Abstract
Purpose
This paper aims to examine the relationship between supply integration and firm performance by first, investigating the mediating effects of manufacturing flexibility and mass customization; and second, exploring the moderating role of innovation orientation on the link between internal capabilities and performance.
Design/methodology/approach
Resource orchestration and contingency theories are used to address the mediating and moderating effects. A cross-sectional data set on 242 Swedish manufacturers is used to test for the hypotheses using structural equation modeling.
Findings
The findings provide support for the mediating roles of manufacturing flexibility and mass customization in the relationship between supply integration and firm performance. However, the results point to contrasting contingent effects of innovation orientation. While innovation orientation positively moderates the association between mass customization and firm performance, it shows a negative impact on the link between flexibility and performance.
Research limitations/implications
The study contributes to the literature on the integrative activities with upstream supply chain actors. Specifically, the authors highlight how specific capability configurations comprising of supply integration, manufacturing flexibility and mass customization lead to firm performance. Moreover, the authors provide insights on the contingency role of innovation, especially if firms consider flexibility or customization capabilities.
Originality/value
While the individual impacts of flexibility and customization on performance have been addressed previously, there is a paucity of research on how these two capabilities are integrated with supply integration. Moreover, there is little known regarding the role of innovation orientation on these integrated relationships.
Keywords
Citation
Jafari, H., Ghaderi, H., Eslami, M.H. and Malik, M. (2022), "Leveraging supply integration, mass customization and manufacturing flexibility capabilities and the contingency of innovation orientation", Supply Chain Management, Vol. 27 No. 7, pp. 194-210. https://doi.org/10.1108/SCM-05-2022-0177
Publisher
:Emerald Publishing Limited
Copyright © 2022, Hamid Jafari, Hadi Ghaderi, Mohammad H. Eslami and Mohsin Malik.
License
Published by Emerald Publishing Limited. This article is published under the Creative Commons Attribution (CC BY 4.0) licence. Anyone may reproduce, distribute, translate and create derivative works of this article (for both commercial and non-commercial purposes), subject to full attribution to the original publication and authors. The full terms of this licence maybe seen at http://creativecommons.org/licences/by/4.0/legalcode
1. Introduction
Why and how some firms are more successful than others is the ongoing focus of research in the operations and supply chain (SC) literature. The resource-based view (RBV) has been an influential theoretical lens to explain “why the performance across firms vary” from a resource heterogeneity perspective (D’Oria et al., 2021), but it does not answer “how some firms outperform others” (Malik et al., 2021). The RBV suggests a direct relationship between the possession of strategic resources and competitive advantage, which has been criticized as a “black box” conceptualization because it ignores the managerial actions that are needed to translate the possession of strategic resources into performance (Gligor et al., 2022a). The resource orchestration theory (ROT) addresses this shortcoming of RBV by “looking into the black box” to explain how managers structure and bundle resources to create unique capabilities and the specific ways in which the combinations or configurations of complementary capabilities are leveraged to create a sustained competitive advantage (Sirmon et al., 2007). The notion of capability configurations is central to the ROT because it describes the specific ways in which the complementary capabilities are coordinated and deployed to create value (Malik et al., 2021). The ROT is specifically relevant to the SC literature because of its ability to explain how a firm’s internal capabilities are integrated with supplier facing capabilities to leverage competitive advantage (Chavez et al., 2021). Integrating resources to create capability configurations comprising of internal capabilities and supplier facing capabilities is rather complex (Adams et al., 2014) but essential for a competitive advantage (Wiengarten et al., 2019). We contribute to this stream of literature by suggesting the specific ways (a capability configuration) in which internal and supplier facing capabilities are coordinated and deployed to gain competitive advantage. In doing so, we delineate how managers orchestrate strategic resources into idiosyncratic capabilities that are difficult to replicate and hence, provide competitive advantage (Carnes et al., 2022).
We specifically draw on the leveraging process of the ROT to conceptualize and empirically test a configuration of three types of capabilities for competitive advantage:
internal production related capabilities (manufacturing flexibility [MF] and mass customization [MC]);
supplier facing capability (supply integration [SI]); and
the strategic orientation of firm toward innovation (innovation orientation [IO]).
