1. Introduction

Off-site construction is a modern method where construction elements are produced in a controlled factory, instead of at a construction site [1,2]. In the past 20 years, off-site construction has become more and more popular. According to a survey in 2017, 90% of interviewees from a wide range of backgrounds including construction contractors, designers, manufacturers, and academic researchers, believe that the number of off-site construction projects will increase in the future [3]. Its popularity has been widely reported in China, Hong Kong, Australia, Germany, and the Netherlands [4,5,6].

Off-site construction may also be named as prefabricated construction, precast construction, modular construction, etc. [7,8,9,10], with subtle differences in various contexts. Some scholars define modular construction as a well-developed off-site manufacturing approach, where prefabricated modules are 85–90% completed with finishes in a factory. Off-site manufacturing also refers to prefabricated, prefinished volumetric construction (PPVC) [11,12,13,14]. In this research, these various definitions are all included and are referred to as off-site construction (OSC).

Many studies have claimed that the major advantage of OSC is that it could save up to 30–50% construction time compared to conventional construction, since construction elements or modules could be manufactured in a factory before the onsite activity starts. Therefore, site preparation and the manufacturing of construction elements can happen at the same time [5,6,15,16,17]. However, in the current practice of OSC, the performance of this construction method still encounters many challenges and has not yet realized its full potential in time and cost saving, as well as labour productivity. Some research has reported that the total time from design to onsite assembly could actually be longer than conventional construction [18,19,20]. Human labour productivity is low due to the high skill level required for on-site assembly in OSC projects [21,22,23]. According to an investigation in the United States (US), in reality nearly half of the prefabrication projects see less than 5% in savings in total labour hours [24]. Other studies have reported that the cost of prefabricated buildings is actually estimated to be 26.3 to 72.1% higher than that of conventional buildings [25,26,27,28]. These facts indicate that many problems need to be solved to fully realize the potential benefits of OSC. Moreover, there are many surveys conducted in the OSC industry to measure performance from different perspectives, for example, energy and environment [29,30,31,32], labour productivity [29,33], and market and social factors [29,34]. These surveys demonstrate the industry’s desire to improve OSC in general.

Digital technology is regarded as the key to improve productivity in the construction industry [35,36]. According to a survey conducted in the Chinese off-site construction sub-sector, published in 2020, over 90% of respondents from construction enterprises consider the lack of advanced technology implementation as the major constraint for the development of OSC [37]. Moreover, according to a survey of contractors at a forum on OSC held in the US, 87% of 156 contractors responded that advanced technology is one of the key enablers for the use of OSC with greater accuracy and efficiency [24]. Technological advancement can provide solutions to address many current issues in construction and have come to play a significant role in construction [38]. Digital technologies have received increasing attention following the development of digitalization and automation concepts in Industry 4.0 [35,39,40,41]. They could be used for logistics management, near-real-time information flows, end-to-end supply chain transparency, and improvements in human interaction through the integration of digital technologies, especially labour-intensive activities [42]. Furthermore, the digital representation of design for manufacture and assembly (DFMA) practices and quality assurance can be achieved by the adoption of technologies in OSC with higher accuracy and efficiency [29]. The general adoption of digital technologies in the construction industry is slow compared to other industries, due to the lack of understanding in their identification, assessment, and selection [43,44,45]. This may slow down the adoption of Industry 4.0 technologies that may potentially improve current construction management issues. Successful technology adoption may facilitate the main requirement of a successful implementation of Industry 4.0. Industry 4.0 embraces the applications of the Internet of Things (IoT), robotics, 3D printing, off-site manufacturing, blockchain, cyber-physical systems, and other relevant technologies [41]. While the literature on off-site construction is growing, there is no systematic evaluation of how available digital technologies have been utilized in the construction sectors, and how these technologies can effectively enhance current OSC practices. Therefore, the aim of this study is to identify the most relevant papers on digital technology applications in the OSC context through a systematic review of the literature. Then, the identified papers are critically reviewed to analyze the limitations and the gap in the literature, which will help draft a road map for Industry 4.0 utilization. The objectives of this research are: (1) To provide a scientific mapping of the current status of digital technology utilization in OSC; (2) to identify the network links and relationships between different types of digital technologies; (3) to investigate the main research topics, current achievements, and limitations of these technologies when utilized in OSC; and (4) to point out the potential of each technology and provide guidance for its improvement and future adoption in OSC.

