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Article

Defining a BIM-Enabled Learning Environment—An Adaptive Structuration Theory Perspective

by
Theophilus Olowa
1,*,
Emlyn Witt
1,
Caterina Morganti
2,
Toni Teittinen
3 and
Irene Lill
1
1
Department of Civil Engineering and Architecture, Tallinn University of Technology, 12616 Tallinn, Estonia
2
Department of Architecture, University of Bologna, 40126 Bologna, Italy
3
Department of Construction Management and Economics, Tampere University, 33720 Tampere, Finland
*
Author to whom correspondence should be addressed.
Buildings 2022, 12(3), 292; https://doi.org/10.3390/buildings12030292
Submission received: 30 January 2022 / Revised: 25 February 2022 / Accepted: 28 February 2022 / Published: 2 March 2022
(This article belongs to the Special Issue Towards Smart Tech 4.0 in the Built Environment: Applications of Disruptive Digital Technologies in Smart Cities, Construction, and Real Estate)
Browse Figures
Versions Notes

Abstract

:
Digitalization of the AEC-FM industry has resulted in the reassessment of knowledge, knowledge management, teaching and learning, workflows and networks, roles, and relevance. Consequently, new approaches to teaching and learning to meet the demands of new jobs and abilities, new channels of communication, and a new awareness are required. Building Information Modelling (BIM) offers opportunities to address some of the current challenges through BIM-enabled education and training. This research defines the requisite characteristics of a BIM-enabled Learning Environment (BLE)—a web-based platform that facilitates BIM-enabled education and training—in order to develop a prototype version of the BLE. Using a mixed-methods research design and an Adaptive Structuration Theory (AST) perspective for interpreting the findings, 33 features and 5 distinct intentions behind those features were identified. These findings are valuable in taking forward the development of the BLE as they suggest a BLE requires the integration of functions from three existing types of information technology application (virtual learning environments, virtual collaboration platforms, and BIM applications). This study will inform the design of a web-based BLE for enhanced AEC-FM education and training, and it also provides a starting point for researchers to apply AST to evaluate the use of a BLE in different educational and training contexts.

1. Introduction

Digitalization of the construction industry is driving changes in the required knowledge, skills, and attitudes of construction industry professionals, thus motivating the adaptation of their education and training. Building Information Modelling (BIM) is central to this digitalization, and it offers opportunities to address some of the current challenges through BIM-enabled education [1], i.e., using BIM as a vehicle for knowledge creation, sharing, transmission, and evaluation. In earlier research, the authors analyzed extant cases of BIM education and investigated the difficulties faced in designing and implementing BIM education curricula generally and BIM-enabled education curricula specifically. In doing so, the need for an integrated, BIM-enabled Learning Environment (BLE) in which educators and trainers can effectively carry out BIM-enabled education and training was identified [2,3]. A BLE is expected to provide a web-based platform through which new and existing BIM-enabled approaches can be conveniently deployed for teaching and learning activities for the Architecture, Engineering, Construction, and Facilities Management (AEC-FM) disciplines. This study aims to define the characteristics of a BLE and applies an Adaptive Structuration Theory (AST) perspective to achieve this.
AST is a development of Anthony Gidden’s Structuration Theory to the context of Advanced Information Technology (AIT) use in organizations [4]. Structuration Theory aims to understand social systems through their structures—the properties, rules, and resources or sets of transformational relations that allow similar social practices to be reproduced across time and space and give them the form of systems [5] (pp. 16–25). AST considers the types of structures that are provided by AITs, i.e., structures that are embedded within the technologies themselves, and the structures that emerge in human action as people interact with these technologies [5].
DeSanctis and Poole [6] define AITs as information technologies that not only enable the accomplishment of organizational tasks but also support coordination among people and provide procedures for interpersonal exchange. As an educational and training platform, the proposed BLE must clearly achieve both—it must enable BIM-enabled educational/training tasks and also mediate interpersonal exchanges between teachers/trainers/students—and thus may be considered an AIT in the AST sense.
DeSanctis and Poole [6] propounded the theory for understanding technology-induced organizational change and proposed a comprehensive framework to this end, which is shown in Figure 1. By applying this AST framework to the problem of BLE development, the authors’ intention is to first understand and define the characteristics of the BLE as an AIT in order to develop the BLE and then, later, to study its use and impact in the organizational contexts where it is utilized for education and training. This article reports the first of these steps: research to define the BLE characteristics with reference to the AST framework in order to subsequently facilitate research, in which the AST framework is applied to study the effects of BLE implementation.
AST maintains that the structure of an AIT may be characterized in terms of its set of structural features and its spirit. The structural features relate to the rules, resources and capabilities offered by the AIT, and they control and bring meaning to the social interactions mediated by the AIT. The spirit of an AIT refers to the overall intentions behind its set of structural features in terms of value propositions and goals for which the AIT was designed (cf. [7]). It also embraces what DeSanctis and Poole [6] referred to as the “status quo”, i.e., the current interpretive account of the technology’s values and purposes based on the numerous ways by which the technology is appropriated over time by different users under different conditions. As Orlikowski [8] puts it: “While technologies may appear to have objective forms and functions at one point, these can and do vary by different users, by different contexts of use, and by the same users over time”. Similarly, DeSanctis and Poole [6] argue that the use of any structure in an AIT is not sacrosanct since humans, as reflective agents, may use any aspects of the technology structures in any way they wish—they referred to these as appropriation moves. The decision to appropriate a particular structure and its continuance is dependent on how favorable and satisfying the actual outcome is. An appropriation move is considered faithful, if it is in line with the design intent for which it was created, or unfaithful, if used differently from the spirit of the technology (which is not necessarily a bad thing).
This study defines the structural features and spirit of the proposed BLE as an AIT through a qualitative, interpretivist, pragmatic approach. As previously noted, this will enable BLE development in the first place and, subsequently, facilitate the study of a BLE in use. Moreover, identifying both the structural features and the spirit of a BLE will assist in categorizing the existing sources of BLE structures into domains that would enable both a comparative and gap analysis of users’ requirements in delivering BIM-enabled learning. The latter is particularly necessary since the expected output of this effort is the development of a web-based BLE that will afford geographically dispersed users the opportunity to access learning materials without the constraints and limiting issues associated with hardware devices, encourage independent and lifelong learning, and also promote adaptive and personalized learning. Lastly, it will offer researchers, educators, and trainers a means to evaluate empirically, and, possibly, address the consequences arising from, teachers’ and learners’ appropriation moves with respect to a BLE.
In the next section, we provide a brief review of the related literature. This is followed by a description of the methodology adopted to define and specify the attributes of the proposed BLE through a series of case studies and interviews carried out in three countries. The findings of these case studies and interviews are then presented before their implications for theory and practice are discussed. Conclusions are drawn in the final section.

