figure 4. Proposed BIM-R&R matrix. Please note the different colors correspond to the color of the BIM roles and responsibilities provided in the legend section under the matrix.
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Table
Table 1. Identified BIM tasks and roles.
Table 1. Identified BIM tasks and roles.
Task IDProject PhasesBIM TasksTop Roles from LiteratureSelected Refs
T1InitiationFacilitate the development of a project BIM briefBIM manager (design)[20]
T2Define, complete and update the BIM execution planBIM manager (design), BIM coordinator (design)[3,76]
T3Identify BIM standardsBIM manager (design), BIM coordinator (design)[3,77]
T4Facilitate the identification and implementation of BIM standardsModel manager[35]
T5Define project BIM protocolsBIM coordinator (design), BIM facilitator (design)[3,78]
T6Establish project information requirement and information protocolsInformation manager (design)[68]
T7Coordinate BIM tasks in design discipline BIM coordinator (design)[34]
T8Provide guidelines to the team on agreed project rulesBIM coordinator (design)[34]
T9Provide design guidelines to the team on project rules as agreedModel manager[79]
T10Communicate BIM vision to the teamBIM manager (design)[80]
T11Planning & DesignEstablish asset information requirements and the process to maintain the asset information modelInformation manager (design)[68]
T12Coordinate and organize BIM training and workshopsBIM manager (design), BIM coordinator (design), BIM facilitator (design)[32,81]
T13Coordinate modeling standards among the project teamModel manager[79]
T14Manage all the graphical model development related tasks and non-graphical model development related tasks in accordance with BIM execution planBIM manager (design), BIM coordinator (design), BIM facilitator (design)[30,77]
T15Create, coordinate & extract design drawings from BIM models Model manager, BIM modeler[35]
T16Coordinate all technical discipline and trade-specific BIM activity, i.e., tools, content, standards, requirementsBIM coordinator (design)[76,81]
T17Lead the BIM documentation and analysis efforts of the internal project teamBIM coordinator (design)[21,82]
T18Perform internal model reviews and interdisciplinary checksModel manager[35]
T19Oversee the fully integrated set of project models from all disciplinesBIM manager (design), BIM coordinator (design)[42,83]
T20Coordinate multidisciplinary tasksBIM manager (design), BIM coordinator (design), Model manager[77,84]
T21Assure assembling of merged modelsBIM manager (design), BIM coordinator (design), BIM facilitator (design)[78,85]
T22Assure and inspect the functionality of merged models and the integration of the design modelsModel manager[79]
T23Carry out clash detection and resolution activitiesBIM manager (design), BIM coordinator (design), Model manager[84,86]
T24Manage model transfer and version control BIM manager (design)[20]
T25Schedule, coordinate, and facilitate BIM meetings for the design and construction team as well as all design disciplinesBIM manager (design), BIM coordinator (design)[66,77]
T26Participate and coordinate in internal BIM meetingsModel manager[79]
T27Prepare project outputs and revise them regarding quality assurance (QA) and quality control (QC) protocolsModel manager, BIM modeler[87]
T28Assist in the preparation of project outputsBIM manager (design), Information manager (design)[34,67]
T29Coordinate with the construction manager on the BIM execution planBIM manager (design)[84]
T30ConstructionCreate BIM execution plan in coordination with the design teamBIM manager (construction), BIM coordinator (construction)[82,88]
T31Establish software protocols for efficient BIM deliveryBIM manager (construction)[21,77]
T32Coordinate software trainingBIM manager (construction)[21,77]
T33Coordinate sub-contractor BIM developmentBIM manager (construction)[82]
T34Integrate and coordinate the construction schedule with developed modelsBIM manager (construction)[84]
T35Integrate 3D fabrication models with the updated design model to ensure compliance with the design intentBIM manager (construction), BIM facilitator (construction)[78,82]
T36Carry out clash detection and resolution activitiesBIM manager (construction)[82,84]
T37Schedule, coordinate, and facilitate BIM meetings for the design and construction team and all design disciplinesBIM manager (construction), BIM coordinator (construction), BIM facilitator (construction)[77,89]
T38Update models for shop drawings developmentBIM coordinator (construction)[82,89]
T39Create construction and as-built modelsBIM coordinator (construction)[65]
T40Prepare as-built BIMModel manager[29]
T41Coordinate data extraction sets BIM manager (construction), BIM facilitator (construction)[77,78]
T42Coordinate model commissioning and data handoverBIM manager (construction)[82]
T43Monitoring & ControlImplement and manage the BIM process, i.e., the BIM execution planBIM manager (design), BIM manager (construction), BIM manager (design and construction)[35,84]
T44Participate in the updating of the BIM planModel manager[79]
T45Ensure compliance with the BIM execution planBIM manager (design and construction), BIM coordinator (design and construction)[34,77]
T46Ensure compliance with standardsBIM manager (design), BIM coordinator (design), Task information manager[15,87]
T47Ensure BIM protocols implementationBIM coordinator (design), Information manager (design)[3,67]
T48Verify that all necessary configurations required for the seamless integration of design and construction model information have been implementedBIM manager (design)[77,82]
T49Ensure the accuracy of construction documents in accordance with discipline BIM modelingBIM modeler[89]
