Next Article in Journal
An Evolving Landscape of the Psychology of Judgment and Decision-Making: A Bibliometric Analysis
Previous Article in Journal
Lack of Risk Management at Insolvency Consulting Companies: An Empirical Study in Germany 2024
 
 
Search for Articles:
Title / Keyword
Author / Affiliation / Email
Journal
Article Type
 
 
Advanced Search
 
Section
Special Issue
Volume
Issue
Number
Page
 
Journals
Administrative Sciences
Volume 14
Issue 8
10.3390/admsci14080161
admsci-logo
Submit to this Journal Review for this Journal Propose a Special Issue
Article Menu

Article Menu

share Share announcement Help format_quote Cite thumb_up
...
Endorse textsms
...
Comment
first_page
settings
Order Article Reprints
Font Type:
Arial Georgia Verdana
Font Size:
Aa Aa Aa
Line Spacing:
Column Width:
Background:
Article

The Impact of Knowledge Management and Organizational Learning Promotion in Small and Medium Enterprises on the Implementation of Industry 4.0 and Competitiveness

by
Chun-Hung Cheng
1,*,
Meng-Hua Li
2,
Bau-Jen Tang
2 and
Yea-Rong Cheng
3
1
Program in Electro-Optical and Materials Science, Department of Electro-Optical Engineering, National Formosa University, Huwei 632, Taiwan
2
Department of Industrial Management, National Formosa University, Huwei 632, Taiwan
3
Department of Special Education, National University of Tainan, Tainan 700, Taiwan
*
Author to whom correspondence should be addressed.
Adm. Sci. 2024, 14(8), 161; https://doi.org/10.3390/admsci14080161 (registering DOI)
Submission received: 3 June 2024 / Revised: 9 July 2024 / Accepted: 19 July 2024 / Published: 26 July 2024
(This article belongs to the Topic Sustainability Efforts and Importance of Change Management)
Browse Figure
Versions Notes

Abstract

:
The transformation and upgrading of small- and medium-sized enterprises (SMEs) need to align with global industrial development trends and can further assist SMEs in sustainable operation. In recent years, major industrial countries, such as Germany, China, and the United States, have promoted policies like Industry 4.0 or advanced manufacturing as part of their national manufacturing transformation strategies. In contrast, how SMEs follow these global industrial development trends and effectively apply new technologies hinges on internal knowledge management and organizational learning. To achieve the benefits of new technology implementation, enterprises must establish an effective knowledge management and organizational learning mechanism and promotion practices. The Taiwanese government has also adopted Industry 4.0 as an essential tool for assisting the transformation and upgrading of SMEs. Therefore, this study surveyed 129 SMEs in the Taiwanese metal industry, using a one-way ANOVA, Pearson correlation analysis, and simple regression analysis to explore the impact of the internal promotion of knowledge management and organizational learning on the introduction of Industry 4.0 and the enhancement in competitiveness. The results of this study indicate that the promotion of knowledge management and organizational learning contributes to the effective adoption of Industry 4.0 and the enhancement in competitiveness, showing significant correlations between these factors. Thus, the findings can serve as a reference for other partner countries.

1. Research Background

1.1. Research Motivation

In today’s fiercely competitive market, how small- and medium-sized enterprises (SMEs) can enhance their competitiveness to achieve sustainable development has become a primary task for government units worldwide in promoting industrial transformation and upgrading. Under the trend of global market supply chain reorganization and the development of Industry 4.0, organizational learning capabilities can significantly enhance the impact of Industry 4.0 on enterprise operational performance. Through systematically promoting learning and knowledge sharing, enterprises can achieve greater benefits in the implementation of Industry 4.0 technologies. Moreover, knowledge sharing is crucial for maintaining a long-term competitive advantage (Tortorella et al. 2020; Manesh et al. 2021). Additionally, (Li et al. 2019) pointed out that, under the context of Industry 4.0, the manufacturing industry faces increasingly complex challenges, and enterprises need to emphasize knowledge sharing and organizational learning to cope with growing market demands and competitive pressures. For SMEs, knowledge is one of the most valuable resources; through knowledge sharing, enterprises can effectively transmit internal expertise and technical skills to all employees. This not only enhances individual employee capabilities but also fosters overall innovation within the enterprise. When every employee quickly grasps new technologies and knowledge, the enterprise is more likely to adapt to market changes and anticipate new challenges (Hussein et al. 2016). Furthermore, organizational learning plays a crucial role in SMEs; organizational learning is not merely the sum of individual learning by employees but also a manifestation of collective wisdom. Through organizational learning, enterprises can effectively integrate and exchange the wisdom and experiences of various departments and teams, thereby better responding to market changes and challenges. When a good learning mechanism and culture are established within the organization, the enterprise is more likely to gain a competitive advantage (Tu and Wu 2021). Thus, the introduction of Industry 4.0 technologies has a profound impact on the collaborative culture and knowledge-sharing mechanisms of enterprises, highlighting the importance of organizational learning and knowledge management in the era of Industry 4.0 (Lepore et al. 2021). Knowledge sharing and organizational learning are crucial pathways for SMEs to enhance their competitiveness. Through the effective application of these two elements, enterprises can better cope with market changes and improve their competitiveness.

1.2. Research Design

This study intends to collect knowledge management, organizational learning, Industry 4.0, and competitiveness through a literature review. The collected literature will serve as the foundation for this research, further exploring the impact of knowledge management and organizational learning on Industry 4.0 and competitiveness. The study will focus on the following research questions:
Investigate the impact of promoting knowledge management and organizational learning on Industry 4.0 in SMEs.
Explore the impact of promoting knowledge management and organizational learning on the competitiveness of SMEs.
Examine the impact of promoting Industry 4.0 on the competitiveness of SMEs.

2. Literature Review

2.1. Knowledge Management

In the digital era, knowledge sharing is regarded as a key factor in promoting innovation and enhancing the performance of R&D teams. Xiao et al. (2021) proposed an evolutionary game model for knowledge sharing in R&D teams based on evolutionary game theory, exploring the evolutionary path, stable strategies, and influencing mechanisms of knowledge sharing systems. The study pointed out that the cognitive abilities of members, knowledge absorption capacity, knowledge transformation ability, knowledge innovation ability, and the complementarity of knowledge within the team promote the effectiveness of knowledge sharing in R&D teams. On the other hand, in the era of digital transformation, knowledge management is crucial for handling a large amount of available information and must lead in the generation, sharing, use, and management of relevant knowledge and information. However, existing knowledge management measures may be insufficient to promote knowledge sharing among partners, focusing too much on unidirectional knowledge flow. Therefore, digital collaboration platforms enhance the potential for bidirectional knowledge sharing (Brouwers et al. 2022). Mihardjo et al. (2019) proposed an important viewpoint that knowledge sharing and transformational leadership styles can improve team performance. Additionally, the process of creativity often begins with knowledge sharing among team members, especially in the context of sharing tacit knowledge within a specific field. Through this knowledge sharing, teams can generate numerous novel ideas, driving successful outcomes such as new products, processes, and patents. Mayastinasari and Suseno (2023) further explored the impact of transformational leadership on innovative work behavior in the digital era and the effects of transformational leadership on knowledge sharing and its influence on innovative work behavior in public organizations. Transformational leadership has a significant positive impact on innovative behavior and knowledge sharing. Knowledge sharing is crucial to an organization’s success, impacting creativity, learning, and performance. Additionally, it emphasizes the influence of knowledge sharing on team atmosphere and employee life satisfaction, beyond the work itself (Ahmad and Karim 2019). García-Pérez et al. (2018) highlighted the criticality of knowledge sharing in organizational competitiveness. Their research focused on knowledge sharing within and between organizations, demonstrating through two case studies the importance of knowledge sharing for business development. Regardless of the nature of the business, individuals, groups, and decision-makers within the organization need to share critical knowledge to drive business development. These case studies emphasize the value of collaborative and human-centered knowledge sharing. Fauziyah and Rahayunus (2021) focused on the relationship between individual innovation capability and knowledge sharing, highlighting the importance of knowledge sharing in creating competitive advantages, especially supported by individual innovation capabilities. They found that individual innovation capability has a positive and significant impact on knowledge sharing and employee performance, further proving the key role of individual innovation capability in the relationship between knowledge sharing and employee performance. Nashir and Pratminingsih (2023) found that absorptive capacity positively affects knowledge sharing and job performance, with knowledge sharing acting as a mediator between absorptive capacity and job performance. Key factors for the successful promotion of knowledge management include strategy, culture, information technology, personnel, and organizational structure (Babu 2012). Information technology, knowledge management leadership, knowledge management culture, and knowledge management measurement are also important factors (Wong 2005). Additionally, organizational strategy definition, performance measurement standards, senior management involvement, and organizational culture significantly impact the successful implementation of knowledge management (Onofre and Teixeira 2022). These studies indicate that the successful implementation of knowledge management involves multiple factors, including strategy, culture, technology, personnel, and organizational structure, which collectively contribute to providing a competitive advantage for organizations.

