BIM implementation for Nigeria’s polytechnic built environment undergraduates: challenges and possible measures from stakeholders

2.1 Building information modelling relevance

The relevance of BIM cannot be over-emphasised in the built environment. BIM incorporation into HEI teaching is vital in preparing trained graduates for future competitive work in the built environment (McGraw Hill, 2010). This was corroborated by Han and Bedrick (2015) and may threaten BIM implementation and sustainability without incorporating it into the higher education curriculum. Implementing a BIM construction project demands new components of discipline professionals compared to conventional construction projects (Puolitaival and Forsythe, 2016). BIM education flourishes in HEIs built environment programmes (Lee and Dossick, 2012; Panuwatwanich et al., 2013; Shelbourn et al., 2017). The built environment stakeholders should use more BIM ultimate advantages (Ghaffarianhoseini et al., 2017).

In Nigeria, few studies (Abdullahi et al., 2011; Abubakar et al., 2013; 2014; Fung et al., 2014; Olanrewaju et al., 2020; 2021) have been conducted on BIM implementation in the construction industry. Abdullahi et al. (2011) appraised BIM application and discovered a low awareness of BIM presence in the built environment industry. Abubakar et al. (2013) assessed the willingness of building design organisations to implement BIM software and found that design organisations are willing to fulfil BIM applications in their practices. Abubakar et al. (2014) focused on BIM awareness level and encumbrances to its application from Nigeria’s contractors’ viewpoints. Olatunji et al. (2010) and Zhou et al. (2018) affirmed that BIM could eliminate components of conventional QS activities. This includes bills of quantities production that may not be free from human errors. RICS (2014) and Zhou et al. (2018) avowed that BIM could enhance efficiency and promote integrated collaboration in the bill of quantities preparation. Thus, it enhances the speed with better quality, free from errors. BIM can potentially inspire the QS profession, a component of the built environment, regarding cost-effectiveness and value of construction processes (Pittard and Sell, 2017). Thomas (2010) identified reasons BIM should be encouraged. This includes:

• 30% of construction projects do not meet the budget;

• 37% of materials used in construction projects convert to waste;

• 10% of the project cost is because of change orders; and

• 38% of carbon emissions are from buildings.

2.2 Hindrances facing building information modelling implementation in higher education institutions

Digitalisation, including BIM technology and other drivers of the fourth industrial revolution (4IR) technologies, faces many encumbrances, especially in developing countries. Lack of basic infrastructure, insufficient human resources, lax legislation and policies, absence of a political will, poor awareness and stakeholder engagement and government attitude to support were identified as the hindrances facing digitalisation (Oesterreich and Teuteberg, 2016; Samsor, 2020). BIM is a component of digitalisation. Demirkesen and Tezel (2021) found high implementation costs, unclear usage benefits and resistance to change as the encumbrances of Industry 4.0 in the built environment. Penmetsa and Bruque-Camara (2021) classified the hindrances associated with digital into people related (scarcity, digital illiteracy, culture, adoption, awareness, citizen-centric focus and training and education) and technology related (digital infrastructure, IT standards, system integration, security and cyber insecurity and innovation ecosystem). Others are policy related (bribery and corruption, ICT systems and cyber security risks); institutional related (funds, government support, political willingness and leadership, organisational structure and mission); and economic related (high cost, economic value, funding and software maintenance). Sustainability-related encumbrances were the last categorised, including education, access to technology, digital literacy, inadequate education and power supply. Wong and Yew (2017) examined obstacles to executing BIM technology in Sarawak’s QS organisations and found insufficient training and knowledge and high initial cost as the top-ranked hindrances.

Implementing BIM is challenging (Vass and Gustavsson, 2017), especially in developing country’s higher educational institutions. Adamu and Thorpe (2016) argued that in higher educational institutions, especially universities, can access BIM training freely. It is economically sound to invest in undergraduate students to mitigate future issues of lack of funds for training and upskilling associated with the BIM adoption (Eadie et al., 2015). Despite this benefit, there are practical challenges. Underwood and Ayoade (2015) and Puolitaival and Forsythe (2016) identified that lax upskilling and reskilling, inadequate expertise among staff and regular updates as BIM constantly evolves is germane. Sabongi (2009) and Puolitaival and Forsythe (2016) emphasised the issues connected with the existing curriculum and the inability to integrate BIM courses. This is because of the over-crowded existing curricula. Gier (2015) identified inadequate educational resources and a lack of institutional support. This is compounded by inadequate staff expertise. BIM technology evolves quickly and may confront students, instructors/lecturers (Sacks and Pikas, 2013). In all extant literature, besides the geographical gap, none addressed the challenges of a developing country’s technical-based higher educational institutions. Technical-based higher educational institution graduates are critical players in driving a nation’s economy.