1.1. Literature Review

1.1.1. BIM-Enabled Education

BIM education has seen an upsurge in interest in the last two decades among teaching faculty and researchers with authors emphasizing different aspects of educational skills, attitudes, and knowledge. Conversely, the presence of COVID-19 globally in the past 2 years has also brought to focus the importance of digital technologies, virtual and augmented realities, and other tools that are valuable in construction engineering education [9]. BIM educational programs start with creating awareness and educating students and trainees on how to use different industry-specific BIM software packages (e.g., Revit, ArchiCAD, Navisworks, Rhino3D, Aconex, etc.) for modelling, viewing, simulating, scheduling, or data sharing (see [10,11,12,13,14,15,16]). Courses often begin by highlighting the benefits and barriers of BIM, including the reasons for BIM adoption in the AEC-FM industry (e.g., [17,18,19,20,21,22,23,24,25,26,27]) and the progress on BIM knowledge and authoring/manipulation skills (e.g., [28,29,30,31]).
Beyond developing BIM software skills, BIM technology has also been used to impart other learning such as coordination, collaboration, communication, and interpersonal relationships among students, etc. (see [16,32,33,34]). For instance, Barham et al. [35] experimented with BIM as a visualization tool in teaching structural detailing. Several other studies have demonstrated how researchers and practitioners are pushing the boundaries in the ways that BIM can be leveraged in construction engineering games for educational purposes (e.g., [36,37,38,39,40,41,42]). This mutual influence between BIM technology and BIM agents—teaching BIM technology and using BIM technology to teach—is a defining characteristic of BIM education.
Underwood et al. [1] categorized the evolution of BIM education into three progressive stages:
  • BIM-aware, where graduates are made aware of the uses and exigencies of BIM relating to its implications for both digital and cultural transformation of the construction industry.
  • BIM-focused, which involves graduates’ abilities to use and manipulate BIM software in performing specific tasks such as modelling, clash detection, simulation, etc.
  • BIM-enabled, where education takes place in a BIM-mediated virtual environment, and BIM acts as a platform for learning [1].
Both BIM-aware and BIM-focused education have been generally recognized and initiatives to develop curricula to incorporate BIM have become widespread. A comprehensive account of BIM-enabled education cases has been documented in Abdirad and Dossick [43] and more recently updated in Olowa et al. [2].

1.1.2. BIM-Enabled Learning Environments

COVID-19 has significantly underscored the demand for distributed, collaborative, self-paced, and adaptive learning. Already a decade ago, Ku et al. [40] identified these challenges and experimented on what they referred to as a BIM interactive Model (BiM)—a platform that combines a virtual environment with BIM for learning purposes and proposed a theoretical web-based virtual world for engaging construction stakeholders in real-time social interaction using the Second Life virtual environment. They contended that integrating 2D and intelligent 3D BIM models would supplement construction education to overcome the limitation of location-based learning and make it accessible to anyone with an internet connection. Recognizing the benefits of promoting distributed training opportunities, as suggested by Ku and his colleagues, further studies have been carried out and reported in support of this initiative (e.g., [44,45,46,47,48,49])
Acknowledging the general consensus among previous developers and authors on the ability of a virtual learning environment (VLE) to promote off-site training and education, Shen et al. [50] used the 3D-UNITY game engine to create a web-based training environment for HVAC rehabilitation and improvement using a BIM model. In contrast to Ku et al. [40] and the Second Life platform, the authors argued that game engines have been sufficiently developed for BIM interoperability, thereby making game creation cheaper and easier with little to no need for programming skill. With their research, Shen et al. [50] were able to demonstrate how BIM could be leveraged for teaching at the topical level.

1.1.3. Application of AST to BIM-Enabled Learning Environments

AST is used in this study as it emphasizes the importance of social structures in the development of new technologies and in the use of those technologies by people [6,51]. As Turner et al. [51] note: “AST explains the complications associated with the technology–organization connection and provides … information on how to develop new technologies or design educational curriculums that encourage adapting new technologies”. Although we have not come across any study that has applied AST in the development of a new, innovative technology (in this case, a BIM-enabled Learning Environment), AST has been extensively used in evaluating AITs relating to group decision support systems [7] and, more recently, to explore value creation at the business process level through BIM in the construction industry [52]. AST has also been used to investigate socio-technical changes that are brought about by AITs, such as social media interaction among researchers [53], understanding the relationship between agile methods and organizational features [54], and understanding the influence of ICT infrastructure on student teachers’ use of Student Information Management System [55].

2. Materials and Methods

According to Ma et al. [56], there are 3 steps involved in defining the functional requirements for an AIT. These include identifying and isolating relevant processes of intended users; formulating functional requirements based on the isolated processes; and revising and validating the relevant processes that correspond to the formulated functional requirements through inquiries from prospective users. With these processes in mind, an exploratory sequential mixed-methods research methodology [57] was applied in this research with the aim of specifying a BIM-enabled Learning Environment (BLE).
In preparatory work to this study, an initial, theoretical BLE concept developed by Witt and Kähkönen [58] had been applied in a BIM-enabled learning intervention that was trialed at Tallinn University of Technology within an existing course taught to fourth year civil engineering students (reported in [3]). In addition to this Estonian case, two further cases of BIM-enabled learning activities carried out at the University of Bologna, Italy and Tampere University, Finland were analyzed in order to develop an initial list of requirements for a BLE. A desk study was also conducted to review existing academic and grey literature to find relevant materials related to existing BLE type initiatives so as to understand the general characteristics of a BLE. These preparatory activities enabled the design of the semi-structured interview data collection strategy and instrument elaborated below.

2.1. Data Collection

2.1.1. Interview Participants

For the interviews, participants were purposively selected in 3 European countries: Estonia, Finland, and Italy. These 3 countries were selected for convenience in the context of an ongoing research collaboration between the Tallinn University of Technology, Tampere University, and the University of Bologna. The relevance criteria for participants were that they should be actively engaged with AEC-FM training and/or AEC-FM education and/or BIM-training and/or BIM-education in any (e.g., academic, industry, etc.) setting irrespective of their mode of delivery in teaching practice. The selection of interviewees was intentionally directed towards achieving representation from as wide a range of relevant stakeholders as possible. A total of 31 participants (10 from Estonia, 9 from Finland, and 12 from Italy) were interviewed with interviews in each country conducted by 2 or 3 different facilitators. All interviewees read and signed an informed consent form prior to their participation.

2.1.2. Interview Schedule

A semi-structured interview schedule was used to elicit information regarding the ideal characteristics of a BLE based on the educator’s/trainer’s lived experiences and aspirations. The interview schedule commenced with an overview of the purpose and context of the research and confirmation of the interviewee’s data (name, position, and affiliations). As the interviewees were expected to comment on a concept (the BLE), as opposed to an existing artefact with which they could have direct experience, it was important to establish a common understanding of the general idea of the BLE among all interviewees. For this purpose, a short (1 min) video outlining the BLE concept with commentary in the local language (Estonian, Finnish, or Italian) was played to them before a series of open-ended questions were asked as follows:
  • Please describe the teaching/training that you/your organization give (Including subject(s), target audience).
  • Do you currently use BIM for delivering your teaching/training? (Alternative if organization only arranges training: Is BIM currently used in the delivery of training arranged by your organization?)
If YES:
3.
How do you use BIM in the delivery? (e.g., for visualizations, project data, communication, etc.)
(Alternative if organization only arranges training: How is BIM used in training delivery?)
If NO:
4.
Could you use BIM to help deliver your teaching/training and for what? (e.g., for visualizations, project data, communication, etc.)
(Alternative if organization only arranges training: Could BIM be used in training delivery?)
5.
Beyond your present area(s) of teaching/training, how do you think BIM could be used in BIM-enabled learning?
(Alternative if organization only arranges training: Beyond the areas of training arranged by your organization, how do you think BIM could be used in BIM-enabled learning?)
6.
What functions would you like to see in a BIM-enabled Learning Environment?