2.2. Organizational Learning

Watad (2018) emphasized that, in IT-driven organizational changes, there is often a neglect of knowledge management and learning. They pointed out that organizations, when restructuring processes and improving productivity, tend to focus on immediate benefits while overlooking long-term knowledge management and learning strategies. This indicates that the managers’ attention is usually limited and may not be able to handle both aspects simultaneously. This viewpoint reminds managers to pay more attention to the importance of knowledge management and learning in organizational change to ensure long-term development. Chuah and Law (2019) theoretically overviewed various concepts of organizational learning, describing it as the process of developing, retaining, and transferring knowledge within an organization. Although there is no unified definition of organizational learning, it is influential across many disciplines and closely related to knowledge management. Antunes and Pinheiro (2020) focused on knowledge management and learning in human resource management, emphasizing that an organization’s knowledge management capabilities largely depend on its human resources, as they are the main force in creating, sharing, and applying knowledge. This underscores the importance of valuing knowledge management and learning in human resource management and viewing it as a key factor in organizational development. Hafner (2016) pointed out that the ability to effectively change and use knowledge is crucial for modern organizations. In today’s era of knowledge explosion, organizations need to constantly adapt to changes and utilize knowledge to maintain competitive advantages. He emphasized the importance of incorporating organizational learning strategies into organizational development to ensure that organizations can timely absorb new knowledge and apply it in practice.
Chou and Ramser (2019) proposed a multi-level theoretical model, emphasizing that organizational learning is influenced by multiple levels and sources. They suggested that employees’ spontaneous behaviors (such as upward help and voice) affect organizational learning and that developing leadership capital can promote organizational learning, offering strategies to encourage employee engagement in learning behaviors. Kim and Lu (2019) discussed the literature on learning organizations and organizational performance, highlighting the importance of learning organizations in improving organizational performance. They stated that the ability of learning organizations to connect with the external environment and the presence of leadership that supports learning enable these organizations to better cope with changes and challenges, maintaining a leading position in competitive environments.
Seman and Mohamad (2019) emphasized the role of organizational learning in promoting corporate innovation. Organizational learning helps organizations to continuously develop new ideas and solutions, thereby enhancing innovation capabilities. The study further pointed out that introducing transformational leadership styles helps to motivate employees to actively participate in the learning process, thereby driving innovation. Argote et al. (2020) divided organizational learning into four processes: searching, knowledge creation, knowledge retention, and knowledge transfer. This perspective provided a more detailed exploration of the processes and influencing factors of organizational learning. Through these four processes, organizations can continuously acquire new knowledge, create value, retain important information, and share knowledge within the organization. Olejarski et al. (2019) explored the importance of organizational learning from the perspective of public sector organizations, highlighting that organizational learning requires public institutions to change their norms and policies to better meet the changing demands and challenges. You et al. (2021) proposed organizational learning as a strategic approach to organizational change, emphasizing the importance of learning organizations in coping with change challenges and achieving organizational goals.
Namada (2018) regarded organizational learning as a key source of competitive advantage for contemporary business organizations, exploring different elements of organizational learning, including knowledge acquisition, knowledge distribution, information interpretation, and organizational memory, and how these elements influence organizational competitive advantage. Pham and Hoang (2019) confirmed the positive impact of organizational learning capabilities on business performance. They particularly found a positive correlation between management’s commitment to learning, knowledge transfer, and business performance, encouraging companies to enhance business performance by strengthening organizational learning capabilities.
Elkjaer (2021) explored the theoretical construction of organizational learning, discussing the debates on the responsibility of organizational learning between practitioners and researchers, and suggested adopting a pragmatic learning theory to resolve these disputes. This study provided valuable insights into the future development of the field of organizational learning. Key success factors for organizational learning include strategy, culture, and technological factors (Mas-Machuca and Martínez Costa 2012). Organizational-level strategies and policies, IT readiness, performance and impact evaluation, personnel skills and expertise, and data quality are also critical to success (Clark et al. 2020). Moreover, organizational learning, as a strategic tool, not only enhances employees’ knowledge and skills but also promotes organizational development and growth, creating a dynamic learning organization that plays an important role in achieving knowledge management and organizational goals (Saadat and Saadat 2016). Support from senior executives is equally crucial, as their participation and commitment can ensure the smooth progress and successful implementation of organizational learning and knowledge management programs (Onofre and Teixeira 2022).

2.3. Industry 4.0

2.3.1. Operational Management

Majstorovic et al. (2020) believe that Industry 4.0 is a new model of technological system automation, based on the technological integration of the smart manufacturing concept, including the application of information and communication technologies such as cloud computing, big data analytics, artificial intelligence, and distributed control. They point out that ERP systems are evolving and can connect to IoT, big data analytics, AI, and cloud computing. Polívka and Dvořáková (2021) emphasize the significant impact of Industry 4.0 on the IT environment of organizations, especially ERP systems. Rathnayake et al. (2022) stress that Industry 4.0 technologies will increasingly rely on the application of ERP systems. Integrating Industry 4.0 technologies, such as IoT and RFID, into ERP systems can enhance ERP capabilities, providing more accurate analysis and forecasting. Skrzeszewska and Patalas-Maliszewska (2019) mention that Manufacturing Execution Systems (MES) are tools for executing internal business processes, particularly notable in the automotive manufacturing industry. Based on examples from two automotive manufacturing companies, they analyze the effectiveness of MES usage by maintenance department employees across business, tactical, and strategic management levels. Govender et al. (2019) explore the integration challenges between ERP and MES systems in the steel industry, which needs to integrate manufacturing and business systems for real-time decision-making and increased visibility of production processes. Additionally, the combination of MES and PLM systems can accelerate the promotion of Industry 4.0 (D’Antonio et al. 2017). Popescu and Scarlat (2022) discuss the need to integrate new paradigms of industrial automation and control systems in Industry 4.0 management. They examine the synergy of two concepts: cyber-physical SCADA systems and human-centric production, emphasizing their complementarity. This study highlights the role of SCADA systems in Industry 4.0 transformation. Malik et al. (2021) mention the construction modules of Industry 4.0, including cyber–physical systems, AI, robotics, cloud computing, and IoT, noting that SCADA systems play a key role in Industry 4.0 by monitoring, collecting, and processing real-time data to control industrial manufacturing processes. Chang et al. (2021) emphasize the importance of the SCADA architecture for achieving smart interconnected manufacturing factories, proposing a cloud-based analytics module for predictive maintenance (PDM) in Industry 4.0, using machine learning algorithms to analyze preprocessed data and provide predictive recommendations for production quality management. Saxby et al. (2020) point out how lean management methods support continuous improvement in the field of Industry 4.0. Lean management supports factors in Industry 4.0, including continuous improvement, supply chain involvement, pull systems, and customer-centric approaches. This study identifies that lean management can be supported by Industry 4.0 technologies. Abdulnour et al. (2022) introduce the digital transformation process of SMEs in the context of personalized mass production, emphasizing the importance of Industry 4.0 for the sustainable development of manufacturing enterprises and proposing the concept of Lean 4.0 to better adapt SMEs to personalized mass production environments. Bordeleau et al. (2018) mention that traditional business intelligence (BI) must adapt to the large volume of data from Industry 4.0 technologies and use this data for decision-making, thus creating value for companies. They point out that, by analyzing data and integrating it into strategic and operational activities, Industry 4.0 value is created. Choi et al. (2022) emphasize the impact of rapid business process changes in the era of Industry 4.0 on enterprise participants. They suggest promoting Industry 4.0 within organizations and review the positive impact of BI on decision-making within organizations. Arana-Landín et al. (2023) analyze the impact of Industry 4.0 technologies on energy efficiency, stating that the application of multiple Industry 4.0 technologies can significantly enhance decision-making capabilities for achieving higher energy efficiency. On the other hand, Medojević et al. (2019) focus on the impact of the Industry 4.0 concept on manufacturing energy and environmental management systems and overall manufacturing energy efficiency. Their research shows a significant correlation between the Industry 4.0 concept and manufacturing energy and environmental management systems. Additionally, SCM can enhance the capability of supply chain management through the connection and use of Industry 4.0-related technologies, improving production efficiency and management capabilities (Garay-Rondero 2019; Han et al. 2021).