Nigeria’s built environment industry in West Africa is the largest (Saka et al., 2020). This comprises skilled and unskilled workers. Studies such as Olanrewaju et al. (2020), Ebekozien and Aigbavboa (2021) and Ebekozien et al. (2022a; 2022b) found that the industry is slow in adopting emerging technologies associated with the 4IR technologies. This includes BIM, robotics, simulation, 3D, blockchain, big data, etc. Olanrewaju et al. (2020) discovered that the slow approach to adopting innovative technologies had affected the full implementation of emerging technologies like BIM. Onungwa et al. (2017) found low technical knowledge and poor BIM awareness as critical factors. Their findings validate the work of Anifowose et al. (2018). Anifowose et al. (2018) found that BIM awareness level is about 40% among built environment practitioners, even with the enormous benefits, which is not encouraging. This can be attributed to insufficient government programmes and policies, high cost of implementation, software accessibility issues and inadequate knowledge (Olanrewaju et al., 2020). Many architectural, mechanical and electrical drawings are generated with 2D CAD, while few use 3D for visualisation (Hamma-adama et al., 2017). Babatunde et al. (2021), Olanrewaju et al. (2020) and Ebekozien et al. (2022b) found that apart from the absence of policies to enforce or promote the use of BIM, the Nigerian government has not created an enabling environment for BIM adoption to grow compared to the UK, USA and Australia. It was found that though the level of awareness among construction professionals has increased, reaching maturity is far, as it experiences hindrances connected with BIM usage. The Eko Atlantic City project has fully implemented BIM in Nigeria (Anifowose et al., 2018). The number is not encouraging and calls for concern.

4.1 Theme one: building information modelling relevance

In this sub-section, the study’s interviewees agree that BIM technology relevance via Revit cannot be over-emphasised in the built environment of polytechnic undergraduates in the 21st century driven by digitalisation. This is key and timely in the history of Nigeria because more middle-level workforce via polytechnic training in technology, applied science and commerce and management in practical knowledge and theory with support from research are needed to drive the economy towards sustainable technological development (P1, P9, P25 and P34). P25 says, “ […] the Nigerian polytechnics stand out when training and developing their undergraduates for self-reliant manpower for sustainable technological development because of the vast practical knowledge for meaningful contribution to local and national development. Thus, BIM will enhance this role appropriately […]” Findings show that BIM can enhance the built environment practitioners’ efficiency and productivity (Participants P4, P9, P13, P18 and P34). Among the testimony of BIM technology application via Revit are reliable and more accurate work and immediate details with an alternative approach. P13 says, “[…] I am a quantity surveyor by background. I can tell you categorically that BIM (Revit Cost) enhances my duties regarding contract administration, pre-tender documentation, estimating and cost planning, procurement advice, measurement, preparation of bills of quantities, interim valuation preparation, and material schedule charts. Other benefits are improved cost database management, rapid identification of design changes, data storage in the centrally coordinated model, improved visualisation, and reduced requests for information […]” Findings agree with Olatunji et al. (2010), Zhou et al. (2018) and Babatunde et al. (2018). They affirmed that BIM could eliminate components of conventional QS activities. BIM can enhance efficiency and promote integrated collaboration in main QS functions (Zhou et al., 2018).

Findings show that one of the benefits of Revit software is the multiple usages (majority). Participant P14 says, “[…] we have the Revit Architecture for architectural model and applied by an architect for design and other related works. Also, there is Revit MEP for the mechanical, electrical, and plumbing (MEP) model and applied by mechanical, electrical, and plumbing experts for MEP model and other related works. Lastly is the Revit Cost for resources and cost model and applied by quantity surveyor for costing and estimating and other related works […]” Findings agree with Eastman et al. (2011), Kushwaha (2016) and Olugboyega (2017). Eastman et al. (2011) and Kushwaha (2016) asserted that BIM offers solutions to several problems inherent in the built environment. The technology is unique because the industry is dynamic. Olugboyega (2017) developed the framework for creating a BIM environment and categorised the various BIM authorising software technologies. “[…] BIM technology via Revit benefits training Nigeria’s built environment polytechnic undergraduates cannot be challenged. Integratng BIM education into the curriculum will improve sustainability practices on construction projects […]” said Participant P24. Findings agree with Olawumi and Chan (2018). They examined the perceived advantages of integrating BIM and sustainability practices in projects. Olawumi and Chan (2018) found that BIM could advance project quality and proficiency and simulate building performances.