2. Materials and Methods 2.1. Research Process

A three-step approach is adopted to conduct a systematic literature review and analysis on how digital technologies can be utilized to overcome existing challenges in OSC. The first step is to identify specific digital technologies adopted in the construction industry from the literature searched in Scopus. Various digital technologies and relevant terminologies are identified and selected from the keywords’ analysis carried out by using VOSviewer. The second step is to use the selected digital technologies/terminologies as keywords to conduct a literature search in a publication database. The third step is to carry out an in-depth review and qualitative analysis based on the database search outcome. The process for this review is illustrated in Figure 1. In this research, Scopus is used as it is one of the largest research publication databases available. Compared with other databases, it has a wide range of coverage of quality publications in the domain of construction, as well as interdisciplinary research topics [46]. The process involved in identifying specific digital technologies and the details of searching relevant papers are explained in Section 2.2 and Section 2.3, respectively.

2.2. Preliminary Search to Identify Keywords of Technologies

This literature review focuses on the digital technologies used in OSC projects. Digital technology is a general term and it covers a wide range of specific techniques. To ensure the literature search covers all commonly-adopted digital technologies in the construction industry, a preliminary search was carried out to identify the specific technologies and the terminologies used in the literature. This paper reviews a variety of papers with different terminologies, and therefore, there is a need to preserve consistency throughout the current paper by defining the core technical concepts. BIM, as the core concept examined in this paper, is known as a debatable concept since it has been referred to as a solution, approach, methodology, and technology depending on the context of the investigation. Practitioners, particularly vendors, refer to it as a solution, while academics and some stakeholders refer to it as a methodology. In this research, it is found that BIM is closely linked to many technologies. Consequently, the technology aspect of BIM is the focus of this paper. Recently, Shirowzhan et al. [47] defined technology broadly to include artefact, its relevant knowledge, and processes to solve problems. They defined technology as tools, software, hardware, electronic boards, sensors, and machines or a combination of them or any modification of them to be considered in the construction context. The definition adopted in this paper embraces BIM as a technology, and it is important to understand that BIM also refers to a process of modelling, analyzing, simulating, integrating, and visualizing building and construction information by using different tools and software [48,49,50].

Step 1 is to identify all the digital technologies utilized in the construction industry most recently. A preliminary search was carried out in Scopus, and in order to identify the latest digital technologies reported in the literature, the published papers are confined to the last 10 years, from 2010–2020. The papers are limited to journals and conference proceedings in English. First, “digital technology” or ”digital technologies” were searched as keywords in Scopus, then the construction-related keywords were added as constraints within the results. The keyword search algorithm is:

(TITLE-ABS-KEY (digital AND technology OR digital AND technologies)) AND (construction AND industry OR construction AND project OR construction AND projects). The initial search resulted in identifying 3627 papers including journal articles and conference papers. This outcome is used for further analysis by utilizing VOSviewer, which enables the scientometric analysis including the frequency of occurrence of selected keywords. After merging abbreviations with the full terms or relevant meanings that they represent, the following technologies are identified: (1) “BIM” and “Building Information Modelling” and “Building Information Model”; (2) “IoT” and “Internet of Things”; (3) “virtual reality” and “VR”; (4) “augmented reality” and “AR”; (5) “3D printing” and “addictive manufacturing”; “3D concrete printing”; (6) “artificial intelligence” and “machine learning” and “deep learning”; (7) “laser scanning” and “3D scan”; “3D scanning”; “3D laser scanning”; “terrestrial laser scanning”; (8) “GIS” and “Geographic Information System”; (9) “GPS” and “Global Positioning System”; (10) “photogrammetry” and “video”; “drones”; and “UAV”. All the technologies that appeared in the keywords are selected and visualized in Figure 2.

The fifteen specific digital technologies and their co-occurrences in the literature are illustrated by VOSviewer in Figure 2.

In Figure 2, the size of the circles is in proportion with the total occurrence frequency of each technology in relation to the others, while the thickness of the lines represents the link strength between two technologies [9,51]. Obviously, BIM is the most widely reported digital technology in the construction industry and it is closely linked to many other technologies. The items with the same color represent a close relationship among them and are categorized in one cluster [9,51]. An example is that virtual reality is closely linked to BIM and augmented reality [52] and laser scanning is often discussed with photogrammetry and BIM [53]. GPS, GIS, and RFID are in the same cluster, and the remaining five technologies covering sensors, IoT, AI, big data, and blockchain are grouped together, and they are all closely linked to BIM. Note that BIM technologies have been developed over the last 20 years so the total number of occurrences in the systematic review is quite high, while big data, IoT, AI, VR, and photogrammetry have been developed more recently but are quickly catching up. These fifteen digital technologies, as shown in Figure 2, are adopted as the keywords for a more detailed literature search regarding their utilization in OSC. The application of each technology is reviewed in the following sections.