2.3.2. Smart Production Applications

Lee et al. (2015) emphasized that the deployment of CPS systems is crucial for the infrastructure of Industry 4.0, highlighting that CPS systems enable information flow between physical factories and cyberspace. (Berger et al. 2016) pointed out that the introduction of CPS in Industry 4.0 has a significant impact on production scheduling and economic benefits. Through advanced information analysis, connected machines can operate more efficiently and flexibly, particularly in monitoring and controlling physical infrastructure (Pérez et al. 2016). Buhl et al. (2019) discussed the benefits of integrating dual-arm collaborative robot systems in smart factories and Industry 4.0 environments, especially for complex industrial assembly tasks. They highlighted the flexibility and synchronized movement capabilities of collaborative robot systems and their role in enhancing human work efficiency. Bragança et al. (2019) briefly outlined how collaborative robots support human resource needs in Industry 4.0 manufacturing environments. Gallala et al. (2022) noted the rapid increase in collaborative robots in manufacturing under the backdrop of Industry 4.0 and smart factories. Gualtieri et al. (2020) emphasized industrial collaborative robots as one of the main enabling technologies of Industry 4.0. (Berlak et al. 2021) found that the use of construction robots increased productivity by 75.6–91.3%. Jagatheesaperumal et al. (2022) reviewed the integration of artificial intelligence and big data in Industry 4.0, discussing their impact on manufacturing, with a particular focus on smart factory applications and the deployment of AI and big data in modern industries, highlighting advantages such as improved production efficiency and quality, and the challenges faced. Bécue et al. (2021) explored the application of artificial intelligence in manufacturing, particularly its role within the Industry 4.0 framework, emphasizing how AI technologies can enhance production efficiency and product quality, while also addressing related security issues, including data privacy and protection. Banitaan et al. (2023) underscored the critical role of artificial intelligence in Industry 4.0, viewing AI as a key technology for enhancing enterprise competitiveness, and mentioned its applications in production monitoring, optimization, and control. Çınar et al. (2020) discussed the widespread application of intelligent systems and AI in Industry 4.0, particularly machine learning and predictive maintenance methods. Due to digital transformation, many industrial devices generate vast amounts of operational and process condition data, which are used for automated fault detection and diagnosis, improving equipment utilization and extending its lifespan. Zonta et al. (2020) viewed machine maintenance in Industry 4.0 from another perspective, stating that the ability to predict future asset maintenance needs is crucial for improving production efficiency and quality. Arora (2023) proposed an automated defect diagnosis method using advanced image processing technology to improve quality control in Industry 4.0, highlighting that traditional manual inspection methods are time-consuming, arbitrary, and prone to errors, thus proposing this groundbreaking automated solution. Penumuru et al. (2019) introduced a general approach for automatic material identification using machine vision and machine learning technologies to enhance the cognitive capabilities of machines in the Industry 4.0 era. They used various classification algorithms to prepare and process material surface datasets and tested their robustness under different conditions. The results showed that the proposed method can effectively identify different material groups and be implemented in existing manufacturing settings without significant modifications, improving product quality. Ottogalli et al. (2019) proposed a framework using VR and AR technologies to simulate industrial processes, emphasizing the importance of such simulations for testing and studying new processes before deployment, introducing new features such as interaction between human workers and automated systems and flexible modeling for various domains and purposes. Bhattacharya (2022) discussed the use cases and prospects of AR and VR technologies in industrial production processes, emphasizing their role in improving work efficiency and accuracy. Ulmer et al. (2019) highlighted the important role of AR and VR in virtual prototyping, manufacturing, and maintenance in Industry 4.0, noting that fully integrating these technologies into existing process structures is crucial for ensuring future competitiveness. Li et al. (2015) emphasized the importance of wireless networks in the Industry 4.0 framework, especially in smart factories and smart manufacturing systems. They introduced the concept of industrial wireless networks, discussed their characteristics, relevant technologies, and new architectures based on quality of service and data quality, while also highlighting design challenges and unresolved issues. Alrashidi et al. (2020) proposed an advanced clustering method to overcome challenges in monitoring and control applications, emphasizing the importance of extending the lifespan and minimizing power consumption, and proposed some optimization methods for the efficient operation of wireless sensor networks. Alabi (2017) pointed out the popularity and widespread application of 3D-printing technology globally, particularly in healthcare, automotive, aerospace, and manufacturing fields. They mentioned that big data and 3D-printing technologies are identified as key technologies driving Industry 4.0 and fostering innovation across various industries. Chen and Lin (2017) discussed the technical and managerial challenges faced by 3D printing, including time-consuming object design, material type limitations, accuracy, and productivity issues. Malik et al. (2022) explored the sustainability of 3D-printing technology within the Industry 4.0 framework, highlighting its advantages in weight reduction, waste reduction, and energy savings. They emphasized the importance of 3D printing as part of the Industry 4.0 technological revolution in achieving smart manufacturing across various industries. (Berlak et al. 2021) calculated that the introduction of 3D printing in the construction industry resulted in a productivity increase of 5.3–41.4%. Elbasani et al. (2020) reviewed and elaborated on the core technologies of Industry 4.0 from the perspective of RFID technology, highlighting its role in IoT, big data, and other fields, and delved into its potential in Industry 4.0. Gładysz et al. (2023) emphasized the importance of RFID in Industry 4.0, exploring how the Industry 4.0 concept influences the adoption of RFID technology. Hakeem et al. (2020) focused on the application of RFID technology for material handling functions in Industry 4.0, stating that, with the advent of Industry 4.0, RFID technology is crucial for improving and effectively executing these functions. Zeba and Čičak (2020) discussed the importance of RFID technology in Industry 4.0, especially in resource planning, and highlighted RFID as a key technology supporting IoT, essential for achieving smart factories and efficient resource management. Long et al. (2018) emphasized the opportunities provided by Industry 4.0 for achieving flexible and efficient production. Zant et al. (2021) proposed a new approach to improving manufacturing operation flexibility, transforming rigid production systems into agile ones. They tested this approach on an Industry 4.0 platform, demonstrating its effectiveness, especially in quickly adapting to demand. Gania et al. (2017) discussed flexible manufacturing systems and the development of solutions based on flexibility concepts within Industry 4.0.

2.3.3. Information and Data Applications

Alcaraz et al. (2020) indicated that Industry 4.0 combines information technology (IT) and operational technology (OT), creating new opportunities to improve and optimize operational processes, products, and services. This combination creates a new industrial ecosystem but also leads to challenges in information security, as more connection points can lead to security vulnerabilities. Cheng and Zhang (2020) analyzed information security in the implementation of Industry 4.0 strategies, proposing a series of specific measures, from industrial control system security to encryption technologies, aimed at ensuring information security in Industry 4.0. Pereira et al. (2017) noted that Industry 4.0 leads to new technological trends, such as IoT and big data, while highlighting potential security vulnerabilities in these new technological solutions. They emphasized the security challenges for Industry 4.0 and called for increased awareness of security practices. Khan and Javaid (2021) recognized IoT as a crucial component of Industry 4.0, with widespread applications in monitoring production systems in manufacturing and services. IoT promotes higher performance in Industry 4.0 and opens up new possibilities for manufacturing innovation and renewal. The primary function of IoT is to collect and share information through connected devices and machines, aiding in the creation of smart factories and providing better solutions, making IoT a key driver of Industry 4.0. Bisio et al. (2018) viewed IoT as one of the key technologies in Industry 4.0, utilizing smart, ubiquitous connected devices to achieve faster and more efficient production and management processes. Subramanian et al. (2021) emphasized the importance of cloud technology for the continuous advancement of Industry 4.0, particularly for the adoption by micro-, small, and medium enterprises (MSMEs). Cloud technology helps to centralize business information and provides a collaborative platform. Velásquez et al. (2018) noted that Industry 4.0 promotes the use of information and communication technology (ICT) in manufacturing processes to meet the demanding needs of new consumers. They highlighted cloud computing and big data as key technologies that support interconnected service networks and provide more flexible production processes. Atobishi et al. (2018) discussed the application of cloud computing and big data in Industry 4.0, which can accelerate the efficiency of enterprise production processes. Pisching et al. (2015) described the concept and characteristics of cloud-based manufacturing services in Industry 4.0, proposing the integration of cloud computing and IoT into the Internet of Services. Santos et al. (2017) discussed the role of big data in Industry 4.0, particularly in collecting, integrating, storing, processing, and analyzing data, enhancing production and data application capabilities, and making it more suitable for use in multinational enterprises.

2.4. Competitiveness

Corporate competitiveness indicators include various aspects. Calış Duman and Akdemir (2021) mentioned profitability, revenue, and market share, stating that companies related to Industry 4.0 can improve their performance through changes in technological production models and the introduction of applications. However, while providing business performance, the production performance related to product quality, production efficiency, and cost reduction is closely linked to business performance (Amoako-Gyampah and Acquaah 2008). Additionally, Yu et al. (2016) also pointed out that related cost and quality improvements can further enhance a company’s profitability and revenue growth.

3. Research Design

3.1. Research Framework

This study focuses on the Taiwanese metal industry to investigate the impact of promoting knowledge management and organizational learning on Industry 4.0 and competitiveness. The conceptual framework of this study is shown in Figure 1.

3.2. Research Subjects

This study targeted the Taiwanese metal industry SMEs as the research population. According to the Ministry of Economic Affairs of Taiwan, the upper limit for the number of employees in SMEs is 200. According to the statistics from the Department of Statistics, Ministry of Economic Affairs, Taiwan, there are 23,000 registered metal industry companies in Taiwan, of which 95% are SMEs.

3.3. Data Collection

The survey period for this study was from March 2024 to April 2024. To ensure that the respondents were representative and indicative of the industry, the survey questionnaires were distributed to members of relevant associations in the Taiwanese metal industry. For a comprehensive and reliable survey, the survey was sent via email to senior executives (managers of the management department, HR department, manufacturing department, or R&D department). Responses were collected through an online Google form, yielding a total of 129 valid samples with a response rate of 24%.

3.4. Survey Design

Based on the collected literature, indicators were designed to explore knowledge management, organizational learning promotion, Industry 4.0, and competitiveness. Three experts from relevant fields were invited to provide expert opinions, which helped to establish a valid questionnaire for this study. The questionnaire covers the company background as defined in Table 1.
The survey items for this study included promoting knowledge management and organizational learning, with Industry 4.0 divided into operational management, smart production applications, and information and data applications. Competitiveness was divided into “business performance and production performance.” A Likert five-point scale was used, with responses ranging from “strongly agree” (5), “agree” (4), “neutral” (3), “disagree” (2), to “strongly disagree” (1). Higher scores indicate a higher degree of actual conformity to the situation. A pilot survey was conducted, yielding 14 responses, and a Pearson correlation analysis was performed. The results show significant correlations between promoting knowledge management, organizational learning, Industry 4.0, and competitiveness, forming the basis for the full survey.

3.5. Data Processing and Statistical Methods

After collecting the survey data, all valid responses were coded and entered into a computer database. For statistical analysis, SPSS for Windows version 27 was used. The following statistical analyses were conducted:

3.5.1. Dimensional ANOVA Analysis

Business operations were used as the independent variables, divided into employee numbers, company revenue, and export. Knowledge management, organizational learning promotion, Industry 4.0, and competitiveness were used as the dependent variables. A one-way ANOVA was conducted. If significant differences were found, Scheffé’s post hoc comparisons were performed to understand the differences.

3.5.2. Pearson Correlation Analysis

We used a correlation analysis on each dimension of knowledge management, organizational learning promotion, Industry 4.0, and competitiveness to understand the relationships between the variables.

3.5.3. Dimensional Simple Regression Analysis

We used simple regression models to examine the relationships between promoting knowledge management, Industry 4.0 (operational management, smart production applications, and information and data applications), and competitiveness (business performance and production performance).
We used simple regression models to examine the relationships between promoting organizational learning, Industry 4.0 (operational management, smart production applications, and information and data applications), and competitiveness (business performance and production performance).
We used simple regression models to examine the relationship between Industry 4.0 and competitiveness.