This conceptualization is consistent with the resource advantage leveraging strategy for the manufacturing sector to produce incremental product improvements for expansion of existing markets (Carnes et al., 2022). In this research, we posit that MF is a key internal capability to produce incremental product improvements (Ramos et al., 2021) and MC enables the product improvements to be expanded to the existing market (Liu et al., 2021). Thus, our thesis in this study is that in conjunction with SI, MF and MC capabilities leverage a resource-based advantage for a manufacturing sector. MF is defined as the ability of a system to efficiently respond to both internal and external uncertainties with minimum resource compromise (Ramos et al., 2021). Firms with high MF are more efficient to change output volumes and adjust their production system to accommodate for a different mix of products demanded by customers (Nawanir et al., 2020). MC is another internal production related capability that refers to the ability of a manufacturing system to allow its customer to personalize and/or customize the features of products at a cost and timeframe comparable to mass production (Qi et al., 2020). MC allows manufacturing firms to differentiate their products, create customer value, and, therefore, outperform competition (Salvador et al., 2020). The SC literature, however, suggests integration of internal capabilities with suppliers to stay competitive (Chen and Paulraj, 2004). SI capability represents the ability of a firm to seamlessly integrate the logistics functions with upstream end of the value chain (Stock et al., 2000, p. 535). The literature has addressed the individual effects of the MF and MC on firm performance (FP), but how these two internal capabilities are integrated with SI and if these integrated relationships are affected by the IO of a firm is unknown.
We address this literature shortcoming by drawing on the ROT to explicate how managers orchestrate actions to fully exploit the “structured and bundled resources” for a resource-based advantage (Carnes et al., 2022). This line of inquiry has allowed us to respond to the recent calls in the literature to investigate the specific ways in which strategic resource are used (orchestration actions) to create value because possession of strategic resources is not enough for a competitive advantage (D’Oria et al., 2021). In doing so, we provide more clarity and detail to the operations and SC literature on the importance of specific leveraging actions (mobilization, coordination and deployment) that the managers need to undertake to connect “resource possession” with performance realization (Sirmon et al., 2011). Effective leveraging actions correspond to capability configurations that provide a market fit and, therefore, a source of competitive advantage (Gligor et al., 2022a). In this study, we conceptualize and empirically test a capability configuration – internal production capabilities of MF and MC mediate the relationship between the supplier facing capability (SI) and FP. Our thesis in this research is that the proposed mediation of the relationships between SI and FP by MF and MC represents effective leveraging actions because the literature suggests that a sustained high FP reflects a firm’s competitive advantage (Malik et al., 2021). Specifically, our first research question (RQ) is:
Do MF and MC mediate the relationship between SI and FP?
In this study, we also examine the contingency of the strategic orientation of a firm toward innovation (IO) on how the capability configurations are leveraged. A firm’s strategic orientation reflects business tendencies toward a set of activities, which the literature also recognizes as a strategic capability that affects performance (Schweiger et al., 2019; Baker et al., 2022). IO has become a core concept to examine firm behavior toward developing innovation-enabling competencies related to resource allocation, technology, employees, operations and markets (Simpson et al., 2006; Chen et al., 2022). In resource-constrained environments, IO is known as a desirable organizational attribute that fosters creativity, facilitates new forms of resource mobilization, and allows organizations to “anticipate” and “react” to market requirements quicker than their counterparts (Lii and Kuo, 2016). While there are suggestions for the positive contribution of MF and MC toward FP, drawing on the contingency theory (CT) (Sousa and Voss, 2008), we seek to generate additional insights by examining the moderating effect of IO for the relationships between internal capabilities (MF and MC) and FP. Specifically, we also investigate:
Does IO moderate the effects of MF and MC on FP?
In Section 2, we provide further details on the theoretical underpinnings for this research, while in Section 3, we develop support for the conceptualized mediating and moderating hypotheses. Section 4 describes the research methodology, and the results. A discussion on the results in terms of theoretical contributions and managerial implications is carried out in Section 5. We conclude the paper with limitations and directions for future research in Section 6.
2. Theoretical foundations
2.1 Resource orchestration theory
ROT, the theoretical lens to answer RQ1, is in the intellectual lineage of the resource-based inquiry to explain “why and how some firms outperform others” (D’Oria et al., 2021). The genesis of this line of inquiry is the RBV which suggests that the firms possessing strategic resources that are valuable, rare, inimitable and nonsubstitutable would have a competitive advantage (Kraaijenbrink et al., 2010). The RBV, however, gave a partial explanation because its focus is on why firms outperform others, and it does not provide enough details on how the strategic resources enable a competitive advantage (Gligor et al., 2022a). The augmentation of the RBV to more adequately answer the variations in FP began with the inquiries on how strategic resources are transformed into idiosyncratic firm capabilities (Sirmon et al., 2011). Resources in the resource-based inquiry refer to both tangible and intangible assets that a firm has access to, whereas a firm’s capability is derived from using the strategic resources to perform a set of tasks to achieve an outcome (Malik et al., 2021). This shift of focus in the resource-based inquiry from “resource possession” to “resource usage” led to the emergence of the dynamic capabilities (DCs) and the ROT – both DC’s and ROT provide a complementary logic to enhance our understanding of how some firms outperform others. Dynamic Capabilities theory doesn’t sufficiently differentiate between the “resources that are inputs to the firm and the capabilities that enable the firm to select, deploy and organize such inputs” (Kraaijenbrink et al., 2010). Thus, despite acknowledging the value of organizational responses to the rapidly changing external environment, DC’s fall short of examining the key managerial actions to integrate and apply idiosyncratic capabilities for a competitive advantage (D’Oria et al., 2021). The ROT, on the other hand, establishes managerial actions firmly in the nomological network to explain the “black box” of resource possession and competitive advantage (Sirmon et al., 2007).
