Abstract
Lean management remains the most popular approach to operational excellence within industry. The next wave of industrial improvement is widely considered to be driven by the application of digital technologies. Organizations are seeking to understand how the two approaches can be utilized synergistically. This paper aims to sketch the landscape for current theories and managerial challenges facing Lean and digital transformation based on Lean principles with respect to organizational design, supply chain planning, decision systems and supplier relationships. We raise fundamental questions that should be addressed by future research in the field of digital lean manufacturing and lean digital transformations.
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Keywords
- Lean management
- Digital transformation
- Organization design
- Supply chain planning
- Decision systems
- Supplier relationships
1 Introduction
For several decades, improvement efforts in organizations have built on the concept of “Lean Thinking” and related ideas of process standardization and continuous improvement [25]. The next wave of industrial improvement is widely considered – within industry and academia alike – to be driven by the application of digital technologies [18, 26]. Hence, there is growing appreciation among managers of the need to understand how these new digital technologies can be put to good use in order to improve efficiency and competitiveness.
Digital Lean manufacturing refers to the application of digital technology in order to enhance the Lean and learning transformation in manufacturing organizations. E-kanbans, digital problem solving, or kaizen in digital collaborative environments are some examples. In a recent article, Romero et al. [27] discussed the emergence of Digital Lean Manufacturing and the significance of digital waste that may that may come into existence in the cyber world due to the non-use (e.g. lost digital opportunities) and/or over-use (e.g. abused digital capabilities) of new digital/smart manufacturing technologies.
On the other hand, industrial experience suggests that too often technology adoption happens according to a “technology push” model: some technological component is developed or bought, and work processes are adapted to fit the technology. Technology pushes often contradict the key Lean principle that technology should serve the people and the processes [21]. Lean digital transformation, therefore, refers to the application of Lean principles to digitalization processes in order to achieve a digital transformation that creates less waste.
Management research on Lean and digitalization is still in its infancy [4, 30], as it remains poorly understood which organization models and principles make possible the best utilization of the new digital technologies [2]. This paper aims to sketch the landscape for Lean and digitalization joint transformation. We propose that novel theoretical insights can be developed by framing the relationship between the two.
2 Frontiers of Knowledge and Technology
2.1 Lean Management
Lean management, as popularized by Womack et al. [33], was ultimately a description of the philosophy and production system of the Japanese car manufacturer Toyota. Lean was subsequently presented as the global solution to improve efficiency and quality [13]. Lean has evolved over time and been embraced by other industries and in other cultures than that of its origin [25]. Five fundamental principles have been claimed to be universally applicable [34]: specification of value, identification of value streams, continuous flow, customer pull and striving for perfection. Netland & Powell [25] recently proposed a further abstraction in that Lean, cut to the core, is about continuous improvement and three essential Ls: Learning, Leadership, and Long-term perspective. In their recent book, Ballé et al. [1] challenged organizations’ traditional understanding and practicing of Lean by putting forward the Find-Face-Frame-Form strategy as a fresh new approach to understand the “true” Lean vs. the “false” one, i.e., Lean without learning. Yet, the practical application of Lean usually involves using a set of techniques such as just-in-time logistics, standardized work procedures, supplier feedback, reduction of set-up times, total quality management and statistical process controls [31].
2.2 Digital Manufacturing Technologies
As a result, from a future-oriented project, the German government coined “Industry 4.0” at the Hannover trade fair in 2011. New concepts, like Cyber-Physical System, Internet of Things, Big Data, Digital Twin, Block Chain and collaborative robot were introduced. Some of these concepts are old technologies recombined in new ways, and often incorporated with new technologies [12]. The overreaching goal of Industry 4.0 is to create highly flexible, yet high volume production lines, making processes more efficient and robust as well as reducing costs and improving the quality [20].
All of these technologies are powerful by themselves and create new opportunities, however, the core value of digitalization remains in true value creation for the customers, and at its core, to enhance “connectivity”. This connectivity can be divided into two dimensions, internal and external. Internal connectivity deals with how to connect seamlessly different technologies and work processes inside the organization [26, 30]. The external connectivity relates to data flows, system integration, etc. between companies. Important and essential quality information can be shared using the Internet of Things technology [3].
3 The Landscape
The topic of Lean and digital transformation is fairly new and complex and it requires insight from several disciplines. In order to bring further clarity into challenges associated with Lean and digitalization interactions, a fairly extensive literature review was performed during the course of this study. As a result, four categories for further research are proposed. These categories correspond to four theoretical domains that are: organization theory, operations management, operations research and inter-organizational business relationships. In this section, each of these categories are briefly explained and some outstanding questions that ought to be addressed by further research are put forward.
3.1 Organizational Design
The Lean work organization is characterized by both functional integration and integration of performance and control [5, 15]. Extensive involvement of operators is premised on this organization design, as it empowers the shop floor vis-à-vis specialist functions. Digital technologies can support such an organization design, by providing faster and more reliable information for operational decision-making and continuous improvement activities [30]. If the technology is designed with this purpose, the relationship between Lean and digitalization may be synergistic. However, these synergies are not realized if the digitalization drives an organization-wide redistribution of decision-making power in favor of ICT-specialists organized in staff functions. For several reasons, such a redistribution of power is a likely development. Firstly, knowledge about how to design, configure and maintain the technologies will be a scarce resource, making the shop floor more dependent on outside expertise. Secondly, the big investments associated with digital technologies call for organization-wide standardization of technology, limiting the shop floor’s discretion on the choice of technology and how to operate it. Thirdly, when continuous improvement becomes more analytical and data-driven, it relies more heavily on theoretical knowledge and require a deeper understanding of statistics. Hence, it may likely become the domain of experts, rather than shop floor workers [14]. These tendencies clearly contradict the Lean principles of creating functional integration at the shop floor.