4. Method Analysis

4.1. ANOVA Method Analysis

In the ANOVA analysis of the employee numbers on the four variables (Table 2), the results show significant impacts on knowledge management promotion, organizational learning promotion, and Industry 4.0, but no significant impact on competitiveness. Knowledge management promotion has a significant impact (p < 0.01**), with the post hoc comparison results indicating that the third group scored higher than the first and fourth groups. Organizational learning promotion has a significant impact (p < 0.05*), with the post hoc comparison results showing that the third group scored higher than the second, fourth, and first groups. The introduction of Industry 4.0 has a significant impact (p < 0.01**), with the post hoc comparison results indicating that the third group scored higher than the fourth, second, and first groups. In terms of competitiveness, there is no significant impact (p = 0.284); this can be explained by the fact that competitiveness is a part of overall corporate performance indicators, and it is unlikely to show significant differences solely based on the number of employees.
The ANOVA analysis of company revenue on the four variables (Table 3) shows that there are highly significant impacts on knowledge management, organizational learning promotion, and Industry 4.0, while the impact on competitiveness is relatively lower but still significant. Specifically, knowledge management promotion has a significant impact (p < 0.01). The post hoc comparison results indicate that the third group scored higher than the fourth, first, and second groups. Organizational learning promotion has a very significant impact (p < 0.001). The post hoc comparison results show that the third group scored higher than the fourth and first groups. The introduction of Industry 4.0 has a highly significant impact (p < 0.001). The post hoc comparison results indicate that the fourth group scored higher than the third, first, and second groups. In terms of competitiveness, there is a significant impact (p < 0.05). The post hoc comparison results show that the fourth group scored significantly higher than the third, second, and first groups.
In the ANOVA analysis of the export ratio on the four variables (Table 4), the results show no significant impact on knowledge management promotion, organizational learning promotion, and Industry 4.0. Specifically, the p-value for knowledge management promotion is 0.496, for organizational learning promotion is 0.154, and for the introduction of Industry 4.0 is 0.120, indicating that the export ratio does not have a significant impact on these three variables. However, for competitiveness, the p-value is 0.004, indicating a significant impact. The post hoc comparison results show that the fourth group scored significantly higher than the third, second, and first groups; this can be explained by the fact that companies with higher export levels generally have higher-value products, which in turn can enhance their competitive advantage.

4.2. Pearson Correlation Analysis

The results of the product-moment correlation analysis between knowledge management promotion, organizational learning promotion, operational management, smart production applications, information and data applications, business performance, and production performance are shown in Table 5. The following is a brief description of the correlations between variables and their significance levels:
Knowledge management and organizational learning show a strong positive correlation (r = 0.562, p < 0.001).Knowledge management has significant correlations with operational management (r = 0.430, p < 0.001), smart production applications (r = 0.207, p < 0.05), business performance (r = 0.346, p < 0.001), and production performance (r = 0.211, p < 0.05). There is no significant correlation with information and data applications (r = 0.168).
Organizational learning has highly significant correlations with operational management (r = 0.631, p < 0.001), smart production applications (r = 0.512, p < 0.001), information technology (r = 0.389, p < 0.001), business performance (r = 0.518, p < 0.001), and production performance (r = 0.437, p < 0.001).
Operational management and smart production applications show a strong positive correlation (r = 0.684, p < 0.001). There are significant correlations with information and data applications (r = 0.476, p < 0.001), business performance (r = 0.480, p < 0.001), and production performance (r = 0.390, p < 0.001).
Smart production applications and information and data applications show a strong positive correlation (r = 0.687, p < 0.001). There are significant correlations with business performance (r = 0.491, p < 0.001) and production performance (r = 0.449, p < 0.001).
Information and data applications and business performance show a strong positive correlation (r = 0.526, p < 0.001), and a significant correlation with production performance (r = 0.456, p < 0.001).
The correlation between business performance and production performance is strong and positive (r = 0.684, p < 0.001).

4.3. Simple Regression Analysis Method

Examining the impact of knowledge management on operational management in Table 6, the results show that the unstandardized coefficient (B) of knowledge management is 0.433, the standardized coefficient (β) is 0.430, the t-value is 5.373, and the p-value is lower than 0.001, indicating statistical significance. The related coefficient ΔR2 is 0.185, indicating that knowledge management has a moderate positive impact on operational management, explaining 18.5% of the variance.
Examining the impact of knowledge management on smart manufacturing applications in Table 7, the results show that the unstandardized coefficient (B) of knowledge management is 0.187, the standardized coefficient (β) is 0.207, the t-value is 2.380, and the p-value is 0.019, indicating statistical significance. The related coefficient ΔR2 is 0.043, indicating that knowledge management has a significant but relatively low positive impact on smart manufacturing applications, explaining 4.3% of the variance.
Examining the impact of knowledge management on information and data application in Table 8, the results show that the unstandardized coefficient (B) of knowledge management is 0.195, the standardized coefficient (β) is 0.168, the t-value is 1.923, and the p-value is 0.057. The results are close to but do not reach the level of statistical significance. The related coefficient ΔR2 is 0.028, indicating that knowledge management has a slight positive impact on information and data application, explaining 2.8% of the variance.
Examining the impact of knowledge management on business performance in Table 9, the results show that the unstandardized coefficient (B) of knowledge management is 0.378, the standardized coefficient (β) is 0.346, the t-value is 4.154, and the p-value is lowr than 0.001, indicating a high level of statistical significance. The related coefficient ΔR2 is 0.120, indicating that knowledge management has a significant positive impact on business performance, explaining 12% of the variance.
Examining the impact of knowledge management on production performance in Table 10, the results show that the unstandardized coefficient (B) of knowledge management is 0.258, the standardized coefficient (β) is 0.211, the t-value is 2.433, and the p-value is 0.016, indicating statistical significance. The related coefficient ΔR2 is 0.045, indicating that knowledge management has a significant positive impact on production performance, explaining 4.5% of the variance.
Examining the impact of organizational learning on operational management in Table 11, the results show that the unstandardized coefficient (B) of organizational learning is 0.750, the standardized coefficient (β) is 0.631, the t-value is 9.165, and the p-value is lower than 0.001, indicating a high level of statistical significance. The related coefficient ΔR2 is 0.398, indicating that organizational learning has a significant positive impact on operational management, explaining 39.8% of the variance.
Examining the impact of organizational learning on smart manufacturing in Table 12, the results show that the unstandardized coefficient (B) of organizational learning is 0.547, the standardized coefficient (β) is 0.512, the t-value is 6.721, and the p-value is lower than 0.001, indicating a high level of statistical significance. The related coefficient ΔR2 is 0.262, indicating that organizational learning has a significant positive impact on smart manufacturing, explaining 26.2% of the variance.
Examining the impact of organizational learning on information and data applications in Table 13, the results show that the unstandardized coefficient (B) of organizational learning is 0.533, the standardized coefficient (β) is 0.389, the t-value is 4.762, and the p-value is lower than 0.001, indicating a high level of statistical significance. The related coefficient ΔR2 is 0.152, indicating that organizational learning has a significant positive impact on information and data applications, explaining 15.2% of the variance.
Examining the impact of organizational learning on business performance in Table 14, the results show that the unstandardized coefficient (B) of organizational learning is 0.669, the standardized coefficient (β) is 0.518, the t-value is 6.831, and the p-value is lower than 0.001, indicating a high level of statistical significance. The related coefficient ΔR2 is 0.269, indicating that organizational learning has a significant positive impact on business performance, explaining 26.9% of the variance.
Examining the impact of organizational learning on production performance in Table 15, the results show that the unstandardized coefficient (B) of organizational learning is 0.629, the standardized coefficient (β) is 0.437, the t-value is 5.471, and the p-value is lower than 0.001, indicating a high level of statistical significance. The related coefficient (R) is 0.437, and ΔR2 is 0.191, indicating that organizational learning has a significant positive impact on production performance, explaining 19.1% of the variance.
Examining the impact of Industry 4.0 on competitiveness in Table 16, the results show that the unstandardized coefficient (B) of Industry 4.0 is 1.203, the standardized coefficient (β) is 0.534, the t-value is 7.113, and the p-value is lower than 0.001, indicating a high level of statistical significance. The related coefficient ΔR2 is 0.285, indicating that Industry 4.0 has a significant positive impact on competitiveness, explaining 28.5% of the variance.