Participant P16 says, “[…] BIM technology knowledge via Revit could be used to promote the training of middle-level workforce in Nigeria’s built environment polytechnics. The truth is that polytechnic undergraduates lag behind their university counterparts. This technology can create an atmosphere for information model development, interoperability, integration and collaboration, and healthy communication for a construction project […]” Findings agree with Fung et al. (2014). They emphasised a paucity of studies into BIM potentials in the QS profession in HEIs. Findings show that this is pronounced in Nigerian polytechnics offering built environment programmes. The polytechnic undergraduates should be more attentive to BIM education and its application (Participants P9, P17, P20, P24, P24, P25, P35 and P37). This is because polytechnic education focuses on technical and practical sciences training rather than theory based. This is where most middle-level workforce are trained and the pillar of any economy. The engine room of a vibrant economy is based on technology and innovation (Participants P1, P10, P15, P19, P25, P30 and P34). BIM education and application will enhance productivity. Findings reveal that BIM via Revit will inspire the built environment undergraduates in their future careers. Findings agree with Pittard and Sell (2017). They opined that BIM could inspire every aspect of the QS profession regarding cost-effectiveness and value of construction processes. The QS profession is a component of the built environment professions. “[…] one cannot use Revit (BIM) to compare conventionally (e.g., manual) concerning project development, precise, actionable costing information that defines during preliminary project phases. Apart from the time spent, not less than 50%, this process is highly disposed to error and could enhance construction project inaccuracies […]” said Participant P13. Results agree with Nagalingam et al. (2013). They acknowledged that besides cost savings, BIM optimises construction project resources. The technology is all-inclusive with a teaching tool for key built environment professionals’ functions (P4, P8, P13, P17, P19, P23, P25, P30, P33 and P37).

4.2 Theme two: issues hindering building information modelling implementation in higher education institutions (polytechnics)

In promoting the applications of BIM technology in polytechnics, this sub-section attempted to discover the perceived issues hindering BIM technology education in Nigerian polytechnics. One pertinent point is the identified issues hindering BIM implementation technology. The issues were grouped into government/polytechnic regulatory agency (NBTE)-related, polytechnic management-related and polytechnic undergraduate student-related hindrances in Nigeria’s built environment context, as presented in Table 2. A total of 24 main issues emerged from the study. From the 24 issues, 21 were government/polytechnic regulatory agency related, 24 were polytechnic management related and 7 were polytechnic undergraduate student related. Table 2 shows that some identified issues cut across the three groups: low awareness of BIM, lax BIM collaboration between industry professionals and the academic world and resistance to change. Others are unclear advantages and gains to many stakeholders, high-security risks regarding data protection and cyber issues, insufficient investment in research and development and financial constraints. The government and the polytechnic managers need to demonstrate more leadership and political willingness for polytechnic BIM education (P6, P9, P16, P26, P28, P30 and P34). P34 says, “[…] in many developed and some developing countries that have recorded progressive output in education digitalisation, the government leads and gives direction with support to drive education digitalisation from HEIs to practices. This is not the case in many Nigerian polytechnics. I know that in some schools, some polytechnic students enrol for training in a private outfit. Also, few schools’ students were forced to pay a certain amount to be eligible for BIM training […]” The concerned schools rebuffed these allegations. Findings agree with Smart Nation and Digital Government Office (2018), and it was reported that the Singaporean Government fashioned an enabling environment and maintained the thriving of digitalisation via many programmes and platforms. “[…] thus, the government refusal or lax approach to creating the enabling environment for stakeholders to promote BIM is one critical issue. I am not against BIM education; can the graduates practice BIM fully if the enabling environment is not there? This brings us back to one of the root issues, government should lead […]” said Participant P3. Findings agree with Babatunde et al. (2021), Olanrewaju et al. (2020) and Ebekozien et al. (2022b). They discovered that apart from the absence of policies to enforce or promote the use of BIM, the Nigerian government has not created the enabling environment for BIM adoption to grow compared to the UK, USA and Australia. The outcome has affected the rate of construction projects reaching maturity regarding BIM usage (Anifowose et al., 2018). This is a call for concern. Participant P12 alleges academic staffers are encouraged to self-sponsorship for BIM training in some schools. This is not encouraging. (P3, P12 and P15).