2.3. Database Search for Selecting Relevant Papers

Step 2 is to identify all relevant papers on digital technology utilization in OSC. The details of the procedures involved in the database search are given in Figure 3. First, all papers related to OSC are retrieved from the Scopus database. The keyword of “off-site construction” in Scopus returned 2532 papers. After limiting the publication period to 2010–2020, to the English language, and to conference and journal papers, 885 papers were retrieved related to OSC. The number of published papers appearing yearly on OSC is represented in yellow bars in Figure 4. The next step was to identify the papers related to digital technology utilization among the OSC papers. Fifteen digital technologies identified from Step 1 were applied as keywords to narrow down the search results. The literature search was conducted by inputting keywords into Scopus as follows:

TITLE-ABS-KEY (“precast construction” OR “off-site construction” OR “prefabricated construction” OR “Prefabricated prefinished volumetric construction” OR “on-site assembly” OR “modular building” OR “prefabricated building” OR “Offsite manufacturing” OR “Offsite manufacture” OR “Off-site manufacturing” OR “Off-site manufacture” OR “Off site manufacturing” OR “Off site manufacture”) AND TITLE-ABS-KEY (“BIM” OR “building information modelling” OR “IoT” OR “internet of thing” OR “Virtual reality” OR “Augmented reality” OR “AR” OR “VR” OR “Artificial intelligence” OR “deep learning” OR “machine learning” OR “photogrammetry” OR “photometric point cloud” OR “computer vision-based” OR “UAV” OR “photo” OR “image” OR “video” OR “camera” OR “laser scanning” OR “3D sensing” OR “laser scanner” OR “laser scans” OR “RFID” OR “sensor” OR “Global Position System” OR “GPS” OR “Big data” OR “3D printing” OR “addictive manufacturing” OR “3D printer” OR “blockchain” OR “block chain” OR “block-chain” OR “GIS” OR “Geographic Information System” OR “robotics” OR “robotic” OR “robot arm”).

Initially, 193 papers were returned in the database. After manual processing, 113 papers were selected as valid papers that are relevant to digital technology utilization in OSC. The annual distribution of the 113 papers is shown as blue bars in Figure 4, in comparison with the annual published papers on OSC. It can be seen that the total number of published papers on digital technology utilization in OSC, accounts for only 12.8% of total papers on OSC from 2010–2020. This suggests that the area is under-explored and the digital technology utilization level is low. In addition, published papers on digital technology utilization in OSC mainly start from 2016, although they are increasing steadily year by year to 2020.

3. Results of Scientometric Analysis

The scientometric analysis is conducted by VOSViewer, which can visualize the influence of key journals, publications, and countries, and analyze the co-occurrence of research keywords, which were commonly adopted key contents in the literature-review-based studies [9,51,54,55]. This section analyzes the co-occurrence of keywords, and the countries active in the targeted research. Moreover, it described a basic background of the targeted research domain and could facilitate further content analysis and qualitative discussions with the mapping results.

3.1. Co-Occurrence of Keywords

The mapping of co-occurrence of author keywords indicates the frequency of occurrence of study topics in one paper and the inter-relatedness among topics [9]. By visualizing the relationships, each keyword can be grouped in a defined category and several clusters that provide information about the main research topic of this literature review. Several main criteria guided the inclusion and exclusion of keywords: (1) The threshold value at a minimum of two co-occurrences; (2) the general keywords such as “construction”, “prefabrication”, “buildings”, “research review”, and “literature review” were removed; (3) keywords with the same meaning but using various abbreviations were combined, for example, “BIM”, “Building Information Model” and “Building Information Modelling”; and “IoT” and “Internet of Things”; and (4) country names such as “Hong Kong” and “Singapore” were removed as they were analyzed separately. Finally, a total of 26 main keywords were shortlisted and visualized in Figure 5.