2.2. Data Analysis

2.2.1. Grounded Theory Method

The analysis of the interviews was based on a Grounded Theory (GT) model because of their acclaimed usefulness in the development of process-oriented, context-based descriptions and explanations of information system phenomena [59]. GT is a method of data analysis and theory generation propounded by Glasser and Strauss [60] that is based on induction. Since the pronouncement of their initial concept, it has metamorphosed with different authors suggesting additional nuances on how it should be applied leading to different GT versions. According to Urquhart, the major models used in the literature are those suggested by Glasser, Strauss, and Charmaz [59]. Despite their differences, they all agree on iteratively sampling data to generate themes (at a high abstract level) that are useful for developing theories grounded in the collected data. This study adopted the Straussian Theory Model (STM) with the unit of analysis being predominantly segments of the interview transcripts that convey a particular meaning. In line with the Straussian approach, extracting these segments of texts is the first step of analysis referred to as open coding. This was followed by axial coding in order to identify major categories. However, this methodology was applied as a tool for discovering associations within the data rather than as a rigid set of rules [59]. The data collection and analysis were sequential. Interviews were mostly carried out virtually (online) using MS Teams, Zoom, etc. as maybe agreed by both the facilitators and the participants. Where possible, face-to-face interviews were also conducted. In both circumstances, interview sessions were audio recorded and transcribed. As interviews were conducted in local languages as well as in English, interview transcription and analysis were carried out by different analysts and this necessitated coordination in the form of a commonly agreed analysis template with four predetermined coding categories: demographics; subjects taught; target audience; and functional requirements. Additionally, emergent categories were then continuously added as analysts found them. These included method(s) of teaching/training, BIM uses, level(s) of BIM awareness/competency, and challenges. The structural coding was achieved using NVivo qualitative data analysis software in some cases and, in others, the MS Word text editor was used, as not all the facilitators were familiar with NVivo software. Analysis of all interviews was then aggregated using NVivo software for further and final analysis. As part of this aggregated analysis, all interview references to the “spirit” attributes of the BLE were also captured through theoretical sensitivity.

2.2.2. Validation of BLE Features by Focus Group

The results of the interview analysis were then presented to a focus group of AEC-FM education experts for validation. For the focus group, the researchers took advantage of an online workshop in which BIM educators and enthusiasts from 5 countries participated and discussed the BLE concept and the proposed BLE features that had emerged from the interviews. Focus group participants were then asked to rate the level of importance of each proposed BLE feature identified from the interviews using an online questionnaire containing both closed- and open-ended questions. The closed-ended questions presented each identified feature with a 5-point Likert-type scale for importance ratings: “1-Not important”, “2-Slightly important”, “3-Moderately important”, “4-Very important” and “5-Critically important”. The open-ended questions were intended to elicit comments, suggestions and recommendations for additional features that would be important for a BLE but were missing from the list identified from the interviews.

2.2.3. Statistical Methods

The questionnaire was fully completed and submitted by 10 respondents. Analysis of the online questionnaire by the focus group was carried out using descriptive statistics, viz simple mean score and a relative importance index for each of the identified BLE features. Figure 2 illustrates the research process adopted for this study.

3. Results

3.1. Characteristics of Participants

The interviewed participants were from diverse backgrounds in terms of the type of organization that they belonged to, actual sub-sector in which they operate, and their geographical location. Figure 3 shows three clusters of bars, which depict the distribution of the participants according to their organization type, sub-sector, and country. From the three countries where the interviews were conducted, i.e., Estonia, Finland, and Italy, a total of six sub-categories emerged from the organization type with the highest participants coming from the university (13), construction (8), and vocational education (4) sub-categories. Other sub-categories are Construction information and training NGO (1), Consultancy (1), and Real Estate management and maintenance (4).
The sub-sectors to which the participants belong were also identified as education (15), general contracting (5), and real estate/facilities management (2). The individual characteristics of the validation questionnaire of respondents within the focus group could not be isolated because, while it was expected that all validation workshop participants who had not been engaged in developing the research findings would complete the online questionnaire, this did not turn out to be the case.

3.2. Identifying and Isolating Functional Requirements/Structural Features of the Proposed BLE

Table 1 shows the list of 33 identified and isolated functional requirements emerging from the preparatory desk study (literature review and three case study analyses), the 31 interviews and the focus group suggestions for additional BLE features together with an explanatory commentary on the corresponding structural feature for the proposed BLE.

3.3. Validating and Revising the Structural Features of BLE

Table 2 shows the list of structural features for a BLE based on the focus group ranking. The mean was calculated based on the 5-stage Likert scale ranging between 1 and 5, 1 being “Not important” and 5 representing “Critically important”. Using the relative importance index (RII) where the most important has the least value (1 in this case) and the least important has the highest value (i.e., 30). Three of the functional requirements (#13, #26, #27) were identified by the focus group as suggestions for additional BLE features and were therefore not included in the validation questionnaire and consequently, not ranked by the focus group.

3.4. Spirit of the Proposed BLE

Qualitative content analysis of the interview data also revealed insights into the attributes of the spirit of the proposed BLE. Table 3 shows the spirit attributes or intentions that were expressed by the participants and which informed their defining of structural features for a BLE. These attributes include collaboration, active learning, integrated learning, adaptive and personalized learning, and project process improvement