“[…] many young built environment graduates, especially engineers, architects, and quantity surveyors from polytechnic backgrounds, cannot use the BIM platform to manage projects. The level of the novice is alarming […]. We operate a consortium, and it cuts across. The root cause is that BIM technology was not integrated into their curriculum […]. Come to think of it, how many instructors/lecturers understand the basic concept of BIM? These issues should be addressed to increase the chances of polytechnic graduates getting competitive jobs because the world is now global […]” said Participant P17.

Results agree with Hamma-adama et al. (2017) and Babatunde and Ekundayo (2019). Hamma-Adama et al. (2017) discovered that few design team members use 3D for visualisation while the majority still generate their drawings via 2D CAD. The many functionalities of BIM, such as clash detection, energy analysis and cost estimation, are left unexploited. Babatunde and Ekundayo (2019) found that the high training cost of academic staff, insufficient competent staff to teach BIM, absence of accreditation standards within a curriculum and challenging BIM for people with weak IT skills were among the top ten ranked hindrances. More work is expected from the root, BIM education should be encouraged across all built environment HEIs, especially polytechnics that train most of the middle-level workforce for the economy (Participants P6, P14, P18, P22, P24, P25, P33 and P37). There is a long way to go concerning BIM implementation. The polytechnic management should revamp ICT centres in their institutions to enhance BIM implementation.

4.3 Theme three: solutions to promote building information modelling technology

From the extensive reviewed literature and results, BIM education technology is one driver of construction digitalisation that is unmatched if well implemented for the built environment polytechnic undergraduates because of what the training institution stands and represents. Despite the enormous advantages of BIM technology usage, the level of BIM technology education and awareness in built environment programmes in Nigerian polytechnics is abysmal. This calls for concerns. During the pre-primary data collection, the researchers found that some senior academic staffers and final-year students need help understanding the concept of BIM. This exercise ensured that only knowledgeable persons regarding BIM and polytechnic education were engaged in the virtual interviews. Therefore, the sub-section provides measures to promote BIM technology via Revit usage in Nigeria’s built environment polytechnic undergraduates’ training and digitalisation. The theme generated six sub-themes/measures. This includes government/regulatory agencies (NBTE) and polytechnic managers (Rectors), an institutional framework to drive policy and programme, ICT infrastructure, training (upskilling and reskilling), collaboration and joint venture with stakeholders and sincerity in research investment.

Participant P8 says, “[…] the regulatory agencies, polytechnic managers, and the academic staff should agree to embrace BIM education as one way to revamp the economy and make the built environment polytechnic graduates more employable in the 21^st century. This can be done by developing an institutional implementation framework integrating BIM education into all vital courses. This is presently missing. Also, the government policy support to enhance accreditation standards and requirements should be backed with feasible financial budget […]” Findings show that emphasis should be on awareness and practical implementation concurrently (P12, P16, P19, P23, P30 and P37). Besides awareness, achieving a reasonable record in BIM education in Nigerian polytechnics requires an integrated collaboration between academia/government, industry and students (P16). Joint ventures and collaboration are pertinent, with the government leading as the team leader. Local and international software developers should be engaged via government efforts to make the tool readily available and affordable for the end users. “[…] this will motivate construction practitioners to patronise and embrace future new construction technologies knowing that support will come from the government regarding usage and cost […]” said P33. Findings agree with Babatunde et al. (2021) and affirmed that government involvement via support demonstrates a significant enabler of BIM implementation.

Most participants agree that training (upskilling and reskilling) of academic staff in the built environment to transfer BIM education knowledge (practical and theory) to the students is germane in promoting Nigeria’s built environment polytechnic undergraduates’ training and digitalisation. Participant P12 says, “[…]. BIM education training should be a continuous exercise. This is because the software is dynamic and can be upgraded. In my institution, not up to one-tenth of the academic staff understand BIM nomenclature. So, you do not expect them to teach it even if the curriculum says so without adequate training. The era of imposing charges on staff to pay for such training should be discouraged because it is anti-motivator […].” As previously discussed, understanding BIM technology via the Revit mechanism is key and has many benefits. Findings agree with Lee and Dossick (2012), Ayinla and Adamu (2018) and Oyewole and Dada (2019). Lee and Dossick (2012) recommended that academic staffers should stay in contact with the industry to reflect the trends and practices. Ayinla and Adamu (2018) found that training will answer hindrances faced by several countries and help them acquire the correct skills for BIM implementation. Oyewole and Dada (2019) found that BIM technology training could enhance integrated construction project delivery.