5. Research Conclusions

5.1. Conclusions

The metal industry in Taiwan is composed of 95% small- and medium-sized enterprises (SMEs). The metal industry chain is extensive, covering upstream, midstream, and downstream sectors, including steel, hand tools, casting, fasteners, plumbing hardware, surface treatment, and heat treatment. These enterprises are generally small in scale and operate with a specialized division of labor. Therefore, for enterprises to promote transformation, upgrade, and enhance competitiveness through the introduction of new technologies, it is necessary to simultaneously promote knowledge management and organizational learning. The findings of this study can be summarized as follows:
  • Through this study, it was observed that companies with relatively high organizational learning promotion and Industry 4.0 significance tend to have higher revenues. This can be explained by the fact that a higher degree of organizational learning promotion helps companies to apply more new technologies or enhance R&D capabilities, thus driving revenue growth. Similarly, companies with a higher degree of Industry 4.0 adoption can leverage production technology advantages to increase revenues. This result aligns with global government policies and resources supporting enterprises in adopting Industry 4.0 technologies to aid in transformation and sustainable operations. Furthermore, it was observed that knowledge management promotion, organizational learning promotion, and Industry 4.0 adoption do not significantly impact export proportions, except for competitiveness. Companies with higher export proportions tend to have market advantages in their products, thereby enhancing business performance and production efficiency. Regarding the number of employees, significant impacts were found on knowledge management promotion, organizational learning promotion, and Industry 4.0 adoption, especially in groups with 51–75 employees. This suggests that reaching a certain scale in the number of employees can facilitate the establishment of knowledge management and organizational learning mechanisms. For Industry 4.0 adoption, companies with 51–75 and over 76 employees have higher adoption levels, indicating that the scale of the workforce affects the extent of Industry 4.0 adoption.
  • The transformation and upgrading of SMEs can enhance competitiveness, with Industry 4.0 adoption being a global industrial development trend. Regarding the correlation between knowledge management and the three aspects of Industry 4.0, operational management had the highest correlation, followed by intelligent production applications, while information and data applications showed no significant correlation. This study’s findings are consistent with those of Bettiol et al. (2022), showing that knowledge management can influence operational management and intelligent production applications. However, unlike their findings, this study did not find a significant impact on information and data applications, possibly because this study focused on SMEs that have already adopted operational management and intelligent production technologies, leading to more knowledge sharing and exchange within the organization.
  • Promoting organizational learning can enhance the technological capabilities and competitiveness of SMEs. This study observed that organizational learning can facilitate the adoption of relevant technologies in the three aspects of Industry 4.0: operational management, intelligent production applications, and information and data applications. The findings are consistent with those of Srivastava et al. (2022) and Prashar et al. (2024), indicating that a comprehensive learning mechanism within the organization, supported by senior management, is crucial for transformation and upgrading. Organizational learning can serve as a key strategy for promoting enterprise transformation and accelerating the upgrading process.
  • The adoption of Industry 4.0 technologies is an optimal tool for SME transformation, enhancing business performance and production efficiency. The findings of this study are consistent with those of Lavinsaa et al. (2020), Calış Duman and Akdemir (2021), and Chauhan et al. (2021), which show that promoting Industry 4.0 can enhance competitiveness. Competitiveness is key to the sustainable operation of enterprises, leading governments to invest resources in supporting SMEs to adopt Industry 4.0, thereby driving sustainable national industrial development.
In summary, knowledge management and organizational learning can drive enterprises to adopt Industry 4.0. This study finds that SMEs need to establish a short-, medium-, and long-term transformation roadmap with set goals and benefits for each stage to verify if the transformation meets the expected goals. For SMEs to adopt new technologies such as Industry 4.0, they need to fully utilize these technologies as a strategy to enhance competitiveness. Promoting knowledge management is crucial, as the dissemination and application of new knowledge within the organization is key to SME transformation. Internalizing new knowledge among employees facilitates the expected benefits of new technology adoption. Promoting organizational learning is also critical for new technology adoption within the organization, thereby enhancing competitiveness. Hence, promoting knowledge management and organizational learning effectively drives Industry 4.0 adoption, enhancing competitiveness, aligning with the research objectives, and serving as a strategy for future technology adoption to ensure successful transformation and sustainable operation.

5.2. Research Limitations

The limitations of this study include the fact that Industry 4.0 has become a global industrial development trend, yet this study is limited to a single country, Taiwan, and a single industry. The Taiwanese government prioritizes Industry 4.0 as a key policy for industrial transformation, providing enterprises with substantial resources and reducing obstacles to Industry 4.0 adoption.

5.3. Future Research Recommendations

As Industry 4.0 has become an industrial development trend, future research and surveys should expand the industry scope and conduct comparative analyses across different industries. Further investigation is needed to explore whether the transformation promotion results differ across industries and countries with varying background factors.
Additionally, knowledge management, organizational learning, and Industry 4.0 involve changes in business strategies and technology applications. Future research should explore the key success factors and obstacles in promoting these three aspects simultaneously.

Author Contributions

Conceptualization, C.-H.C. and B.-J.T.; methodology, C.-H.C. and M.-H.L.; formal analysis, C.-H.C. and B.-J.T.; investigation, B.-J.T. and Y.-R.C.; data curation, Y.-R.C.; writing—review and editing, C.-H.C. and M.-H.L.; visualization, Y.-R.C.; project administration C.-H.C. and M.-H.L. All authors have read and agreed to the published version of the manuscript.

Funding

This research received no external funding.

Institutional Review Board Statement

Not applicable.

Informed Consent Statement

Not applicable.

Data Availability Statement

The data presented in this study are available on request from the corresponding author.

Conflicts of Interest

The authors declare no conflict of interest.