4. Discussion

The interview transcripts and emergent recommendations for BLE features, to an extent, appear to reflect the participants’ positive and negative experiences in relation to their own education/training activities. For instance, the popularity of collaborative learning in groups and problem/project-based learning approaches is reflected in the numerous recommended features that relate to groups and collaboration (features (refer to Table 1 and Table 2 above): #3, #6, #14, #15, #16, #17, #18, and #20) and generating realistic project learning contexts (features: #2, #7, #8, and #9). In addition, participants complained of problems with managing software for students and interoperability (reflected in features #7 and #18) as well as the need for effective integration between systems (reflected in features #12, #32, and #33). Further challenges expressed by participants included the limited BIM skills of educators and trainers themselves, and there was some skepticism regarding educators’/trainers’ motivation to welcome new modes of training using BIM models. These challenges have been identified by several researchers as impediments to BIM education generally (e.g., [1,61,62]) and, it seems, could not be addressed by specific feature recommendations for the proposed BLE.
The recommended BLE features can also be understood as corresponding to three distinct categories of function: “BIM” functions, “collaboration” functions, and “virtual learning environment” (VLE) functions, and Figure 4 depicts these categories together with their associated BLE features.
The BIM functions relate to features typically associated with BIM software such as the creation and editing of BIM models, BIM model viewing, common data environments for project data, etc. Collaboration functions allow for virtual communication, coordination, and collaboration in groups and can be readily recognized as including features commonly associated with existing virtual collaboration/video conferencing platforms such as Zoom, MS Teams, etc. Similarly, the VLE functions aggregate those features (learning progress tracking, performance monitoring, assessment and testing, feedback to learners, associated security and data protection, and so on), which would be associated with typical VLE or learning management system (LMS) platforms such as Moodle, Blackboard, etc. There are also some recommended BLE features that relate to more than one of these categories. For example, the ability to be able to upload, store, download, and edit files is common to both VLE and collaboration categories. Similarly, the ability to simulate project development processes and associated stakeholder interactions relates to both collaboration and BIM function categories. Importantly, we note that these three functional categories are required to be incorporated into the proposed BLE if it is to properly support and facilitate AEC-FM training and learning.
These findings suggest that, when asked to specify the functionalities that would be necessary in a BLE, the interview participants have collectively drawn on their educational/training experiences of existing AITs (specifically BIM, virtual collaboration, and VLE technologies) and identified relevant functionalities from these familiar AITs to then incorporate into the new, proposed AIT (the BLE). This process closely resembles the “appropriation of structures” as conceptualized by DeSanctis and Poole [6]—see boxes one and four and proposition P1 in Figure 1. The same types of social interactions enabled by certain structures embedded within these existing AITs are considered by the interviewees to be desirable for BIM-enabled learning, and therefore similar social interactions should also be enabled by the BLE. In order to replicate these desired social interactions among and between learners and teachers using the BLE, the same enabling structures must therefore be appropriated and incorporated into the BLE specification.
DeSanctis and Poole’s [6] conceptualization also points to other sources of structure in the organizational environment and task (Figure 1, box two) as well as the (AIT user) group’s internal system and styles of interaction (Figure 1, box three). Whereas at the stage of designing the BLE, both user groups and tasks are as broadly defined as possible so as to allow the greatest and widest potential utility of the BLE, the organizational environments in which the BLE will be used and from which the interviewees have been drawn may be readily identified as being of two distinct types: educational and industry. It follows that the structures of the BLE will also reflect the structures from these two organizational types: structures from the education system and structures from the AEC-FM industry system. The structures embedded in education systems have been delineated by Witt and Kähkönen [58] to include the rules, resources, and roles relating to learning and teaching, and it is clear that participants’ interactions and relationships with these structures have informed their suggestions offered for defining the structures of a BLE.
The contributing structures from the AEC-FM industry system relate to industry-specific roles and ways of working. The nature of the construction industry is such that it involves different stakeholders, with different responsibilities and liabilities even when they have the same product as a goal. The industry workflow demands that suppliers come in at different points in the execution and delivery of projects with clear deliverables and targets. The structures enabling these activities are reflected in the interviewees’ recommendations of related structures that a robust BLE must exhibit to effectively deliver project-based learning to graduates, trainees, and professionals for industry relevance. Within the AEC-FM industry environment, its digital transformation and, specifically, its adoption of BIM is particularly important, as the BLE is predicated upon the latent benefit of BIM for the industry and also for education. BIM structures dictate how work and project data should flow with different levels of definition, how they should be shared, etc.
The emergent conception is one in which the structural features recommended by participants for the proposed BLE are those which they have identified as enabling the social interactions they consider could support BIM-enabled learning. Additionally, when we consider from where (the organizational environments from which) those participants are drawn and the types of AITs (BIM, virtual collaboration technologies, and VLEs) with which they are already familiar, it becomes clear that these (environments and AITs) are the sources of the structures that are being appropriated for incorporation into the BLE.
DeSanctis and Poole [6] consider the structure of AITs to comprise both structural features and also spirit—the overall intentions behind the set of structural features. While our data collection and validation rather emphasized the definition of the structural features (for the practical reasons of interviewees and focus group members’ ease of understanding), the intentions that drive these features have also been extracted to some extent from the interview transcripts (summarized in Table 3). It is notable that many of the intentions (spirit attributes in Table 3) among educators in higher education institutions (HEIs) reflect what have previously been documented and described as educators’ strategies in BIM for construction education [2]. These include integrative teaching, promoting active learning or constructivist education, promoting accessible education, and creating adaptive and personalized learning experiences. Further spirit attributes (intentions) captured included collaboration and (project process) improvements, both of which appear to reflect current intentions (particularly relating to BIM adoption) within the AEC-FM industry, thus reinforcing the notion that the recommended structures (both structural features and spirit) for the proposed BLE are indeed selected structures appropriated from existing AITs and organizational environments with which the interviewees were familiar. This is illustrated in Figure 5: concept map showing the sources of structures appropriated to define the BLE.
The notion of appropriation of structures from existing AITs and organizational environments, in itself, is a useful insight for the further development of the BLE as it may be thought of as representing an integration of these AITs and environments. This phenomenon of adapting available resources underscores the need to have a defined structural starting point that will promote the delivery of BIM-enabled education in an efficient way. The development of a prototype BLE on this basis will enable a new pedagogical strategy capable of increasing students’ motivation by presenting a more inclusive and sophisticated view of any AEC-FM BIM-related topic or course. Going forward, the defined structures must now inform technical system design in order to develop a prototype BLE.
Whereas DeSanctis and Poole [6] originally designed AST to assess and evaluate the outcomes of AIT use in social settings, this study has shown how it can also be employed to define an AIT (the BLE) in terms of the desired social structures (structural features and spirit) that the proposed AIT is intended to enable. We have also found AST to be a useful theoretical lens through which to interpret and understand the emergent BLE definition that has been derived. Once the BLE is developed, even in prototype form, then it will be possible, and it is intended to deploy the full AST approach to investigate how it is used by (different) social groups and thus evaluate its effectiveness in delivering BIM-enabled learning.
Regarding the limitations of this study, it should be noted that we have concentrated on defining the structural features and the spirit of a BLE using a structured set of interview questions among a few interviewees and respondents in three European countries. While we consider the findings robust, they are geographically and developmentally specific, and a larger, more geographically dispersed sample size would be beneficial for a more comprehensive identification and definition of the structures of a BLE, particularly if it were to be utilized in non-European contexts.

5. Conclusions

The digitalization of the AEC-FM industry has resulted in a demand for the reassessment of knowledge, knowledge management, teaching and learning, workflows and networks, individual roles, and relevance. Consequently, new teaching and learning platforms to cater to the requirements of new jobs and abilities, new channels of communication, and a new awareness are all required. BIM is a central feature of this digitalization, and it also offers opportunities to address some of the current challenges through BIM-enabled education and training. While BIM has become standard in industry, it is still being determined how it can be fully leveraged in training and education. To facilitate BIM-enabled learning, a platform—the BIM-enabled Learning Environment (BLE)—through which new and existing BIM-enabled approaches can be conveniently deployed for teaching and learning activities in the AEC-FM disciplines is needed.
This study aimed to define the characteristics of the proposed BLE. Within an exploratory sequential mixed-methods approach, preliminary data were collected through the qualitative analysis of three case studies as well as a study of the academic and grey literature. This led to a series of 31 semi-structured interviews being carried out in three European countries (Estonia, Finland, and Italy). A qualitative, grounded theory inspired, content analysis of the interview transcripts was applied to identify and isolate the desired functionalities of the BLE and the broader intentions behind these functionalities. The identified and isolated features of the BLE were then validated and added to in a focus group validation exercise using a quantitative, questionnaire with a Likert-type scale for importance ranking. Thus, a comprehensive list of BLE features was defined and validated, and each feature’s ranking in terms of its relative importance was determined. In addition, the general intentions underlying the set of identified features were described.
Adaptive Structuration Theory (AST) was applied as a theoretical lens through which to interpret and understand the emergent findings in terms of the BLE’s structural features (functionalities) and spirit (intentions behind the recommended functionalities). While, to the authors’ knowledge, the application of AST for the design of an Advanced Information Technology (AIT) (the BLE) is a first, the AST lens did enable us to appreciate that the structures of the proposed BLE (its structural features and spirit) were not new in themselves but were rather being appropriated from other, existing AITs (BIM, virtual collaboration technologies, and VLE platforms) with which the interview participants were already familiar. In addition, and, in a sense, providing the sources of structure to the existing AITs, structures were also appropriated from the organizational environments that the participants came from. These insights are valuable in taking forward the development of the BLE into an actual, usable prototype as they suggest the functional integration of features from three defined AIT sources. The AST framework also provides a sound basis for future investigations of the BLE in use—which would be the typical application of the AST framework to study AIT use in a given social/organizational context.
Plainly, there are remaining challenges and doubts about how best to implement BLE in training and whether the new processes will be worth the effort among the stakeholders. This skepticism is understandable when we remember that change is turbulent and not easily embraced by all. This situation gets more complicated when trainers envisage putting in disproportionate additional efforts to bring a new learning style to bear. However, this is one way the development of an easy to use, open, and accessible platform with a repository of example BIM-enabled exercises could prove valuable.
The findings of this study have a wide range of implications for both theory and practice and in guiding future research direction. First and foremost, from a practical point of view, it provides the basis for the actual development of a prototype BLE. It also provides decision makers in software development organizations (especially those relating to the development of BIM applications for industry) insights and improvement opportunities to develop products that can be more easily integrated into AEC-FM education. Additionally, educational policy decision makers at relevant governmental levels should consider promoting more collaboration between developers of technologies for industry, users of technology, and educators/trainers—not only from the point of view of preparing industry workers with appropriate technology knowledge and skills but also in order to maximize the degree to which the technologies can be used to enhance education and training. Future research will focus on
  • Further investigation among more diverse and geographically dispersed stakeholders especially in the developing countries to ensure context-wide requirements are captured.
  • Investigating the technical integration of all the identified functions into a user-friendly, web-based platform for optimized AEC-FM education (the BLE).
  • Exploring the implementation of the BLE and evaluating its effectiveness using the AST framework.