BIM technology is a capital-intensive project. Thus, collaboration is required from all stakeholders to get it right. “[…]. from ICT infrastructure to software procurement and maintenance requires high cost and complicated with scarcity of specialists […]” Government and private organisations should integrate into this regard (P2, P15, P25 and P33). Results agree with Khoshfetrat et al. (2020), and it was suggested that apart from collaborative efforts in training BIM software users, the government, software developers and construction companies should increase their investment in BIM technologies. The technology has output augmentation capacities. Findings agree that polytechnic managers should do more concerning ICT infrastructure to enhance BIM technology education. “[…] a computer-friendly environment is important for BIM implementation. This includes connectivity, stable power supply, standby alternative, and smart infrastructure to align with BIM nomenclature […]” said Participant P20.

5.1 The study’s theory implication

The study examined the relevance and perceived issues hindering the implementation of BIM technology via Revit and offered measures to promote BIM usage in Nigeria’s built environment polytechnic undergraduates’ training and digitalisation. Findings reveal that BIM technology’s relevance via Revit in training Nigeria’s built environment polytechnic undergraduates and improving integrated project delivery cannot be overstated. This indicates that the technology is pertinent to developing the built environment stakeholders’ collaboration from HEIs to practices. Hence, there is a need for more training in Nigeria’s built environment polytechnic undergraduates using BIM technology. Twenty-four issues emerged as the possible factors hindering BIM technology implementation in training Nigeria’s built environment polytechnic undergraduates. The 24 issues were grouped into government/polytechnic regulatory agency (NBTE)-related, polytechnic management-related and polytechnic undergraduate student-related hindrances in Nigeria’s built environment context, as presented in Table 2. Besides the previous studies not covering polytechnic undergraduates, categorisation of perceived issues was missing in past studies and formed part of the theoretical implications. The findings show that BIM technology can improve cost database management and enhance integrated collaborative measurements. Also, BIM provides effective and efficient automatic quantification of contract documents and improved visualisation for a better understanding of designs. Exposing the intending middle-level manpower to the pre-career phase (polytechnic undergraduates) while still in HEIs is vital. The study will fill this gap.

5.2 The study’s practice implication

Regarding the study’s practical/managerial implication, the study provides polytechnic management, polytechnic regulatory agencies, built environment researchers, construction experts and policymakers with a detailed list of issues hindering the implementation of BIM technology via Revit in training Nigeria’s built environment polytechnic undergraduates. The findings and recommendations might benefit polytechnic managers, policymakers, regulatory agencies, researchers and other stakeholders to start looking beyond BIM technology applications and focus on policies and programmes that will promote the full digitalisation of Nigeria’s built environment programmes in the polytechnic. The policymakers and professionals might benefit from the identified issues and the measures to promote Nigeria’s built environment polytechnic undergraduates’ training and digitalisation. It forms part of the study’s practical implication. From the international perspective, other countries with similar perceived BIM technology implementation issues in their technical/polytechnic institutions may modify and adapt the measures.

5.3 The study’s social implication

For the study’s social implication, the research offers the polytechnic management, polytechnic regulatory agencies, built environment researchers, construction experts, policymakers and students to appreciate the barriers facing BIM implementation via Rivet in the built environment programmes despite the benefits and its relevant to the medium workforce capacity building in the digitalisation era. Appreciating these issues may stir the regulatory agency (NBTE) in charge of Nigeria’s polytechnics to review most of the curriculum, not just the built environment programmes but all to align with the 21st century where operations are achieved via digitalisation (software and electronic tools). Also, it would stir policymakers and other relevant authorities (Rectors) to invest more in technical/polytechnic BIM technology and upgrade existing facilities to a global minimum standard. The social impact of implementing some of the findings and recommendations might benefit polytechnic management, policymakers, regulatory agencies, researchers, students and industry. From the international perspective, it would expand the built environment graduates’ employment opportunities because of the training and exposure to BIM applications regarding each discipline.