As can be seen from Figure 5, BIM is the most frequently used technology in OSC. It is the second biggest circle and is in the center position along with OSC. The items with the same colour represent the same cluster. There are nine clusters reflecting the main research topics of the 113 papers, six of which are clear from the interrelationship analysis:

• Design for manufacturing and assembly (DfMA) is significant in prefabricated project design. Lean construction aims to improve construction processes by reducing constraints or waste and accelerating construction cycles in OSC. Lean construction is closely linked to DfMA and digital technologies, such as BIM and RFID [56,57,58,59], as seen in the light blue circles in Figure 6a;

• Information delivery and exchange, and the product architect model are to address OSC information sharing issues [52,60,61,62], as seen in the orange circles in Figure 6b;

• The estimation of carbon emissions, from additional production and transportation processes in the life-cycle assessment of OSC, is different from traditional construction [63,64,65]. This cluster is shown in the light purple circles in Figure 6c;

• Supply chain management is closely linked to the construction project management practice and the decision-making system [60,66,67], as seen in the dark purple circles in Figure 6d;

• Construction schedule risks are usually dealt with by using simulation and productivity improvement [68,69,70], as seen in the red circles in Figure 6e;

• Integration management combines different stages or processes together, such as contract management [46,71], as seen in the brown circles in Figure 6f.

The remaining three clusters are construction automation and robotics, logistics, and sustainable construction. Construction automation is closely related to robotic technology and virtual prototyping [72,73]. Logistics is grouped with BIM and energy efficiency in a dark blue colour [60,74], while sustainable construction is grouped with off-site construction, which indicates that OSC is generally taken as a sustainable approach to building [75,76,77,78]. Other keywords identified from this analysis indicate the benefit of OSC, e.g., productivity improvement and energy efficiency.

In summary, the scientometric analysis provided nine research topics from the 113 papers. How digital technologies are linked in these topics need further discussions. Therefore, a more in-depth content analysis is carried out in Section 4.

3.2. Analysis of Countries Involved in Research

This category provides a list of authors and their countries of origin. The minimum number of documents for a country is set to five, and from a total of 25 countries identified from all the literature sources, nine countries meet this requirement, as shown in Figure 7. Table 1 shows the number of citations of papers published by these countries and the link strength with other countries.

Mainland China is the most active country in carrying out research on adopting digital technology in OSC, and China is also actively working with other countries and has the highest link strength [27,79,80,81,82]. Hong Kong ranked 3rd in the total number of publications, one paper less than Canada, although the citation and link strength with other countries are much higher than Canada. This can be explained by Hong Kong’s close link to mainland China. Moreover, Hong Kong’s research attracts the highest number of citations in this area, which demonstrates its high quality and the high impact of research in technology applications in OSC.

As for Australia, the total number of published papers is ranked 4th, although the average citation number is 5.4, which is significantly lower than Mainland China, Hong Kong, and Singapore with 13.3, 28.6, and 12.6, respectively, showing its low impact in this field. Canada is in a similar situation with 18 documents ranking 2nd, while the average citation number is 5.2. The link strength between Australia and other countries is still strong with 1494 and ranking 3rd, however. The United States and United Kingdom have smaller total link strengths with 616 and 698, while the average citations are both slightly higher than Australia with 6.6 and 6. Combining the document number, citations, and link strength, it can be concluded that China, Hong Kong, Canada, Australia, the United States, the UK, and Singapore are the main countries carrying out research in adopting digital technologies in OSC. 4. Content Analysis The scientometric mapping provides nine research topics reflecting the identified literature. However, it cannot demonstrate how the fifteen digital technologies are utilized in each of these topic areas. Following the bibliometric analysis and scientometric mapping, a content analysis was conducted to summarize the current practice of digital technology utilization in OSC, to gain some insight on the purpose of utilizing technologies, the outcomes achieved, and issues of concern. 4.1. Overview and Relationship

As shown in Figure 5, BIM is the most widely analyzed digital technology and it is linked to many other technologies adopted in the OSC. Of the 113 papers, 88 are related to BIM, eight of them being literature review papers on BIM utilization, and the remaining 80 BIM-related papers discussing more specific issues in OSC. To examine how closely BIM is linked to other digital technology adoptions, a careful examination of the 80 non-review papers was carried out. The eight review papers are excluded as they may or may not mention other digital technologies, but as their nature is review, they do not represent new cases of using BIM with other digital technologies. Out of the 80 papers on BIM, 56 papers (70%) focus on BIM alone, meaning that BIM is a digital technology that can be used independently. The remaining 24 papers adopted BIM in conjunction with one or more other digital technologies. The overlap with each of the other technologies is given in Table 2. Note that in Table 2, the percentages do not add up to 100% as the other technologies also overlap with each other. How each digital technology is linked to other technologies is illustrated in Figure 8. Table 2 and Figure 8 show the current situation of how these digital technologies are linked to each other in OSC. The detailed technology adoption related to the nine topics will be presented in the following sections.