T50Ensure document managementBIM manager (design)[21,34]
T51Ensure software installation, operation, and version controlBIM manager (design and construction), BIM facilitator (design and construction)[21,34]
T52Ensure software operationModel manager[87]
T53Develop & maintain graphical and non-graphical models in accordance with the BIM execution planBIM modeler[59,90]
T54Monitor model production and updatingBIM coordinator (design and construction), BIM facilitator (design and construction)[6,91]
T55Manage model production and updatingModel manager[35,90]
T56Brief, assist, and coordinate with stakeholdersBIM manager (design and construction), BIM coordinator (design and construction)[20,42]
T57Assist in coordination with stakeholdersModel manager[29]
T58Communicate/Coordinate BIM issues with other membersBIM manager (design and construction), BIM coordinator (design and construction)[20,92]
T59Manage the BIM resources (hardware, software, and people)BIM manager (construction)[35]
T60Ensure BIM is used appropriately to test design requirements/criteriaBIM manager (design), BIM facilitator (design)[78,82]
T61Perform and manage the QA and QC of modelsBIM manager (design), BIM coordinator (design)[34,93]
T62Look after design discipline-based QA and QC of modelsModel manager[79]
T63Coordinate update of as-built conditions in the final model deliverableBIM manager (construction)[21,91]
T64Adhere to the projects BIM deliverables and their submissionModel manager[90]
T65Ensure final BIM deliverable requirements are achievedBIM manager (design)[21,77]
T66Maintain local file transfers, control of access lefts, and compilation of information from smaller models of other membersModel manager[35]
T67Manage digital outputs, data transmission, and archivingBIM manager (design), Information manager (design), Model manager[94]
T68Facilitate, plan, and manage interoperability issuesModel manager[29,35]
T69Manage interoperability issuesBIM coordinator (design), BIM facilitator (design)[6,70]
T70Enable integration and coordination of information within the information modelInformation manager (design), Information manager (construction), Information manager (design and construction)[15]
T71Coordinate to assure completeness of interoperability informationBIM manager (design), BIM manager (construction), BIM manager (design and construction)[21,77]
T72Ensure interoperability information is provided for milestone submittalsBIM manager (design), BIM facilitator (design)[21,91]
T73Liaise with the client’s facilities management department to determine specific data and file exchange requirementsBIM manager (design)[76]
T74Maintain exchange information requirementsInformation manager (construction)[68]
T75Initiate and implement the project information plan and asset information planInformation manager (design)[68]
T76Enable reliable information exchange through a common data environmentInformation manager (design)[68]
T77Manage the processes and procedures for information exchange on projectsInformation manager (design)[68]
T78Ensure that the information exchanged between the different stakeholders corresponds to the rules fixed by the contractBIM manager (design)[18]
T79Operation & MaintenanceArchive the project information modelInformation manager (construction)[68]
T80Ensure information and model availability for operation and maintenanceBIM coordinator (construction)[66]
T81Identify assets (model and physical) and the foreseeable trigger events for which information should be managedInformation manager (construction)[68]
T82Capture lessons learned for future projectsInformation manager (construction)[68]
Table
Table 2. Demographic information of respondents.
Table 2. Demographic information of respondents.
Demographic VariablesNumbersPercentage (%)
Organization typeClient55
Design consultant3937
Supervisory consultant33
Contractor2827
Architect1817
Other1211
Role in organizationProject manager22
Construction manager33
BIM manager4341
BIM modeler2120
BIM coordinator2827
Other87
Year of experience with BIM1–32827
3–63231
6–92321
9–121010
Above 121211
Table
Table 3. Demographics of experts for validating the matrix.
Table 3. Demographics of experts for validating the matrix.
Demographics of RespondentsExpert 1Expert 2Expert 3
Organization typeArchitectArchitectContractor
Country of organizationFranceLebanonQatar
Role in organizationBIM ManagerBIM ManagerBIM Manager
Year of experience with BIM9–126–93–6
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Habib, U.E.H.; Nasir, A.R.; Ullah, F.; Qayyum, S.; Thaheem, M.J. BIM Roles and Responsibilities in Developing Countries: A Dedicated Matrix for Design-Bid-Build Projects. Buildings 2022, 12, 1752. https://doi.org/10.3390/buildings12101752

AMA Style

Habib UEH, Nasir AR, Ullah F, Qayyum S, Thaheem MJ. BIM Roles and Responsibilities in Developing Countries: A Dedicated Matrix for Design-Bid-Build Projects. Buildings. 2022; 12(10):1752. https://doi.org/10.3390/buildings12101752

Chicago/Turabian Style

Habib, Um E Hani, Abdur Rehman Nasir, Fahim Ullah, Siddra Qayyum, and Muhammad Jamaluddin Thaheem. 2022. "BIM Roles and Responsibilities in Developing Countries: A Dedicated Matrix for Design-Bid-Build Projects" Buildings 12, no. 10: 1752. https://doi.org/10.3390/buildings12101752

APA Style

Habib, U. E. H., Nasir, A. R., Ullah, F., Qayyum, S., & Thaheem, M. J. (2022). BIM Roles and Responsibilities in Developing Countries: A Dedicated Matrix for Design-Bid-Build Projects. Buildings, 12(10), 1752. https://doi.org/10.3390/buildings12101752

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