References

  1. Abdulnour, Samir, Chantal Baril, Georges Abdulnour, and Sébastien Gamache. 2022. Implementation of Industry 4.0 Principles and Tools: Simulation and Case Study in a Manufacturing SME. Sustainability 14: 6336. [Google Scholar] [CrossRef]
  2. Ahmad, Farhan, and Muhaimin Karim. 2019. Impacts of Knowledge Sharing: A Review and Directions for Future Research. Organizations & Markets: Policies & Processes eJournal 31: 207–30. [Google Scholar]
  3. Alabi, Micheal Omotayo. 2017. Big Data, 3D Printing Technology, and Industry of the Future. In Additive Manufacturing: Breakthroughs in Research and Practice. Hershey: IGI Global. [Google Scholar]
  4. Alcaraz, Cristina, Yan Zhang, Alvaro Cardenas, and Liehuang Zhu. 2020. Guest Editorial: Special Section on Security and Privacy in Industry 4.0. IEEE Transactions on Industrial Informatics 16: 6530–31. [Google Scholar] [CrossRef]
  5. Alrashidi, Malek, Nejah Nasri, Salim Khediri, and Abdennaceur Kachouri. 2020. Energy-Efficiency Clustering and Data Collection for Wireless Sensor Networks in Industry 4.0. Journal of Ambient Intelligence and Humanized Computing. [Google Scholar] [CrossRef]
  6. Amoako-Gyampah, Kwasi, and Moses Acquaah. 2008. Manufacturing strategy, competitive strategy and firm performance: An empirical study in a developing economy environment. International Journal of Production Economics 111: 575–92. [Google Scholar] [CrossRef]
  7. Antunes, Helder de Jesus Ginja, and Paulo Goncalves Pinheiro. 2020. Linking knowledge management, organizational learning and memory. Journal of Innovation & Knowledge 5: 140–49. [Google Scholar]
  8. Arana-Landín, Germán, Naiara Uriarte-Gallastegi, Beñat Landeta-Manzano, and Iker Laskurain-Iturbe. 2023. The Contribution of Lean Management—Industry 4.0 Technologies to Improving Energy Efficiency. Energies 16: 2124. [Google Scholar] [CrossRef]
  9. Argote, Linda, Sunkee Lee, and Jisoo Park. 2020. Organizational Learning Processes and Outcomes: Major Findings and Future Research Directions. Management Science 67: 5399–429. [Google Scholar] [CrossRef]
  10. Arora, Makund. 2023. AI-Driven Industry 4.0: Advancing Quality Control through Cutting-Edge Image Processing for Automated Defect Detection. International Journal of Computer Science and Mobile Computing 12: 16–32. [Google Scholar] [CrossRef]
  11. Atobishi, Thabit, Szalay Zsigmond Gábor, and Szilard Podruzsik. 2018. Cloud computing and big data in the context of industry 4.0: Opportunities and challenges. Paper presented at the IISES Annual Conference, Sevilla, Spain, April 1–2. [Google Scholar]
  12. Babu, K. V. S. N. Jawahar. 2012. Key Factors in Knowledge Management. Available online: https://www.researchgate.net/publication/251341440_Key_Factors_in_Knowledge_Management (accessed on 18 July 2024).
  13. Banitaan, Shadi, Ghaith Al-refai, Sattam Almatarneh, and Hebah Alquran. 2023. A Review on Artificial Intelligence in the Context of Industry 4.0. International Journal of Advanced Computer Science and Applications 14. [Google Scholar] [CrossRef]
  14. Berger, Christoph, Joachim Berlak, and Gunther Reinhart. 2016. Service-based Production Planning and Control of Cyber-Physical Production Systems. Paper presented at 29th Bled eConference, Digital Economy, Bled, Slovenia, June 19–22; pp. 491–502. [Google Scholar]
  15. Berlak, Joachim, Stefan Hafner, and Volker G. Kuppelwieser. 2021. Digitalization’s impacts on productivity: A model-based approach and evaluation in Germany’s building construction industry. Production Planning & Control 32: 335–45. [Google Scholar]
  16. Bettiol, Marco, Mauro Capestro, Eleonora Di Maria, and Stefano Micelli. 2022. Disentangling the link between ICT and Industry 4.0: Impacts on knowledge-related performance. International Journal of Productivity and Performance Management 71: 1076–98. [Google Scholar] [CrossRef]
  17. Bécue, Adrien, Isabel Praça, and João Gama. 2021. Artificial intelligence, cyber-threats and Industry 4.0: Challenges and opportunities. Artificial Intelligence Review 54: 3849–86. [Google Scholar] [CrossRef]
  18. Bhattacharya, Biswajit. 2022. Impact of AR and VR in Industrial Revolution. International Journal for Research in Applied Science and Engineering Technology 10. [Google Scholar] [CrossRef]
  19. Bisio, Igor, Chiara Garibotto, Aldo Grattarola, Fabio Lavagetto, and Andrea Sciarrone. 2018. Exploiting Context-Aware Capabilities over the Internet of Things for Industry 4.0 Applications. IEEE Network 32: 101–7. [Google Scholar] [CrossRef]
  20. Bordeleau, Fanny-Eve, Elaine Mosconi, and Luis Antonio Santa-Eulalia. 2018. Business Intelligence in Industry 4.0: State of the art and research opportunities. Paper presented at the Hawaii International Conference on System Sciences, Village, HI, USA, January 3–6. [Google Scholar]
  21. Bragança, Sara, Eric Costa, Ignacio Castellucci, and Pedro M. Arezes. 2019. A Brief Overview of the Use of Collaborative Robots in Industry 4.0: Human Role and Safety. In Studies in Systems, Decision and Control. Berlin: Springer. [Google Scholar]
  22. Brouwers, Kay, Wouter van Lelyveld, Emoke Takacs, and Toon Abcouwer. 2022. Lifelong Learning Through Knowledge-sharing and Digital Collaboration. In European Conference on Knowledge Management. Reading: Academic Conferences and Publishing Limited. [Google Scholar]
  23. Buhl, Jens F., Rune Grønhøj, Jan K. Jørgensen, Guilherme Mateus, Daniela Pinto, Jacob K. Sørensen, Simon Bøgh, and Dimitrios Chrysostomou. 2019. A Dual-Arm Collaborative Robot System for the Smart Factories of the Future. Limerick: Procedia Manufacturing. [Google Scholar]
  24. Calış Duman, Meral, and Bunyamin Akdemir. 2021. A study to determine the effects of industry 4.0 technology components on organizational performance. Technological Forecasting and Social Change 167: 120615. [Google Scholar] [CrossRef]
  25. Chang, Ray-I., Chia-Yun Lee, and Yu-Hsin Hung. 2021. Cloud-Based Analytics Module for Predictive Maintenance of the Textile Manufacturing Process. Applied Sciences 11: 9945. [Google Scholar] [CrossRef]
  26. Chauhan, Chetna, Amol Singh, and Sunil Luthra. 2021. Barriers to industry 4.0 adoption and its performance implications: An empirical investigation of emerging economy. Journal of Cleaner Production 285: 124809. [Google Scholar] [CrossRef]
  27. Chen, Toly, and Yu-Cheng Lin. 2017. Feasibility Evaluation and Optimization of a Smart Manufacturing System Based on 3D Printing: A Review. International Journal of Intelligent Systems 32: 394–413. [Google Scholar] [CrossRef]
  28. Cheng, Xiaolei, and Pinghua Zhang. 2020. Information Security and Adoptable Solutions in the Implementation of Industry 4.0 Strategy for the Fourth-generation Industrial Revolution. Journal of Physics: Conference Series 1682: 012087. [Google Scholar] [CrossRef]
  29. Choi, Lee Kyung, Aropria Saulina Panjaitan, and Dwi Apriliasari. 2022. The Effectiveness of Business Intelligence Management Implementation in Industry 4.0. Startupreneur Business Digital (SABDA Journal) 1: 115–25. [Google Scholar] [CrossRef]
  30. Chou, Shih Yung, and Charles Ramser. 2019. A multilevel model of organizational learning. The Learning Organization 26: 132–45. [Google Scholar] [CrossRef]
  31. Chuah, Kong Bieng, and Kris My Law. 2019. “What Is Organizational Learning?”. In Project Action Learning (PAL) Guidebook: Practical Learning in Organizations. Cham: Springer. [Google Scholar]
  32. Clark, Jo-Anne, Yulin Liu, and Pedro Isaias. 2020. Critical success factors for implementing learning analytics in higher education: A mixed-method inquiry. Australasian Journal of Educational Technology 36: 89–106. [Google Scholar] [CrossRef]
  33. Çınar, Zeki Murat, Abubakar Abdussalam Nuhu, Qasim Zeeshan, Orhan Korhan, Mohammed Asmael, and Babak Safaei. 2020. Machine Learning in Predictive Maintenance towards Sustainable Smart Manufacturing in Industry 4.0. Sustainability 12: 8211. [Google Scholar] [CrossRef]
  34. D’Antonio, Gianluca, Lisa Macheda, Joel Sauza Bedolla, and Paolo Chiabert. 2017. PLM-MES Integration to Support Industry 4.0. In Product Lifecycle Management. Cham: Springer International Publishing. [Google Scholar]
  35. Elbasani, Ermal, Siriporn Pattamaset, and Jae Sung Choi. 2020. A Survey on RFID in Industry 4.0, Internet of Things for Industry 4.0: Design, Challenges and Solutions. In Internet of Things for Industry 4.0. Cham: Springer, pp. 1–16. [Google Scholar]
  36. Elkjaer, Bente. 2021. Taking stock of “Organizational Learning”: Looking back and moving forward. Management Learning 53: 582–604. [Google Scholar] [CrossRef]
  37. Fauziyah, and Zenida Wella Rahayunus. 2021. The Role of Knowledge Sharing and Innovation on Employee Performance. In 4th International Conference on Sustainable Innovation 2020-Accounting and Management (ICoSIAMS 2020). Amsterdam: Atlantis Press. [Google Scholar]
  38. Gallala, Abir, Atal Anil Kumar, Bassem Hichri, and Bassem Hichri. 2022. Digital Twin for Human–Robot Interactions by Means of Industry 4.0 Enabling Technologies. Sensors 22: 4950. [Google Scholar] [CrossRef] [PubMed]
  39. Gania, Ireneusz, Agnieszka Stachowiak, and Joanna Oleskow-Szlapka. 2017. Flexible manufacturing systems: Industry 4.0 solution. Paper presented at the 24th International Conference on Production Research (ICPR 2017), Poznań, Poland, July 30–August 3. [Google Scholar]
  40. Garay-Rondero, Claudia Lizette. 2019. Digital supply chain model in Industry 4.0. Journal of Manufacturing Technology Management 31: 887–933. [Google Scholar]
  41. García-Pérez, Alexeis, Juan Gabriel Cegarra-Navarro, and Mahsa M. Jahantab. 2018. Knowledge Sharing as a Driver of Competitive Advantage: Two Cases from the Field. In Knowledge Management in the Sharing Economy: Cross-Sectoral Insights into the Future of Competitive Advantage. Berlin: Springer. [Google Scholar]
  42. Gładysz, Bartłomiej, Donatella Corti, and Elias Montini. 2023. Forecasting the Development of RFID Technology. Management and Production Engineering Review 12: 38–47. [Google Scholar] [CrossRef]
  43. Govender, Esenthren, Arnesh Telukdarie, and Michael N. Sishi. 2019. Approach for Implementing Industry 4.0 Framework in the Steel Industry. Paper presented at the 2019 IEEE International Conference on Industrial Engineering and Engineering Management (IEEM), Macao, China, December 15–18; pp. 1314–18. [Google Scholar]
  44. Gualtieri, Luca, Ilaria Palomba, Fabio Antonio Merati, Erwin Rauch, and Renato Vidoni. 2020. Design of Human-Centered Collaborative Assembly Workstations for the Improvement of Operators’ Physical Ergonomics and Production Efficiency: A Case Study. Sustainability 12: 3606. [Google Scholar] [CrossRef]