Author Contributions

Conceptualization, T.O. and E.W.; methodology, T.O. and E.W.; formal analysis, T.O., C.M., T.T. and E.W.; writing—original draft preparation, T.O.; writing—review and editing, E.W.; visualization, T.O. and E.W.; supervision, E.W. and I.L.; project administration, E.W. and I.L.; funding acquisition, E.W. and I.L. All authors have read and agreed to the published version of the manuscript.

Funding

This research was supported by the BIM-enabled Learning Environment for Digital Construction (BENEDICT) project (grant number: 2020-1-EE01-KA203-077993), Integrating Education with Consumer Behavior relevant to Energy Efficiency and Climate Change at the Universities of Russia, Sri Lanka, and Bangladesh (BECK) project (grant number: 598746-EPP-1-2018-1-LT-EPPKA2-CBHE-JP), Building Resilience in Tropical Agro-Ecosystems (BRITAE) project (grant number: 610012-EPP-1-2019-1-LK-EPPKA2-CBHE-JP) and Strengthening University-Enterprise Collaboration for Resilient Communities in Asia (SECRA) project (grant number: 619022-EPP-1-2020-1-SE-EPPKA2-CBHE-JP) all co-funded by the Erasmus Programme of the European Union. The European Commission support to produce this publication does not constitute an endorsement of the contents which reflect the views only of the authors, and the Commission cannot be held responsible for any use which may be made of the information contained therein.

Institutional Review Board Statement

Not applicable.

Informed Consent Statement

Not applicable.

Data Availability Statement

Not applicable.

Conflicts of Interest

The funders had no role in the design of the study; in the collection, analyses, or interpretation of data; in the writing of the manuscript; or in the decision to publish the results.