Figure 8 shows the dependent relationships between all fifteen technologies. The number in the circle is the total number of papers published on each technology. The number on the thickened bar between any two technologies is the number of the papers adopting both technologies, and the thickness of the bar is proportional to how much the two technologies overlap with each other. In particular, as the green bars indicate, all papers on IoT, GPS, laser scanning, big data, and blockchain, adopted BIM technology at the same time, indicating that they are heavily dependent on BIM. BIM acts as the central “intersection” linking to other technologies. Moreover, note that all 10 papers on IoT are linked to RFID and GPS technologies, as well as BIM. There are no studies on GIS utilization in OSC and 3D printing. Furthermore, robotics, big data, and blockchain are much less explored in OSC currently. In the following section, the use of each of these technologies in OSC is analyzed and discussed.

4.2. Building Information Modelling (BIM)

Eighty eight papers related to BIM adoption in OSC were retrieved from the database including eight review papers, and 80 non-review papers. The major findings of the eight review papers are listed in Table 3, and the major findings for the 80 non-review papers are summarized in Table 4.

The eight review papers summarize different aspects of BIM application in OSC. For example, the authors of [46] carried out a comprehensive review in identifying future directions and the authors of [83] conducted both qualitative and quantitative evaluation of the benefits of BIM for OSC. Three papers reviewed BIM applications in different phases of the project life-cycle [71,84,85]. The balance explored BIM utilization in OSC from structural engineering [86], end-of-life phase [55], and organizational management perspectives [87].

In addition, some of the review papers including [46,55,84,85] show the practical application and benefits of combining other technologies such as RFID with BIM. For example, Luo and Chen [84] showed a BIM-RFID method to store and visualize information. In a different practice, Senthilvel et al. [71] showed the utilization of VR with BIM for identifying construction sequence planning. Moreover, the literature shows that the utilization of laser scanning along with BIM is useful in site inspections for quality control purposes [46,71,86]. In recent practices, the application of AI for generative design along with BIM is discussed by [46], as well as IoT and photogrammetry [46]. The shift from desktop-based BIM to web-based BIM also provided more flexibility and opportunity for BIM usage in OSC supply chain management [88]. In summary, three research gaps can be summarized from these reviews:

• There is a lack of knowledge on how BIM could be used appropriately to fully achieve its benefit in OSC and a relevant assessment model for measuring those benefits is missing. For example, how BIM usage in conventional construction projects can benefit a specific area, such as cost estimating, has been discussed in the literature (e.g., [89]), but there has been no such evaluation for OSC;

• Current discussions on BIM application in OSC are for fragmented phases. How to integrate BIM throughout the OSC project life cycle needs further study;
• How BIM can be best utilised with other technologies in OSC and especially implemented in real construction practice, is still unclear.

The 80 non-review papers related to BIM discussed a wide range of issues in OSC and the research topics (as identified and categorized in Section 3.1) associated with them are summarized in Table 4.

Based on the identified issues, the future directions for BIM utilization in OSC are suggested as follows:

• BIM-based automated design and optimized planning to coordinate prefabricated elements rather than separate parts design. AI is a promising technology to support an automated assembly process;
• Developing BIM standards for data exchange and delivery among different stakeholders considering the characteristics of OSC projects, as well as BIM integration and communication with other technologies data, such as sensors, RFID, point cloud to reduce information loss, and improve data processing efficiency;
• More functions can be added in BIM to reflect actual practices of supply chain management and on-site management of OSC, such as procurement processes, safety management, quality management, and environment issues;
• AI could be integrated into BIM to facilitate complex data processing and decision-making in project schedule risk identification and logistics optimization;
• Recycling strategies for end-of-life prefabrication materials should be further developed for sustainable development;
• BIM utilization throughout the entire life cycle in OSC needs to be streamlined;
• More case studies need to be conducted to evaluate the actual improvement resulting from BIM implementation, and to help develop an assessment model for measuring the benefits of BIM utilization in OSC projects;
• The integration and arrangement of other technologies (e.g., RFID, sensors) with BIM in OSC need to be developed in a more scientific way to be aligned with OSC processes and leverage the benefit of each technology with less effort.

4.3. Radio Frequency Identification Devices (RFID)

There are two types of RFID systems. One is called a passive system without any power source and the other is called an active system with a battery in tag. Most papers on RFID in OSC discuss the passive RFID system [96,98,109]. A passive RFID system usually includes an antenna, RFID reader, and tag [77,89]. The tags are always attached to tools, machinery, and materials and then the status and numbers of targeted objects can be quickly detected and recorded near-real-time in digital data [81,89,90]. There are 20 RFID papers describing the application in OSC, and all 20 use BIM simultaneously. The main topics, the purpose of adopting RFID, and the outcomes achieved in these papers are listed in Table 5.