Specifically, ROT identifies managerial roles to create competitive advantage along three interdependent processes of structuring, bundling and leveraging (Sirmon et al., 2011). Structuring process describes how managers create a portfolio of strategic resources either through acquisition, accumulation or/and divestment. The bundling process puts the spotlight on how managers combine resources to create capabilities which are then used by the leveraging process, as complementary capability configurations, to meet specific market needs (Malik et al., 2021). This capability-market-need fit then translates into competitive advantage (Sirmon et al., 2007). We specifically draw on the “leveraging” process of the ROT as the theoretical framework because leveraging actions are the missing link in connecting “structured and bundled resources” to performance (Carnes et al., 2022). For effective leveraging, the three managerial actions of mobilization, coordination and deployment need to be synchronized. Mobilization refers to the identification of capabilities needed for a specific market and the design of a leveraging strategy to establish the capabilities-market fit (Sirmon et al., 2011).
A ROT leveraging strategy appropriate for a manufacturing context (our study sample) is the “resource advantage” to produce incremental product improvements for expansion of existing markets to strengthen the market advantage (Carnes et al., 2022). Consistent with the resource advantage leveraging strategy for the manufacturing sector, we conceptualize MF as a key internal capability to produce incremental product improvements and MC as an internal capability to expand the existing market. MF is the ability of a firm to efficiently respond to both internal and external uncertainties (MF) (Ramos et al., 2021) and MC is the ability of a manufacturing system to mass-customize (Liu et al., 2021; Qi et al., 2020). Further details on how the two internal capabilities contribute to competitive advantage have been identified in Section 3. Effective leveraging also requires the internal production capabilities of a firm to be integrated with the ability of a firm to integrate its operations with its suppliers (SI) (Boone et al., 2018). The specific ways (capability configuration) in which MF, MC and SI are integrated is determined by the “coordinating” action of the leveraging process of ROT. Coordinating internal capabilities with SC partners is challenging because of conflicting objectives, differences in resource base and core competencies, cultural differences and commitment issues (Adams et al., 2014). The resource orchestration actions relevance to answer RQ1 is accentuated here because the managerial relational skills to build a social capital (within and across firms in SC’s) plays an important role in effective capability coordination (Sirmon et al., 2007). The physical deployment of capability configuration is the third and the final managerial action within the leveraging process of the ROT. The deployment actions heavily draw on the explicit and tacit managerial knowledge and skills to build and maintain the resource base advantage that translates into a competitive advantage (Sirmon et al., 2011; Gligor et al., 2022a). Taken together, mobilization, coordination and deployment are the three sets of orchestration actions representing managerial knowledge and experience that explain how firms may perform differently despite have similar resource base.
2.2 Contingency theory
To address RQ2, we draw on the theoretical lens of CT, which suggests that the relationship between the explanatory variables and the outcome is affected by contingencies such as national context, organization factors (e.g. firm size, age, industry type) and the strategic context of a firm (Sousa and Voss, 2008). Recently, more attention has been directed toward elucidating and explaining how strategic context or orientation of a firm can influence the effectiveness of its practices (Schweiger et al., 2019; Baker et al., 2022). In line with CT, we suggest that a strategic orientation toward innovation acts as a moderating force on the relationships between internal capabilities and FP. Often, when change or improvement is introduced in similar ways across multiple firms, the performance is variable (Chavez et al., 2021), and thus, the benefits are not being fully materialized. Such phenomena can be explained by the lack of innovation culture or orientation in organizations (Simpson et al., 2006; Hughes et al., 2019). According to Wei and Wang (2011), firms with higher IO tend to be quicker and more efficient in materializing new ideas in response to market requirements. Therefore, in such firms, innovative ideas and processes are being spread at a faster rate and wider acceptance (Chen et al., 2009). Hence, we advance the proposition that firms with higher IO could capitalize on their MF and MC capabilities toward achieving a more competitive position (Stock and Zacharias, 2011).
3. Literature review and hypothesis development
3.1 Supply integration
With the developments of supply chain management (SCM), firms have realized the importance of reaching out to SC actors to combine, coordinate, collaborate and align their objectives, resources and capabilities to stay competitive and spread risks (Soosay and Hyland, 2015). Nevertheless, attempts to integrate resources with external parties is a rather complex process due to the heterogeneity of resources, cultural differences, resistance and commitment issues (Adams et al., 2014); to an extent that often an external party is often used to “orchestrate” the interorganizational resources (Zacharia et al., 2011).