To address these challenges, the following questions can be put forward:
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How are the collaboration between the shop floor and ICT-specialists reconfigured considering digitalization?
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How can digital technology be designed to support functional integration at the shop floor?
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How may shop-floor workers and managers be trained to master the digital technologies, so that they retain participation in continuous improvement activities?
3.2 Supply Chain Planning
Supply chain planning aims to improve performance in operations by mitigating uncertainty through managing operations and customer demand, and coordinate supply chain activities with business strategy. With principles leading to elimination of waste, improving quality, cost reduction and increasing flexibility, the Lean concept has strongly influenced existing planning models and made planning highly sensitive to disturbance and variability [7, 9]. However, driven by technology combined with shifting supply and market complexity such as globalization, customization and serving individual needs instead of market categories [3], variability and uncertainty increases. While planning is becoming more demand and event driven (real-time, increased frequency, shorter planning horizon and cross functional), and turned into a process within the supply chain rather than in individual companies, the complexity and uncertainty increases [16].
Information technology strongly facilitates planning models by efficiently allowing access to information, advanced analytics and integrating operations between supply chain partners and across functions, which is crucial in most Lean programs [23]. However, technology may also come into conflict with Lean or in short of unlocking the potential by a standardized functionality and design, hindering the support of complex planning environment and interaction between the partners in the supply chain [28].
To address these challenges, these questions can be raised:
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Why and how are digital technologies influencing supply chain planning?
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How do digital technologies affect roles and responsibilities in supply chain integration?
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How can digital technologies be designed to support supply chain planning?
3.3 Decision Systems
Quantitative models and methods have been used for decades to provide decision support within operational production and logistics planning (see e.g., [11]). Many of these models have been made available to companies through commercially available Advanced Planning Systems [19]. Traditionally, most models for operational production, inventory, and distribution planning assume centralized decision making [6, 32]. Lean principles, however, advocate decentralized planning at the lowest possible planning level [5].
Digitalization and advances in information technology will make more data faster available to a decision maker, for example, through the extensive use of sensors monitoring state and surroundings of a production system (or product), or the Internet of Things (see Sect. 2.2). This will lead to more and more data-driven decisions, taking into account a much more comprehensive view of the production system [24].
To evaluate the impact these developments have on Lean principles, the following questions should be addressed:
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Will digitalization lead to more centralized decisions? It has long been recognized that systems need to be optimized as an entity, rather than optimizing subsystems [10]. Using large amounts of data in order to provide decisions for the entire system may push towards more centralized decisions.
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How can local decisions be coordinated in order to optimize the entire production system? Local decision makers may not only need access to vast amounts of data, but also help in understanding the consequences of their decisions. This applies especially in situations where e.g. local maximization of capacity utilization is counterproductive with respect to total cost within the production system.
3.4 Supplier Relationships
While most research on Lean management has focused on intra-organizational applications of Lean principles [17], some attention had been paid to inter-organizational applications, e.g. to develop Lean suppliers and supply networks [8, 22]. Digital communication and decision making with the need for and advantages of personal communication and participative decision making at both the suppliers and buying firm are, therefore, very important.
Furthermore, while some efforts have aimed at offering assistance to suppliers in order to improve their performance in the short run, strategic supplier development efforts have aimed at encouraging and enabling suppliers to develop their Lean capabilities by means of which the suppliers can continuously improve their Lean practices and performance [29]. Suppliers have been encouraged to find their “own Lean way” [25], thus preserving the autonomy of the suppliers. Finally, the development of Lean supplier networks has considered challenges of competitive rivalry, and for example, Toyota has taken care to create separate arenas for interaction with suppliers who are in direct competition [29], whereas Honda has had joint arenas.
The potential of digital technologies to transform performance is now widely recognized, and a few contributions connect efforts at digital transformation with Lean supply principles [26], however, how digitalization can facilitate as well as hamper the manner in which manufacturing firms encourage, enable and enforce the development of Lean practices in their supplier relationships and networks is still challenging.
To address these challenges, the following questions can be raised:
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How can the key characteristics of Lean supplier relationships and networks be reconfigured considering digitalization, with the aim to improve the cost efficiency and the effectiveness of such efforts?
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How can digital technology be used for enabling and enforcing interaction, mutual trust, and knowledge-sharing routines between the suppliers and a buying customer, and between suppliers who may cooperate and compete?
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How can the integrity and autonomy of suppliers be preserved when they become connected in supplier networks by means of digital technologies with requirements for standardization?
4 Conclusion
In this paper, we have sketched the landscape for Lean and digital transformations. Interactions between the two improvement strategies and associated challenges are poorly understood in the current literature. This contribution sheds light on the landscape by classifying various challenges in four areas and proposing key questions for future research. The four areas are organizational design, supply-chain planning, decision systems, and supplier relationship. Although these areas correspond to established management disciplines, Lean- and digital transformations are multidisciplinary in their nature. Therefore, in addition to doing in-depth research within each area, researcher might work together in multidisciplinary team to create workable knowledge addressing practical challenges more holistically.
We hope our framework and research questions will trigger further discussions and research that aims to help organizations obtaining a correct strategy in their pathway towards Lean, learning and digital organization. For practitioners such a framework might be instrumental in clarifying the different aspects of a complex problem.
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Ashrafian, A. et al. (2019). Sketching the Landscape for Lean Digital Transformation. In: Ameri, F., Stecke, K., von Cieminski, G., Kiritsis, D. (eds) Advances in Production Management Systems. Production Management for the Factory of the Future. APMS 2019. IFIP Advances in Information and Communication Technology, vol 566. Springer, Cham. https://doi.org/10.1007/978-3-030-30000-5_4
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