Based on the identified issues, the future directions for RFID utilization in OSC are suggested as follows:

• Better performing devices need to be adopted in OSC with better signal range and strength, reduction of damage, faster reaction speed, such as active RFID, and improved working capacity in the concrete environment of prefabricated components;
• The design of a RFID arrangement plan of tags number, installation position, RFID selection should be detailed and analyzed before implementation;
• The RFID data reliability needs to be further tested and enhanced for accuracy to meet industry requirements for OSC projects—for supply chain management, logistics, and schedule risks identification;
• A more efficient way should be developed to simplify data processing from raw RFID data and reach global standardization of RFID data representation;
• Data security issues need to be addressed in logistics planning and asset management.

4.4. Global Positioning System (GPS)

There are 14 papers describing the application of GPS in OSC, which suggest that OSC could be effectively improved by applying the system [49]. GPS is a digital technology that could provide location information in near-real-time and create smart construction objects, including components, materials, vehicles, and machinery [77]. The implementation of GPS technology is straight forward, since it can be integrated into a smart phone for the detection of components [78,85]. The main topics, purpose of adopting GPS, and outcomes achieved in these papers are listed in Table 6.

Based on the identified issues, the future research directions for GPS utilization in OSC are suggested as follows:

• GPS data accuracy, data storage capacity analysis, and near-real-time data reaction speed should be further validated in actual prefabricated local OSC projects;
• A more automated way of GPS data collection and a more intelligent way of data extraction should be designed in logistics and supply chain management taking into consideration the OSC features.

4.5. Internet of Thing (IoT)

IoT is a system with multiple technologies, which may include sensors, networks, the cloud, analytics, and user interfaces to transmit and record information among different processes and stakeholders in near-real-time [96,97,115]. There are 10 papers discussing IoT applications in OSC, all of them involving BIM as the central technology to analyze collected data with the designed model. These papers are listed in Table 7.

The IoT applications in construction have heavily relied on various integrated technologies such as RFID, sensors, and BIM. This part mainly concentrates on the framework design of IoT and the existing barriers to implementation. The future directions for IoT utilization in OSC are suggested as follows:

• Network signals need to be enhanced with higher stability for information exchange and delivery; data accuracy and delivery speed should be tested for actual OSC daily operation requirements;
• Security and privacy issues in project data exchange and storage for logistics management need to be addressed;
• The IoT system should be enhanced through a quality check of prefabricated components in manufacture, transportation and assembly processes, construction safety management, and environmental protection issues;
• Industrial standards, which are more applicable to OSC projects, should be developed among BIM, GPS, RFID, and other technologies;
• More practical tests need to be conducted for implementation in real-life, off-site projects rather than simulation by virtual models.

4.6. Sensors

Sensors are devices that can generate electronic signals from a physical condition and collect information such as temperature, pressure, location, and carbon emissions, as seen in Table 8.

Ten papers are identified in this study which are applied in OSC. The main topics, purpose of using sensors, and outcomes achieved in these papers are listed in Table 9.

Based on the identified issues, the future directions for sensor utilization in OSC are suggested as follows:

• The application of sensors needs to be extended to other types of projects such as precast concrete components, and more suitable sensors need to be tested for the effective detection of other types of damage that occurs in prefabricated components;
• More effective methods need to be developed to link the physical sensors with virtual sensors for efficient information delivery and exchange;
• Installation and maintenance of sensors in prefabricated concrete components and steel needs to be improved, and sensor layout plans need to be detailed and costed before implementation in real cases;
• To develop cost reduction strategies by identifying critical prefabricated components rather than installing sensors on all prefabricated components.

4.7. Augmented Reality (AR)

AR is a computer-based technology by which virtual data can be added to the user’s perception of the real world and provide a highly immersive experience to the user [118]. This technology can be used for inspection, tracking, and modification of on-site construction tasks [119]. Utilizing AR, the quality of tasks can rely less on workers’ experience and reduce on-site paper-based procedures. There are three papers related to AR technology applications in the OSC database. The main topics, outcomes achieved, and issues identified are given in Table 10.