  45. Hafner, Julee H. 2016. Introduction to the Organizational Learning Minitrack. Paper presented at the 2016 49th Hawaii International Conference on System Sciences (HICSS), Koloa, HI, USA, January 5–8; p. 4302. [Google Scholar]
  46. Hakeem, Akinlabi A. A., Davut Solyali, Mohammed Asmael, and Qasim Zeeshan. 2020. Smart Manufacturing for Industry 4.0 using Radio Frequency Identification (RFID) Technology. Jurnal Kejuruteraan 32: 31–38. [Google Scholar] [CrossRef]
  47. Han, Lu, Hanping Hou, Z. M. Bi, Jianliang Yang, and Xiaoxiao Zheng. 2021. Functional Requirements and Supply Chain Digitalization in Industry 4.0. Information Systems Frontiers, 1–3. [Google Scholar] [CrossRef]
  48. Hussein, AlShaima Taleb Taleb, Sanjay Kumar Singh, Sherine Farouk, and Amrik S. Sohal. 2016. Knowledge sharing enablers, processes and firm innovation capability. Journal of Workplace Learning 28: 484–95. [Google Scholar] [CrossRef]
  49. Jagatheesaperumal, Senthil Kumar, Mohamed Rahouti, Kashif Ahmad, Ala Al-Fuqaha, and Mohsen Guizani. 2022. The Duo of Artificial Intelligence and Big Data for Industry 4.0: Applications, Techniques, Challenges, and Future Research Directions. IEEE Internet of Things Journal 9: 12861–85. [Google Scholar] [CrossRef]
  50. Khan, Ibrahim Haleem, and Mohd Javaid. 2021. Role of Internet of Things (IoT) in Adoption of Industry 4.0. Journal of Industrial Integration and Management 7: 515–33. [Google Scholar] [CrossRef]
  51. Kim, Kyoungshin, and Zhenqiu Lu. 2019. Learning Organization and Organizational Performance. In The Oxford Handbook of the Learning Organization. Edited by Anders Ragnar Örtenblad. Oxford: Oxford University Press, pp. 333–46. [Google Scholar] [CrossRef]
  52. Lavinsaa, Paramasivan, Hemalatha Somu, Noor Hazlina Ahmad, Jignyasu Prafulla Joshi, and Nabsiah Abdul Wahid. 2020. Industry 4.0 Technology Re-Engineering Impacts on Strategy Agility and SME Competitiveness in Malaysia. Amsterdam: Atlantis Press. [Google Scholar]
  53. Lee, Jay, Behrad Bagheri, and Hung-An Kao. 2015. A Cyber-Physical Systems architecture for Industry 4.0-based manufacturing systems. Manufacturing Letters 3: 18–23. [Google Scholar] [CrossRef]
  54. Lepore, Dominique, Sabrina Dubbini, Alessandra Micozzi, and Francesca Spigarelli. 2021. Knowledge Sharing Opportunities for Industry 4.0 Firms. Journal of the Knowledge Economy 13: 501–20. [Google Scholar] [CrossRef]
  55. Li, Dan, Åsa Fast-Berglund, and Dan Paulin. 2019. Current and future Industry 4.0 capabilities for information and knowledge sharing. The International Journal of Advanced Manufacturing Technology 105: 3951–63. [Google Scholar] [CrossRef]
  56. Li, Xiaomin, Di Li, Jiafu Wan, Athanasios V. Vasilakos, Chin-Feng Lai, and Shiyong Wang. 2015. A review of industrial wireless networks in the context of Industry 4.0. Wireless Networks 23: 23–41. [Google Scholar] [CrossRef]
  57. Long, Fei, Peter Zeiler, and Bernd Bertsche. 2018. Realistic modelling of flexibility and dependence in production systems in Industry 4.0 for analysing their productivity and availability. Proceedings of the Institution of Mechanical Engineers, Part O: Journal of Risk and Reliability 232: 174–84. [Google Scholar] [CrossRef]
  58. Majstorovic, Vidosav, Slavenko Stojadinovic, Bojan Lalic, and Ugljesa Marjanovic. 2020. ERP in Industry 4.0 Context. Advances in Production Management Systems. Paper presented at IFIP International Conference on Advances in Production Management Systems, Novi Sad, Serbia, August 30–September 3; Cham: Springer International Publishing. [Google Scholar]
  59. Malik, Abrar, Mir Irfan Ul Haq, Ankush Raina, and Kapil Gupta. 2022. 3D printing towards implementing Industry 4.0: Sustainability aspects, barriers and challenges. Industrial Robot 49: 491–511. [Google Scholar] [CrossRef]
  60. Malik, Varun Rakesh, K. Gobinath, Santosh Khadsare, Ajay Lakra, and Subodh V. Akulwar. 2021. Security Challenges in Industry 4.0 SCADA Systems–A Digital Forensic Prospective. Paper presented at the 2021 International Conference on Artificial Intelligence and Computer Science Technology (ICAICST), Yogyakarta, Indonesia, June 29–30; pp. 229–33. [Google Scholar]
  61. Manesh, Mohammad Fakhar, Massimiliano Matteo Pellegrini, Giacomo Marzi, and Marina Dabic. 2021. Knowledge Management in the Fourth Industrial Revolution: Mapping the Literature and Scoping Future Avenues. IEEE Transactions on Engineering Management 68: 289–300. [Google Scholar] [CrossRef]
  62. Mas-Machuca, Marta, and Carme Martínez Costa. 2012. Exploring critical success factors of knowledge management projects in the consulting sector. Total Quality Management & Business Excellence 23: 1297–313. [Google Scholar]
  63. Mayastinasari, Vita, and Bayu A. Suseno. 2023. The Role of Transformational Leadership, and Knowledge Sharing on Innovative Work Behavior of Public Organization in the Digital Era. International Journal of Professional Business Review 8: e02977. [Google Scholar] [CrossRef]
  64. Medojević, Milovan, Nenad Medic, Ugljesa Marjanovic, Bojan Lalic, and Vidosav Majstorovic. 2019. Exploring the Impact of Industry 4.0 Concepts on Energy and Environmental Management Systems: Evidence from Serbian Manufacturing Companies. In Advances in Production Management Systems. Cham: Springer International Publishing. [Google Scholar]
  65. Mihardjo, Leonardus W. W., Alamsjah Sasmoko, and Elidjen Firdaus. 2019. Knowledge sharing and transformational leadership. Journal of Security and Sustainability Issues 9: 333–46. [Google Scholar]
  66. Namada, Juliana Mulaa. 2018. Organizational Learning and Competitive Advantage. In Handbook of Research on Knowledge Management for Contemporary Business Environments. Hershey: IGI Global. [Google Scholar]
  67. Nashir, Abdullah Maknun, and Sri Astuti Pratminingsih. 2023. Knowledge Sharing in Organization: Increasing Job Performance through Absorptive Capacity and Transformational Leadership. Quantitative Economics and Management Studies 4: 151–61. [Google Scholar] [CrossRef]
  68. Olejarski, Amanda M., Mike Potter, and Robert L. Morrison. 2019. Organizational Learning in the Public Sector: Culture, Politics, and Performance. Public Integrity 21: 69–85. [Google Scholar] [CrossRef]
  69. Onofre, Inês, and Leonor Teixeira. 2022. Critical Factors for a Successful Knowledge Management Implementation. Electronic Journal of Knowledge Management 20: 93. [Google Scholar] [CrossRef]
  70. Ottogalli, Kiara, Daniel Rosquete, Aiert Amundarain, Iker Aguinaga, and Diego Borro. 2019. Flexible Framework to Model Industry 4.0 Processes for Virtual Simulators. Applied Sciences 9: 4983. [Google Scholar] [CrossRef]
  71. Penumuru, Durga Prasad, Sreekumar Muthuswamy, and Premkumar Karumbu. 2019. Identification and classification of materials using machine vision and machine learning in the context of industry 4.0. Journal of Intelligent Manufacturing 31: 1229–41. [Google Scholar] [CrossRef]
  72. Pereira, Teresa, Luis Barreto, and Antonio Amaral. 2017. Network and information security challenges within Industry 4.0 paradigm. Procedia Manufacturing 13: 1253–60. [Google Scholar] [CrossRef]
  73. Pérez, Juan Bullón, Angélica González Arrieta, Ascensión Hernández Encinas, and Araceli Queiruga-Dios. 2016. Industrial Cyber-Physical Systems in Textile Engineering. In International Conference on European Transnational Education. Berlin: Springer. [Google Scholar]
  74. Pham, Lien Thi, and Ha Viet Hoang. 2019. The relationship between organizational learning capability and business performance. Journal of Economics and Development 21: 259–69. [Google Scholar] [CrossRef]
  75. Pisching, Marcos A., Fabrício Junqueira, Diolino J. Santos Filho, and Paulo E. Miyagi. 2015. Service Composition in the Cloud-Based Manufacturing Focused on the Industry 4.0. Paper presented at the Doctoral Conference on Computing, Electrical and Industrial Systems, Costa de Caparica, Portugal, April 13–15. [Google Scholar]
  76. Polívka, Martin, and Lilia Dvořáková. 2021. Selection of the ERP System with Regard to the Global 4th Industrial Revolution. In SHS Web of Conferences. Les Ulis: EDP Sciences. [Google Scholar]
  77. Popescu, Vasile Florin, and Cezar Scarlat. 2022. Supervisory Control and Data Acquisition (SCADA) Systems for Industrial Automation and Control Systems in Industry 4.0. Land Forces Academy Review 27: 309–15. [Google Scholar] [CrossRef]
  78. Prashar, Anupama, Guilherme Luz Tortorella, and V. Raja Sreedharan. 2024. Role of Organizational Learning on Industry 4.0 Awareness and Adoption for Business Performance Improvement. IEEE Transactions on Engineering Management 71: 4904–17. [Google Scholar]
  79. Rathnayake, Hasitha, Lahiru Vimukthi, Methmi Gamage, Ruwan Wickramaarachchi, and A. Withanaarachchi. 2022. Review of the State-of-the-Art of ERP 4.0 Systems. Paper presented at the 2022 International Research Conference on Smart Computing and Systems Engineering (SCSE), Colombo, Sri Lanka, September 1; 5, pp. 351–55. [Google Scholar]
  80. Saadat, Vajiheh, and Zeynab Saadat. 2016. Organizational Learning as a Key Role of Organizational Success. Procedia-Social and Behavioral Sciences 230: 219–25. [Google Scholar] [CrossRef]
  81. Santos, Maribel Yasmina, Jorge Oliveira e Sá, Carina Andrade, Francisca Vale Lima, Eduarda Costa, Carlos Costa, Bruno Martinho, and João Galvão. 2017. A Big Data system supporting Bosch Braga Industry 4.0 strategy. International Journal of Information Management 37: 750–60. [Google Scholar] [CrossRef]
  82. Saxby, Robert, Michele Cano-Kourouklis, and Evi Viza. 2020. An initial assessment of Lean Management methods for Industry 4.0. The TQM Journal 32: 587–601. [Google Scholar] [CrossRef]
  83. Seman, Shahri Abu, and Syed Jamal Abdul Nasir Syed Mohamad. 2019. Organizational Learning Capability and Organizational Innovativeness: The Mediating effect of Transformational Leadership Style of Academic Managers. Advances in Business Research International Journal 5: 104–8. [Google Scholar] [CrossRef]
  84. Skrzeszewska, Małgorzata, and Justyna Patalas-Maliszewska. 2019. Assessing the Effectiveness of Using the MES in Manufacturing Enterprises in the Context of Industry 4.0. In International Symposium on Distributed Computing and Artificial Intelligence. Cham: Springer International Publishing. [Google Scholar]
  85. Srivastava, Deepak Kumar, Vikas Kumar, Banu Yetkin Ekren, Arvind Upadhyay, Mrinal Tyagi, and Archana Kumari. 2022. Adopting Industry 4.0 by leveraging organisational factors. Technological Forecasting and Social Change 176: 121439. [Google Scholar] [CrossRef]