References

  1. Underwood, J.; Khosrowshahi, F.; Pittard, S.; Greenwood, D.; Platts, T. Embedding Building Information Modelling (BIM) within the Taught Curriculum Supporting BIM Implementation and Adoption through the Development of Learning Outcomes within the UK Academic Context for Built Environment Programmes; Higher Education Academy: York, UK, 2013. [Google Scholar]
  2. Olowa, T.O.O.; Witt, E.; Lill, I. BIM for Construction Education: Initial Findings from a Literature Review. In Proceedings of the 10th Nordic Conference on Construction Economics and Organization, Tallinn, Estonia, 7–8 May 2019; Volume 2, pp. 305–313. [Google Scholar] [CrossRef]
  3. Olowa, T.; Witt, E.; Lill, I. Building information modelling (BIM)—enabled construction education: Teaching project cash flow concepts. Int. J. Constr. Manag. 2021. [Google Scholar] [CrossRef]
  4. Rose, J.; Scheepers, R. Structuration Theory and Information System Development—Frameworks for Practice. In Proceedings of the 9th European Conference on Information System, Bled, Slovenia, 27–29 June 2001; pp. 217–231. [Google Scholar] [CrossRef] [Green Version]
  5. Giddens, A. The Constitution of the Society, 1st ed.; Polity Press: Cambridge, UK, 1984; ISBN 0745600069. [Google Scholar]
  6. DeSanctis, G.; Poole, M.S. Capturing the Complexity in Advanced Technology Use: Adaptive Structuration Theory. Organ. Sci. 1994, 5, 121–147. [Google Scholar] [CrossRef]
  7. Gopal, A.; Bostrom, R.P.; Chin, W.W. Applying adaptive structuration theory to investigate the process of group support systems use. J. Manag. Inf. Syst. 1992, 8, 45–69. [Google Scholar] [CrossRef]
  8. Orlikowski, W.J. The Duality of Technology: Rethinking the Concept of Technology in Organizations. Organ. Sci. 1992, 3, 398–427. [Google Scholar] [CrossRef] [Green Version]
  9. Ullah, F.; Sepasgozar, S.; Tahmasebinia, F.; Sepasgozar, S.M.E.; Davis, S. Examining the impact of students’ attendance, sketching, visualization, and tutors experience on students’ performance: A case of building structures course in construction management. Constr. Econ. Build. 2020, 20, 78–102. [Google Scholar] [CrossRef]
  10. Casasayas, O.; Hosseini, M.R.; Edwards, D.J.; Shuchi, S.; Chowdhury, M. Integrating BIM in Higher Education Programs: Barriers and Remedial Solutions in Australia. J. Archit. Eng. 2021, 27, 05020010. [Google Scholar] [CrossRef]
  11. Huang, Y. Introducing an Advanced Building Information Modeling Course in Construction Management Programs. In Proceedings of the ASEE Annual Conference and Exposition, Columbus, OH, USA, 24–28 June 2017; American Society for Engineering Education: Washington, DC, USA, 2017; Volume 2017, pp. 15459–15471. [Google Scholar]
  12. Nassar, K. Assessing Building Information Modeling Estimating Techniques Using Data from the Classroom. J. Prof. Issues Eng. Educ. Pract. 2012, 138, 171–180. [Google Scholar] [CrossRef]
  13. Palomera-Arias, R.; Liu, R. BIM laboratory exercises for a MEP systems course in a construction science and management program. J. Inf. Technol. Constr. 2016, 21, 188–203. [Google Scholar]
  14. Solnosky, R.L. Opportunities for BIM to Enhance Structural Engineering Curricula. In Proceedings of the Structures Conference, Fort Worth, TX, USA, 19–21 April 2018; Soules, J.G., Ed.; American Society of Civil Engineers: Fort Worth, TX, USA, 2018; pp. 522–532. [Google Scholar]
  15. Wang, L.; Leite, F. Process-Oriented Approach of Teaching Building Information Modeling in Construction Management. J. Prof. Issues Eng. Educ. Pract. 2014, 140, 04014004. [Google Scholar] [CrossRef]
  16. Zhao, D.; McCoy, A.P.; Bulbul, T.; Fiori, C.; Nikkhoo, P. Building Collaborative Construction Skills through BIM-integrated Learning Environment. Int. J. Constr. Educ. Res. 2015, 11, 97–120. [Google Scholar] [CrossRef]
  17. Boeykens, S.; De Somer, P.; Klein, R.; Saey, R. Experiencing BIM Collaboration in Education. In Proceedings of the 31st International Conference on Education and Research in Computer Aided Architectural Design in Europe (eCAADe), Delft, The Netherlands, 18–20 September 2013. [Google Scholar]
  18. Dossick, C.S.; Lee, N.; Foleyk, S. Building Information Modeling in Graduate Construction Engineering and Management Education. In Proceedings of the Computing in Civil and Building Engineering, Orlando, FL, USA, 23–25 June 2014; American Society of Civil Engineers: Reston, VA, USA, 2014; pp. 2176–2183. [Google Scholar]
  19. Nawari, N.O. The Role of BIM in Teaching Structural Design. In Proceedings of the Structures Congress, Portland, OR, USA, 23–25 April 2015; American Society of Civil Engineers: Reston, VA, USA, 2015; pp. 2622–2631. [Google Scholar]
  20. Lewis, A.M.; Valdes-Vasquez, R.; Clevenger, C.; Shealy, T. BIM Energy Modeling: Case Study of a Teaching Module for Sustainable Design and Construction Courses. J. Prof. Issues Eng. Educ. Pract. 2015, 141, C5014005. [Google Scholar] [CrossRef]
  21. Shenton, H.W., III; Conte, P.R.; Bonzella, J. A first course in BIM for civil engineering majors. In Proceedings of the Structures Congress, Boston, MA, USA, 3–5 April 2014; Bell, G.R., Card, M.A., Eds.; American Society of Civil Engineers (ASCE): Boston, MA, USA, 2014; pp. 1097–1105. [Google Scholar]
  22. Arashpour, M.; Aranda-Mena, G. Curriculum renewal in architecture, engineering, and construction education: Visualizing building information modeling via augmented reality. In Proceedings of the ISEC 2017—9th International Structural Engineering and Construction Conference: Resilient Structures and Sustainable Construction, Valencia, Spain, 24–29 July 2017; ISEC Press: Fargo, ND, USA, 2017. [Google Scholar]
  23. Zhang, J.; Schmidt, K.; Li, H. BIM and Sustainability Education: Incorporating Instructional Needs into Curriculum Planning in CEM Programs Accredited by ACCE. Sustainability 2016, 8, 525. [Google Scholar] [CrossRef] [Green Version]
  24. Liu, F.; Zhao, J.; Zhang, G.; Ju, J. A Tentative Study of the Correlation between BIM and Courses of Construction Management. In Proceedings of the International Conference on Construction and Real Estate Management, Edmonton, AB, Canada, 29 September–1 October 2016. [Google Scholar]
  25. Wu, W.; Luo, Y. Pedagogy and assessment of student learning in BIM and sustainable design and construction. J. Inf. Technol. Constr. 2016, 21, 218–232. [Google Scholar]
  26. Molavi, J.; Shapoorian, B. Implementing an Interactive Program of BIM Applications for Graduating Students. In Proceedings of the ICSDEC, Fort Worth, TX, USA, 7–9 November 2012; American Society of Civil Engineers: Reston, VA, USA, 2012; pp. 1009–1016. [Google Scholar]
  27. Anderson, A.; Dossick, C.; Osburn, L. Curriculum to prepare AEC students for BIM-enabled globally distributed projects. Int. J. Constr. Educ. Res. 2019, 16, 270–289. [Google Scholar] [CrossRef]
  28. Zhang, J.; Zhang, Z.; Philbin, S.P.; Huijser, H.; Wang, Q.; Jin, R. Toward next-generation engineering education: A case study of an engineering capstone project based on BIM technology in MEP systems. Comput. Appl. Eng. Educ. 2021, 30, 146–162. [Google Scholar] [CrossRef]
  29. Leon, I.; Sagarna, M.; Mora, F.; Otaduy, J.P.; Marín-Marín, J.A. BIM Application for Sustainable Teaching Environment and Solutions in the Context of COVID-19. Sustainability 2021, 13, 4746. [Google Scholar] [CrossRef]
  30. de la Torre, R.; Onggo, B.S.; Corlu, C.G.; Nogal, M.; Juan, A.A. The Role of Simulation and Serious Games in Teaching Concepts on Circular Economy and Sustainable Energy. Energies 2021, 14, 1138. [Google Scholar] [CrossRef]
  31. Bozoglu, J. Collaboration and coordination learning modules for BIM education. J. Inf. Technol. Constr. 2016, 21, 152–163. [Google Scholar]
  32. ElZomor, M.; Mann, C.; Doten-Snitker, K.; Parrish, K.; Chester, M. Leveraging Vertically Integrated Courses and Problem-Based Learning to Improve Students’ Performance and Skills. J. Prof. Issues Eng. Educ. Pract. 2018, 144, 04018009. [Google Scholar] [CrossRef]
  33. Ghosh, A.; Parrish, K.; Chasey, A.D. From BIM to collaboration: A proposed integrated construction curriculum. In Proceedings of the 2013 ASEE Annual Conference & Exposition, Atlanta, GA, USA, 23–26 June 2013. [Google Scholar]
  34. Barham, W.; Meadati, P.; Irizarry, J. Enhancing Student Learning in Structures Courses with Building Information Modeling. In Proceedings of the Computing in Civil Engineering, Miami, FL, USA, 19–22 June 2011; American Society of Civil Engineers: Reston, VA, USA, 2011; pp. 850–857. [Google Scholar]
  35. Wu, W.; Kaushik, I. A BIM-based educational gaming prototype for undergraduate research and education in design for sustainable aging. In Proceedings of the Winter Simulation Conference, WSC, Huntington Beach, CA, USA, 6–9 December 2015; Institute of Electrical and Electronics Engineers Inc., Construction Management Program, California State University: Fresno, CA, USA, 2016; Volume 2016, pp. 1091–1102. [Google Scholar]
  36. Teizer, J.; Golovina, O.; Embers, S.; Wolf, M. A Serious Gaming Approach to Integrate BIM, IoT, and Lean Construction in Construction Education. In Proceedings of the Construction Research Congress, Tempe, AZ, USA, 8–10 March 2020; pp. 21–30. [Google Scholar] [CrossRef]
  37. Wang, B.; Li, H.; Rezgui, Y.; Bradley, A.; Ong, H.N. BIM Based Virtual Environment for Fire Emergency Evacuation. Sci. World J. 2014, 2014, 589016. [Google Scholar] [CrossRef] [PubMed]
  38. Park, C.S.; Le, Q.T.; Pedro, A.; Lim, C.R.; Sik Park, C.; Tuan Le, Q.; Pedro, A.; Rok Lim, C. Interactive Building Anatomy Modeling for Experiential Building Construction Education. J. Prof. Issues Eng. Educ. Pract. 2016, 142, 4015019. [Google Scholar] [CrossRef]
  39. Ku, K.; Mahabaleshwarkar, P.S. Building interactive modeling for construction education in virtual worlds. J. Inf. Technol. Constr. 2011, 16, 189–208. [Google Scholar]