Based on the identified issues, the future directions for AR utilization in OSC are suggested as follows:

• Integrating AI in AR algorithm development to encourage time and cost saving;
• Utilizing AR to improve efficiency and precision of the assembly process in OSC;
• Developing innovative methods which are less dependent on equipment and environmental conditions for OSC projects;
• Integrating laser scanning into AR for creating a near-real-time virtual environment for quality checking of OSC building components.

4.8. Virtual Reality (VR)

Compared with AR, VR technologies are mainly studied in lift planning in relation to off-site projects, as seen in Table 11. Moreover, VR can be integrated with AR as a mix reality (MR) [120]. The main limitation is that 3D objects in VR are identified as phantom models compared with the real-world counterparts, that is, an animation rather than real representation, therefore, critical information such as the level of quality achieved might be lost [72,120,121,122].

Based on the identified issues, possible future directions for AR utilization in OSC are suggested as follows:

• Validate VR utilization in a real OSC environment for monitoring lift activities and near-real-time progress rather than relying on simulations;
• To enhance the fidelity of the VR environment and make the operators feel more immersed in linking VR with the real construction environment;
• Developing assessment models of VR performance to measure efficiency improvement and reduce errors.

4.9. Photogrammetry

There are five papers related to photogrammetry technology and its application in OSC. The two main topics and research outcomes are seen in Table 12. This technology is mainly used to achieve on-site quality control, since it can capture near-real-time image data from the construction site [123]. For example, the information about texture, size, configuration, location, arrangement of the components, and even workers’ facial expression of fatigue, for example, could be captured by images or videos and then visualized in a point cloud processing platform [112,123,124]. The collected data are mainly used to compare with BIM models or VR/AR technologies [112].

Based on the identified issues, possible future directions for photogrammetry utilization in OSC are suggested as follows:

• Extending photogrammetry usage in quality detection to precast concrete projects rather than only steel or wood projects, and recognition of the irregularly shaped precast components;
• Optimization of photogrammetric devices to improve image quality for higher accuracy and reduce the complexity of data processing based on the real OSC environment;
• Developing methods for automated data alignment and data exchange with BIM models to facilitate near-real-time lifting task optimization and construction progress monitoring;
• Further testing and enhancement of image data reliability for improving accuracy and processing speed to meet industry requirements for OSC projects;
• Improving the accuracy of on-site workers’ operations (e.g., for crane operators) and their status for safety purposes.

4.10. Laser Scanning

There are five papers related to laser scanning technology’s application in OSC. The main topic and outcomes are listed in Table 13. Laser scanning could capture point cloud data with geometric, colour, and coordinate information for both objects and the environment generally [125,126]. There are different types of mobile and terrestrial scanners with different levels of accuracy and quality [126], and the literature discusses a wide range of practices of using point cloud data in information systems or models in the construction field [127].

The laser scanning technology is widely discussed in the traditional construction area connected with progress control [130,131], object recognition [132], change detection [133], and creating part-built [126] and as-built models [134,135]. However, the application to OSC is limited. Based on the identified issues, the future directions for laser scanning utilization in OSC are suggested as follows:

• Processing capability improvement to enhance data accuracy and efficiency for quality detection of both regular and irregular precast components;
• Utilizing AI technology to increase the level of automation to reduce dependency on manual intervention in data creation and data processing;
• Developing methods for more accurate data collection using laser scanning and data noise reduction;
• Increasing the adoption of laser scanning technology in the OSC practice in a wider range of construction quality control, progress monitoring, and safety management.

4.11. Artificial Intelligence (AI)

As mentioned previously with many other digital technologies, AI can be used to improve the efficiency and accuracy of other technologies. There are 11 papers related to AI technology application in OSC. The research topics, outcomes achieved, and issues identified are presented in Table 14.

Based on the identified issues, the future directions for AI utilization in OSC are suggested as follows:

• AI-based design for topology analysis of prefabricated elements—configuration, segmentation, and optimization;
• Complex data analysis in logistics data processing;
• Distance determination of factory location and construction site before OSC and optimization of supply chain management to reduce costs;
• Prediction of various potential project risks based on historical and real-time data.

4.12. 3D Printing

There are two papers related to the 3D printing technology and its application in OSC. The research topics, outcomes, and issues identified are presented in Table 15.

Based on the identified issues, possible future directions for 3D printing utilization in OSC are suggested as follows:

• Enhance 3D printing to be able to handle complex and irregular prefabricated components effectively;
• Improve cost, accuracy, and mechanical performance of 3D printing for precast components;
• Implement 3D printing to real case OSC projects to validate the approach and demonstrate its efficiency.

4.13. Robotics

There are three papers related to robotic technology application in OSC. The research topics, outcomes, and issues identified are presented in Table 16.