  86. Subramanian, Geetha, Bhushan T. Patil, and Bhaskar B. Gardas. 2021. Evaluation of enablers of cloud technology to boost industry 4.0 adoption in the manufacturing micro, small and medium enterprises. Journal of Modelling in Management 16: 944–62. [Google Scholar] [CrossRef]
  87. Tortorella, Guilherme Luz, Alejandro Mac Cawley Vergara, Jose Arturo Garza-Reyes, and Rapinder Sawhney. 2020. Organizational learning paths based upon industry 4.0 adoption: An empirical study with Brazilian manufacturers. International Journal of Production Economics 219: 284–94. [Google Scholar] [CrossRef]
  88. Tu, Yu, and Weiku Wu. 2021. How does green innovation improve enterprises’ competitive advantage? The role of organizational learning. Sustainable Production and Consumption 26: 504–16. [Google Scholar] [CrossRef]
  89. Ulmer, Jessica, Sebastian Braun, Chow Yin Lai, Chi-Tsun Cheng, and Jörg Wollert. 2019. Generic Integration of VR and AR in Product Lifecycles Based on CAD Models. Journal on Systemics, Cybernetics and Informatics 17: 25–30. [Google Scholar]
  90. Velásquez, Nancy, Elsa Clara Estevez, and Patricia Mabel Pesado. 2018. Cloud Computing, Big Data and the Industry 4.0 Reference Architectures. Journal of Computer Science & Technology 18: 29. [Google Scholar]
  91. Watad, Mahmoud. 2018. Organizational learning and change: Can they coexist? Business Process Management Journal 25: 1070–84. [Google Scholar] [CrossRef]
  92. Wong, Kuan Yew. 2005. Critical success factors for implementing knowledge management in small and medium enterprises. Industrial Management & Data Systems 105: 261–79. [Google Scholar]
  93. Xiao, Jiuling, Yuting Bao, Jiankang Wang, Haiyun Yu, Haiyun Yu, and Lei Jing. 2021. Knowledge Sharing in R&D Teams: An Evolutionary Game Model. Sustainability 13: 6664. [Google Scholar] [CrossRef]
  94. You, Jieun, Junghwan Kim, and Doo Hun Lim. 2021. Organizational Learning and Change. In Research Anthology on Digital Transformation, Organizational Change, and the Impact of Remote Work. Hershey: Information Resources Management Association. [Google Scholar]
  95. Yu, Feifei, Yue Guo, Khuong Le-Nguyen, Stuart J. Barnes, and Weiting Zhang. 2016. The impact of government subsidies and enterprises’ R&D investment: A panel data study from renewable energy in China. Energy Policy 89: 106–13. [Google Scholar]
  96. Zant, Chawki, Khaled Benfriha, Stéphane Loubère, Améziane Aoussat, and Oussama Adjoul. 2021. A design methodology for modular processes orchestration. Cirp Journal of Manufacturing Science and Technology 35: 106–17. [Google Scholar] [CrossRef]
  97. Zeba, Gordana, and Mirjana Čičak. 2020. Application of RFID Technology for Better Efficiency of Resource Planning. In New Technologies, Development and Application III 6. Cham: Springer International Publishing. [Google Scholar]
  98. Zonta, Tiago, Cristiano André da Costa, Rodrigo da Rosa Righi, Miromar José de Lima, Eduardo Silveira da Trindade, and Guann Pyng Li. 2020. Predictive maintenance in the Industry 4.0: A systematic literature review. Computers & Industrial Engineering 150: 106889. [Google Scholar]
Admsci 14 00161 g001
Figure 1. Research framework.
Figure 1. Research framework.
Admsci 14 00161 g001
Table 1. Company background definitions.
Table 1. Company background definitions.
Number of EmployeesRevenue (100 Million)Percentage of Export (%)
10~250~10~25
226~501~226~50
351~752~351~75
476 or more3 or more75 or more
Table 2. Impact of employee numbers on knowledge management promotion, organizational learning promotion, Industry 4.0, and competitiveness.
Table 2. Impact of employee numbers on knowledge management promotion, organizational learning promotion, Industry 4.0, and competitiveness.
Vector Source of Variation SSdfMSFpPost Hoc
Knowledge managementNumber of workers9.73633.2454.9290.003 **3 > 1 > 4 > 2
Organizational learningNumber of workers5.60031.8673.8600.011 *3 > 2 > 4 > 2
Industry 4.0Number of workers8.55232.8515.9280.001 **3 > 4 > 2 > 1
CompetitivenessNumber of workers10.39833.4661.2800.284
N = 129; *, p < 0.05; **, p < 0.01.
Table 3. Impact of company revenue on knowledge management promotion, organizational learning promotion, Industry 4.0, and competitiveness.
Table 3. Impact of company revenue on knowledge management promotion, organizational learning promotion, Industry 4.0, and competitiveness.
Vector Source of Variation SSdfMSFpPost Hoc
Knowledge managementrevenue11.28633.7625.8230.001 **3 > 4 > 1 > 2
Organizational learningrevenue10.56033.5207.9290.000 ***3 > 4 > 1 > 2
Industry 4.0revenue11.27033.7578.1830.000 ***4 > 3 > 1 > 2
Competitivenessrevenue28.45439.4853.6990.014 *4 > 3 > 2 > 1
N = 129; *, p < 0.05; **, p < 0.01; ***, p < 0.001.
Table 4. Impact of export on knowledge management promotion, organizational learning promotion, Industry 4.0, and competitiveness.
Table 4. Impact of export on knowledge management promotion, organizational learning promotion, Industry 4.0, and competitiveness.
Vector Source of Variation SSdfMSFpPost Hoc
Knowledge managementExport1.73330.5780.7990.496
Organizational learningExport2.70830.9031.7820.154
Industry 4.0Export3.12131.0401.9840.120
CompetitivenessExport35.758311.9194.7570.004 **4 > 3 > 2 > 1
N = 129; **, p < 0.01.
Table 5. Correlation analysis for knowledge management, organizational learning, operational management, smart production applications, information and data applications, business performance, and production performance.
Table 5. Correlation analysis for knowledge management, organizational learning, operational management, smart production applications, information and data applications, business performance, and production performance.
Related Factor1234567
1. Knowledge Management1
2. Organizational Learning0.562 ***1
3. Operational Management0.430 ***0.631 ***1
4. Smart Production Applications0.207 *0.512 ***0.684 ***1
5. Information and Data Applications0.1680.389 ***0.476 ***0.687 ***1
6. Business performance0.346 ***0.518 ***0.480 ***0.491 ***0.526 ***1
7. Production performance0.211 *0.437 ***0.390 ***0.449 ***0.456 ***0.684 ***1
N = 129; *, p < 0.05; ***, p < 0.001.
Table 6. Simple regression analysis of the impact of knowledge management on operational management.
Table 6. Simple regression analysis of the impact of knowledge management on operational management.
BSEBβtp
0.4330.0810.430 ***5.373<0.001
Note: ΔR2 = 0.185.
Table 7. Simple regression analysis of the impact of knowledge management on smart manufacturing applications.
Table 7. Simple regression analysis of the impact of knowledge management on smart manufacturing applications.
BSEBβtp
0.1870.0790.207 *2.3800.019
Note: ΔR2 = 0.043.
Table 8. Simple regression analysis of the impact of knowledge management on information and data application.
Table 8. Simple regression analysis of the impact of knowledge management on information and data application.
BSEBβtp
0.1950.1010.1681.9230.057
Note: ΔR2 = 0.028.
Table 9. Simple regression analysis of the impact of knowledge management on business performance.
Table 9. Simple regression analysis of the impact of knowledge management on business performance.
BSEBβtp
0.3780.0910.346 ***4.154<0.001
Note: ΔR2 = 0.012.
Table 10. Simple regression analysis of the impact of knowledge management on production performance.
Table 10. Simple regression analysis of the impact of knowledge management on production performance.
BSEBβtp
0.2580.1060.211 *2.4330.016
Note: ΔR2 = 0.045.
Table 11. Simple regression analysis of the impact of organizational learning on operational management.
Table 11. Simple regression analysis of the impact of organizational learning on operational management.
BSEBβtp
0.7500.0820.631 ***9.165<0.001
Note: ΔR2 = 0.398.
Table 12. Simple regression analysis of the impact of organizational learning on smart manufacturing.
Table 12. Simple regression analysis of the impact of organizational learning on smart manufacturing.
BSEBβtp
0.5470.0810.512 ***6.721<0.001
Note: ΔR2 = 0.262.
Table 13. Simple regression analysis of the impact of organizational learning on information and data applications.
Table 13. Simple regression analysis of the impact of organizational learning on information and data applications.
BSEBβtp
0.5330.1120.389 ***4.762<0.001
Note: ΔR2 = 0.152.
Table 14. Simple regression analysis of the impact of organizational learning on business performance.
Table 14. Simple regression analysis of the impact of organizational learning on business performance.
BSEBβtp
0.6690.0980.518 ***6.831<0.001
Note: ΔR2 = 0.269.
Table 15. Simple regression analysis of the impact of organizational learning on production performance.
Table 15. Simple regression analysis of the impact of organizational learning on production performance.
BSEBβtp
0.6290.1150.437 ***5.471<0.001
Note: ΔR2 = 0.191.
Table 16. Simple regression analysis of the impact of Industry 4.0 on competitiveness.
Table 16. Simple regression analysis of the impact of Industry 4.0 on competitiveness.
BSEBβtp
1.2030.1690.534 ***7.113<0.001
Note: ΔR2 = 0.285.
Disclaimer/Publisher’s Note: The statements, opinions and data contained in all publications are solely those of the individual author(s) and contributor(s) and not of MDPI and/or the editor(s). MDPI and/or the editor(s) disclaim responsibility for any injury to people or property resulting from any ideas, methods, instructions or products referred to in the content.

Share and Cite

MDPI and ACS Style

Cheng, C.-H.; Li, M.-H.; Tang, B.-J.; Cheng, Y.-R. The Impact of Knowledge Management and Organizational Learning Promotion in Small and Medium Enterprises on the Implementation of Industry 4.0 and Competitiveness. Adm. Sci. 2024, 14, 161. https://doi.org/10.3390/admsci14080161

AMA Style

Cheng C-H, Li M-H, Tang B-J, Cheng Y-R. The Impact of Knowledge Management and Organizational Learning Promotion in Small and Medium Enterprises on the Implementation of Industry 4.0 and Competitiveness. Administrative Sciences. 2024; 14(8):161. https://doi.org/10.3390/admsci14080161

Chicago/Turabian Style

Cheng, Chun-Hung, Meng-Hua Li, Bau-Jen Tang, and Yea-Rong Cheng. 2024. "The Impact of Knowledge Management and Organizational Learning Promotion in Small and Medium Enterprises on the Implementation of Industry 4.0 and Competitiveness" Administrative Sciences 14, no. 8: 161. https://doi.org/10.3390/admsci14080161

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

Article Metrics

Article metric data becomes available approximately 24 hours after publication online.
Back to TopTop