  40. Shen, Z.; Jiang, L.; Grosskopf, K.; Berryman, C. Creating 3D web-based game environment using BIM models for virtual on-site visiting of building HVAC systems. In Proceedings of the Construction Research Congress, West Lafayette, IN, USA, 21–23 May 2012. [Google Scholar]
  41. Wang, J.; Wang, X.; Shou, W.; Xu, B. Construction Innovation Integrating BIM and augmented reality for interactive architectural visualisation Article information. Constr. Innov. 2016, 14, 453–476. [Google Scholar] [CrossRef]
  42. Abdirad, H.; Dossick, C.S. BIM curriculum design in architecture, engineering, and construction education: A systematic review. J. Inf. Technol. Constr. (ITcon) 2016, 21, 250–271. [Google Scholar]
  43. Amr, K. Learning through Games: Essential Features of an Educational Game. Ph.D. Thesis, Syracuse University, Syracuse, NY, USA, 2012. [Google Scholar]
  44. Alshanbari, H.; Issa, R.R.A. Use of Video Games to Enhance Construction Management Education. In Proceedings of the Computing in Civil and Building Engineering, Orlando, FL, USA, 23–25 June 2014; American Society of Civil Engineers: Reston, VA, USA, 2014; pp. 2135–2142. [Google Scholar]
  45. Torrente, J.; Moreno-Ger, P.; Martínez-Ortiz, I.; Fernandez-Manjon, B. Integration and deployment of educational games in e-learning environments: The learning object model meets educational gaming. Educ. Technol. Soc. 2009, 12, 359–371. [Google Scholar]
  46. Moreno-Ger, P.; Burgos, D.; Torrente, J. Digital Games in eLearning Environments. Simul. Gaming 2009, 40, 669–687. [Google Scholar] [CrossRef]
  47. Marchiori, E.J.; Serrano, Á.; Del Blanco, Á.; Martinez-Ortiz, I.; Fernández-Manjón, B. Integrating domain experts in educational game authoring: A case study. In Proceedings of the 2012 IEEE Fourth International Conference On Digital Game And Intelligent Toy Enhanced Learning, Takamatsu, Japan, 27–30 March 2012; pp. 72–76. [Google Scholar] [CrossRef]
  48. Karshenas, S.; Haber, D. Developing a Serious Game for Construction Planning and Scheduling Education; American Society of Civil Engineers: Reston, VA, USA, 2012; pp. 2042–2051. [Google Scholar]
  49. Shen, Z.; Jiang, L. An Augmented 3D iPad Mobile Application for Communication, Collaboration and Learning (CCL) of Building MEP Systems. In Proceedings of the Computing in Civil Engineering, Clearwater Beach, FL, USA, 17–20 June 2012; pp. 204–212. [Google Scholar]
  50. Turner, J.R.; Morris, M.; Atamenwan, I. A Theoretical Literature Review on Adaptive Structuration Theory as Its Relevance to Human Resource Development. Adv. Dev. Hum. Resour. 2019, 21, 289–302. [Google Scholar] [CrossRef]
  51. Chen, B.; Liu, A.M.M.; Hua, Y. An exploration of the interaction between BIM technology and the business process of a construction organization in BIM implementation. WIT Trans. Built Environ. 2017, 169, 177–189. [Google Scholar]
  52. Huang, C.; Zha, X.; Yan, Y.; Wang, Y. Understanding the Social Structure of Academic Social Networking Sites: The Case of ResearchGate. Libri 2019, 69, 189–199. [Google Scholar] [CrossRef]
  53. Fuchs, C. Adapting (to) Agile Methods: Exploring the Interplay of Agile Methods and Organizational Features. In Proceedings of the 52nd Hawaii International Conference on System Sciences, Grand Wailea, HI, USA, 8–11 January 2019; Bui, T.X., Ed.; HICSS: Maui, HI, USA, 2019; pp. 7027–7036. [Google Scholar]
  54. Andollo, A.; Aseey, A.A.A.; Rambo, C.M. Influence of Availability of Information Communication and Technology Infrastructure on the Use of Student Management Information System in Teacher Training Programmes by Distance Learning in Universities in Kenya. Int. J. Arts Soc. Sci. 2020, 3, 334–347. [Google Scholar]
  55. Ma, Z.; Ma, J. Formulating the application functional requirements of a BIM-based collaboration platform to support IPD projects. KSCE J. Civ. Eng. 2017, 21, 2011–2026. [Google Scholar] [CrossRef]
  56. Creswell, J.W. Qualitative Inquiry and Research Design: Choosing among Five Approaches, 3rd ed.; Knight, V., Ed.; SAGE Publications, Inc.: Los Angeles, CA, USA, 2013; ISBN 978-1-4129-9530-6. [Google Scholar]
  57. Witt, E.; Kähkönen, K. A BIM-Enabled Learning Environment: A Conceptual Framework. In Emerald Reach Proceedings Series; Emerald Publishing Limited: West Yorkshire, UK, 2019; Volume 2, pp. 271–279. [Google Scholar]
  58. Urquhart, C. The Evolving Nature of Grounded Theory Method: The Case of the Information Systems Discipline. In The SAGE Handbook of Grounded Theory; Bryant, A., Charmaz, K., Eds.; SAGE Publications Ltd.: London, UK, 2012; pp. 339–359. ISBN 9781412923460. [Google Scholar]
  59. Glaser, B.G.; Strauss, A.L. The Discovery of Grounded Theory: Strategies for Qualitative Research; AldineTransaction: New Brunswick, NJ, USA; London, UK, 1967; ISBN 0-202-30260-1. [Google Scholar]
  60. Bataw, A. On the Integration of Building Information Modelling in Undergraduate Civil Engineering Programmes in the United Kingdom. Ph.D. Thesis, University of Manchester, Manchester, UK, 2016. [Google Scholar]
  61. Barison, M.B.; Santos, E.T. Advances in BIM Education. In Transforming Engineering Education; Mutis, I., Fruchter, R., Menassa, C.C., Eds.; American Society of Civil Engineers: Reston, VA, USA, 2018; pp. 45–122. [Google Scholar]
  62. Olowa, T.; Witt, E.; Lill, I. Conceptualising building information modelling for construction education. J. Civ. Eng. Manag. 2020, 26, 551–563. [Google Scholar] [CrossRef]
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Figure 1. Adaptive Structuration Theory (AST) Framework (DeSanctis and Poole (1994)). Propositions: P1: AITs provide social structures that can be described in terms of their features and spirit. To the extent that AITs vary in their spirit and structural features sets, different forms of social interaction are encouraged by the technology. P2: Use of AIT structures may vary depending on the task, the environment, and other contingencies that offer alternative sources of social structures. P3: New sources of structure emerge as the technology, task, and environmental structures are applied during the course of social interaction. P4: New social structures emerge in group interaction as the rules and resources of an AIT are appropniated in a given context and then reproduced in group interaction over time. P5: Group decision processes will vary depending on the nature of AIT appropriations. P6: The nature of AIT appropriations will vary depending on the group’s internal system. P7: Given AIT and other sources of social structure, ideal appropriation processes, and decision processes that fit the task at hand, then desired outcomes of AIT use will result.
Figure 1. Adaptive Structuration Theory (AST) Framework (DeSanctis and Poole (1994)). Propositions: P1: AITs provide social structures that can be described in terms of their features and spirit. To the extent that AITs vary in their spirit and structural features sets, different forms of social interaction are encouraged by the technology. P2: Use of AIT structures may vary depending on the task, the environment, and other contingencies that offer alternative sources of social structures. P3: New sources of structure emerge as the technology, task, and environmental structures are applied during the course of social interaction. P4: New social structures emerge in group interaction as the rules and resources of an AIT are appropniated in a given context and then reproduced in group interaction over time. P5: Group decision processes will vary depending on the nature of AIT appropriations. P6: The nature of AIT appropriations will vary depending on the group’s internal system. P7: Given AIT and other sources of social structure, ideal appropriation processes, and decision processes that fit the task at hand, then desired outcomes of AIT use will result.
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Figure 2. Research process adopted.
Figure 2. Research process adopted.
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Figure 3. Characteristics of participants with respect to organization type, sub-sector, and location.
Figure 3. Characteristics of participants with respect to organization type, sub-sector, and location.
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Figure 4. Matrix of functional categorization of BLE features.
Figure 4. Matrix of functional categorization of BLE features.
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Figure 5. Concept map showing the sources of structures in a BLE.
Figure 5. Concept map showing the sources of structures in a BLE.
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Table
Table 1. Processes based on BIM structures.
Table 1. Processes based on BIM structures.
#Identified and Isolated Functional RequirementsExplanation of Corresponding Structural Feature of BLE
1BIM model viewingBLE should enable BIM model viewing to allow learners to visually explore the object of their learning experiences.
2BIM model data extractionInput data for any learning task should be available in the model and be accessible to and conveniently extractible by learners.
3BIM model sharingAbility to share models and thus communicate around models.
4BIM model version managementAbility to track and manage different BIM model versions.
5BIM model editingAbility to edit BIM models. If a meaningful learning task is performed, it will generate further data, which needs to be input back into the model (for example, scheduling tasks will elaborate a model from a 3D to a 4D model).
6BIM model collaborative viewing and editingAbility to collaboratively view and edit models. The abovementioned functions of viewing and editing should, ideally, be collaboratively performed in groups.
7Repository of example BIM modelsThe BLE should include a repository or library of high quality, consistent, and error-free models.