Based on the identified issues, the future directions for robotic utilization in OSC are suggested as follows:

• Conducting cost analysis studies for robotic utilization in the manufacturing process;
• Testing the onsite assembly process of robotic utilization using physical prototypes before implementation to provide adequate information and evidence for decision making.

4.14. Big Data

There is only one paper related to big data technology application in OSC. The research topics, outcomes, and issues identified are presented in Table 17.

Based on the identified issues, the future direction for big data utilization in OSC is that more empirical validation and case studies can be conducted. Big data has great potential to be utilized in supply chain management to improve its efficiency, but can also be expanded to other areas of OSC such as component design analysis, construction cost, and time analysis. 4.15. Blockchain

There is only one paper related to blockchain technology and its application in OSC. The research topics, outcomes, and issues identified are shown in Table 18.

Based on the identified issues, the immediate future directions for blockchain utilization in OSC are smart contract management, addressing the security issues, and achieving a faster approval process. 5. Conclusions

This research was inspired by the recent Industry 4.0 phenomena, which is fueled by technology advancement and innovations for improving efficiency and productivity in all fields. As pointed out by the authors of [146], the growth of the construction industry is a subset of the universal set of gross domestic product value, and OSC is an important area to be developed to drive the revolution in the construction industry. Due to the nature of OSC, the successful implementation of OSC heavily relies on technology utilization. Many scholars have utilized a variety of digital technologies to improve the productivity of OSC, although no research has been found to systematically summarize the current practice of technology adoption in OSC and provide directions for future study. This paper fills the gap and the major contributions are summarized below:

This review identified the 15 most commonly used digital technologies in the construction industry based on publications in the Scopus database during the period from 2010–2020 and then, adopted them as keywords to carry out a detailed literature search for their utilization in OSC during the same period. It was found that China, Hong Kong, Canada, Australia, the United States, the UK, and Singapore are the main countries carrying out research on adopting digital technologies to improve OSC processes. However, overall, only a small portion (12.8%) of the research publications related to OSC utilizes digital technologies, which indicates that there is still great potential to implement digital technologies to improve the OSC processes. Based on the VOSviewer visualization of keywords, the research papers related to technology utilization in OSC are grouped under nine research topics. These nine research topics in OSC are used to guide and classify the content analysis of each digital technology’s utilization in OSC. Three research topic areas of OSC including schedule risks, information delivery and exchange, and DfMA have received the most attention by scholars in utilizing digital technologies in OSC. In the content analysis of the retrieved papers, each technology is individually analyzed, and the details about the purpose of utilizing each technology, the outcomes achieved, and issues with each technology are presented in tables for easy reference. Based on the identified issues, the potential future research direction of each technology is discussed. In summary, among the identified technologies, BIM, IoT, RFID, and VR/AR are the most frequently mentioned among all the reviewed papers. BIM, as a concept, a methodology, or a technology has been applied in the construction industry for decades and is in the center to link other newer technologies emerging in the Industry 4.0 revolution. It remains in its important position to facilitate the implementation of other technologies in the construction industry. BIM, RFID, and GPS have been developed for relatively longer in the industry, and are technologically mature, and in a state of “ready to use” for OSC projects. The main issue with these technologies are the need for relevant and applicable industry standards in consideration of OSC characteristics to facilitate a more efficient adoption. VR/AR, photogrammetry, laser scanning, and AI are relatively less explored in OSC, but they could be very effective in improving OSC performance and have great potential to be further developed. The application of all the reviewed digital technologies may contribute to further productivity and efficiency improvement for OSC. However, to effectively utilize these technologies, research and development in some specific areas is still needed and this paper has provided a clear direction. OSC, once it realizes its full potential, will reshape the future construction industry and bring us into a construction 4.0 era.

1 Total link strength means the interrelationship between the given document and other documents.

Author Contributions

Conceptualization, M.W. and C.C.W.; Methodology, M.W. and C.C.W.; Software, M.W.; Validation, C.C.W., S.S. and S.Z.; Formal analysis, M.W. and C.C.W.; Investigation, M.W.; Writing-original draft preparation, M.W.; Writing-review and editing, C.C.W., S.S. and S.Z.; supervision, C.C.W., S.S. and S.Z.; Project administration, C.C.W. All authors have read and agreed to the published version of the manuscript.

Funding

This research was funded by the University of New South Wales (UNSW) Scientia PhD Scholarship Scheme.

Conflicts of Interest

The authors declare no conflict of interest.