8Common Data Environment (CDE) for project dataAbility to host project data consistently and persistently. The learning objects are projects, and project data is not limited to that which is incorporated into the BIM model. Thus, a Common Data Environment is a necessary attribute.
9Simulation of the project development process (realistic BIM workflow, key stakeholder roles, etc.)Ability to simulate a realistic project development process. Learning experiences will attempt to simulate real life projects, so realistic stakeholder roles and BIM-based workflows will need to be supported by the BLE.
10BIM model creatingAbility to create BIM models. Although most BLE tasks are envisaged as starting with an existing model already created, it could be useful to have access through the BLE to model creating tools also.
11BIM model checkingAbility to check BIM models—incorporating/integrating checking functionality within/with the BLE.
12Extended reality (XR) functions: Augmented Reality (AR)/Mixed Reality (MR)/Virtual Reality (VR)Ability to integrate extended reality functions. To improve visualization and communication, additional XR functionality could be useful.
13BIM object creation and editingAbility to create BIM objects.
14Group formationAbility to create groups. The BLE must enable group formation and group work, as learners will typically work in stakeholder groups.
15Collaboration in groupsAbility to communicate and work together in groups while engaged in learning.
16Collaboration between groupsThe possibility for groups to communicate and interact with one another, since learner groups will tend to represent stakeholders and stakeholders need to interact for project development.
17Instructor access and monitoring of groups and group workAbility to create instructor privileges for both access and group work monitoring. Instructors will need to interact with groups (as well as with individuals).
18Collaborative viewing and editing of documents and spreadsheetsThe collaborative viewing and editing of documents and spreadsheets (not only of BIM models) is essential in carrying out learning tasks in groups.
19Live interactions between usersAbility to engage in live interactions among users. To improve the convenience and time efficiency of instruction and group work.
20Recording of group sessions and lessonsAbility to record group sessions and lessons. This functionality would be useful to both learners and instructors (and is increasingly essential in mitigating COVID-19-related learning constraints).
21Registration of users (learners/instructors)Ability to register and deregister users. As the BLE is a learning environment, this is an essential administrative feature.
22Data security/password protectionCapabilities for securing users’ data and information especially in relation to registered users and their activities.
23Hosting of different coursesCapable of hosting multiple courses. Learning experiences will be provided as modules/courses in the BLE.
24File upload, storage, download, sharing, editingAbility to upload, store, download, share, and edit files for course content and access to materials.
25Video playbackAbility to playback videos—for course content as well as enabling access to external (video) materials.
26Linking to extra learning materialsAbility to link to additional learning materials—for course content and access to (all kinds of) materials.
27Individual learners’ storage for learning materialsAbility to store individual’s learning materials. Ideally within the BLE and on individual learners’ devices.
28Links between courses.Ability to link multiple courses to build on previous courses’ results and to track impacts on/inputs to future courses. This would encourage/enable continuity and connections between different/contiguous learning experiences.
29Assessment/gradingAbility to assess and grade learners—grade entering for individuals/groups, grade book. Needed for learning administration, quality, and learner assessment purposes.
30Questionnaire creation, completing, submissionAbility to create and analyses questionnaires, quizzes, and polls. As part of a formative and summative assessment of learning.
31Student feedbackAbility to obtain feedback from users and learners. For quality assurance and improvement purposes.
32Gamification supportCapable of integrating gamification functions. Incorporating competition enhancements as a way of motivating learners—high scores/leader boards, etc.
33Integration of platform with external systems/businessAbility to integrate with external platforms—for example, with institutional study information systems.
Table
Table 2. Revised and validated structural features.
Table 2. Revised and validated structural features.
Structural FeatureMeanRII
Ability to obtain feedback from users and learners (#31)4.541
Ability to input, access, and extract learning task data (#2)4.472
Ability to create and manage within groups (#15)4.472
Ability to simulate project development process (#9)4.444
Ability to link multiple courses to build on previous courses’ results and to track impacts on/inputs to future courses (#28)4.444
Ability to integrate with external platforms or going concerns (#33)4.444
Ability to host project data in persistently (#8)4.357
Ability to secure and protect users’ data and information (#22)4.357
Ability to collaboratively view and edit BIM models (#6)4.289
Ability to visually explore learning objects in BIM models (#1)4.2710
Ability to share and communicate around models (#3)4.2710
Ability to upload, store, download, share, and edit files (#24)4.2512
Ability to create instructor privileges for both access and group work monitoring (#17)4.1313
Ability to host multiple courses (#23)4.1313
Ability to check BIM models against process and regulatory standards (#11)3.9415
Ability to collaboratively view and edit different document file formats (#18)3.9216
Ability to create and analyze questionnaire, quizzes, and polls (#30)3.9216
Ability to playback videos (#25)3.9216
Capable of integrating gamification functions (#32)3.7519
Capacity to accommodate a repository or library of high quality, consistent, and error-free models (#7)3.7420
Ability to create and manage between groups (#16)3.7121
Ability to create groups (#14)3.6722
Ability to edit BIM models (#5)3.6223
Ability to engage in live interactions among users (#19)3.6223
Ability to register and deregister users (#21)3.5825
Ability to integrate extended reality functions (#12)3.4026
Ability to evaluate learners (#29)3.4026
Ability to manage different BIM model versions (#4)3.3328
Ability to create BIM models (#10)3.2229
Ability to record group sessions and lessons (#20)3.0530
Ability to create BIM objects (#13) ***
Ability to store individual’s learning materials (#27) ***
Ability to link to additional learning materials (#26) ***
* Items not included in the focus group questionnaire as these emerged from focus group suggestions for additional BLE features.
Table
Table 3. Spirit of the proposed BLE.
Table 3. Spirit of the proposed BLE.
#Spirit AttributesInterview Quotations Implying Spirit of Proposed BLEParticipant (P)/Country (E = Estonia; F = Finland; I = Italy)
1Collaboration“…the involvement of stakeholders”P.6/E
“…I hope that our school colleagues …will join us because they can use our e-course objects too for their learning subject material for showing and explaining”P.4/E
2Active learning“…more involvement by the students”P.6/E
“…for people who’re just joining the company… they haven’t really seen any… situations on site.”P.8/E
3Integrated learning“…that they understand the impact of various decisions at the early phases of the project.”P.6/E
“…possibilities to take the quantities of the volumes…”P.7/E
“…for architectural definition and building package analysis for teaching activities”P.13/I
“…to teach data visualization including some analysis.”P.9/E
“…to use BIM in an integrated way by all the actors involved in the process.”P.10/I
“Viewing the model of job site and impact of future decision of site safety.”P.17/I
“Quantities and other information-take-offs from digital models”P.22/F
4Adaptive/Personalized learning “…students need related knowledge, and it does not matter which specialty is discussed because all the information is separated … and BIM is very good example of how we can join different line subject with one another and how it will be done for student.”P.9/E
“…need some. Interactions with the courses so if one course finishes with some stage then they will use the same…”P.6/E
5Improvement (of project processes)“…improve our [training] process”P.8/E
“…to use a 3D visualization”P.7/E
“…see the clashes or the mistakes that are in the design”P.7/E
“…exploring and evaluating key areas of innovation and skills through the BIM methodology.”P.11/I
“Marketing with visualizations and interactive 3D Product design (design management)”P.26/F
“Project planning and management (cost estimating, scheduling, purchasing, task planning, project control)”P.26/F
“Compliance checking of BIM models as a part of quality assurance”P.28/F
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Olowa, T.; Witt, E.; Morganti, C.; Teittinen, T.; Lill, I. Defining a BIM-Enabled Learning Environment—An Adaptive Structuration Theory Perspective. Buildings 2022, 12, 292. https://doi.org/10.3390/buildings12030292

AMA Style

Olowa T, Witt E, Morganti C, Teittinen T, Lill I. Defining a BIM-Enabled Learning Environment—An Adaptive Structuration Theory Perspective. Buildings. 2022; 12(3):292. https://doi.org/10.3390/buildings12030292

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Olowa, Theophilus, Emlyn Witt, Caterina Morganti, Toni Teittinen, and Irene Lill. 2022. "Defining a BIM-Enabled Learning Environment—An Adaptive Structuration Theory Perspective" Buildings 12, no. 3: 292. https://doi.org/10.3390/buildings12030292

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