Logistics integration is defined as the “specific logistics practices – operational activities that coordinate the flow of materials from suppliers to customers throughout the value stream” (Stock et al., 2000, p. 535). External integration typically involves extensive information sharing, collaborative planning, IT capability and logistics assets, which is highly dependent on the resources and capabilities of the firm and those of the respective SC actors (Chavez et al., 2021). Often in SCM research and practice, closely working with a select number of key suppliers is preferred to arms-length relationships with large number of actors in achieving integration (Paulraj and Chen, 2007). Lack of a strategic view on integration among SC actors could lead to complexities and conflicts, whereas integration with suppliers has proven to streamline risk management initiatives (Munir et al., 2020). Therefore, SC orientation is often considered as necessary philosophy in achieving integration (Boone et al., 2018). Seamless SI results in configuring the interorganizational boundaries, and avoiding logistics challenges, including the bullwhip effect (Prajogo and Olhager, 2012).
3.2 Manufacturing flexibility
Upton (1994) defines flexibility as the ability of a manufacturing system to respond to change with minimum resource compromise. Since the early introduction of computers and advanced automation, flexibility has become a desirable attribute of manufacturing systems and a key capability to efficiently respond to both internal and external uncertainties (Chaudhuri et al., 2018). MF is conceptualized as the ability of a firm to manage production resources against such uncertainties to meet various customer requests (Zhang et al., 2003). A major portion of the literature has a central focus on characterizing different types of flexibility and developing taxonomies, while more recent studies aim at conceptual and empirical examination of its performance implications (Nawanir et al., 2020; Chaudhuri et al., 2018).
Particularly, earlier studies on MF have distinguished between two types of flexibility: resource and manufacturing system flexibilities. Resource or lower-order or internal flexibility refers to the specific instruments and techniques applied to achieve flexible attributes, including those related to processes, workforce and equipment (Pérez-Pérez et al., 2018). On the other hand, high-order or external flexibility types are those that directly influence the competitive position of a firm, with volume and mix known as the most prominent types. Volume flexibility is defined as the ability of a firm to adjust volumes to varying changing demands by operating at a variety of batch sizes and/or different production output levels with minimum disruption (Scherrer-Rathje et al., 2014). Mix flexibility, on the other hand, is associated with the ability to manufacture various combinations of products economically and effectively (Nawanir et al., 2020). Through the lens of DCs, Zhang et al. (2003) provide a unique conceptualization for such interaction, by formulating internal-external flexibilities as competence-capability mechanism. They argue that internally facing flexible competences are fundamental to support the development of flexible manufacturing capability, desired by and visible to the customer. Considering the competitiveness implications of flexibility as a capability that influence firm’s position in the market (Mishra and Mishra, 2019), volume and mix flexibility types are the main emphasis of this study.
3.3 Mass customization
MC has emerged as the new manufacturing paradigm in practice to blend the advantages of tailored manufacturing and economies of scale from mass production. As a manufacturing capability, MC refers to the ability to meet heterogeneous customer requirements by offering a high volume of customized product options (Liu et al., 2021). Hence, central to MC capability are cost efficiency, high volume production, product quality and reliable customer service-levels characterized by on-time delivery (Qi et al., 2020; Huang et al., 2008). Therefore, several trade-offs should be taken into account by a manufacturing organization when selecting and implementing the right manufacturing strategy – standardization vs MC – depending on the products type, market segment and costs (Shao, 2020). Nevertheless, generally, capitalizing on MC has been stressed to outperform competition in the long tail and creating customer value (Salvador et al., 2020; Pérez-Pérez et al., 2018). A variety of MC typologies have been presented depending on industries, level of customer involvement, product modularity and SC complexity (Swaminathan, 2001; Suzić et al., 2018). In leveraging and realizing MC, managing the upstream SC is often cited as a major challenge (Pérez-Pérez et al., 2018).
The popularity of MC should be considered in relation to the technological and informational developments, as well as intensified competition, shortened product life cycles and increasingly varying customer demand (Kim and Lee, 2022). The literature proposes several mechanisms to achieve MC. For example, modularity facilitates MC by decreasing complexities and operational challenges in processes and components (Wang and Zhang, 2020). Similarly, postponement strategies have a contributing role to this process (Purohit et al., 2016). Digital technologies, as well as lean and agile practices, have been regarded as other enablers of MC (Purohit et al., 2016; Wang and Zhang, 2020; Tu et al., 2004).
3.4 Innovation orientation
IO reflects a firm’s culture encouraging its members to create, contribute to and experiment new ideas (Hurley and Hult, 1998; Chen et al., 2009). As a strategic orientation, it is defined as “the capacity to introduce some new process, product or idea in the organization” (Hult et al., 2004, p. 430). Siguaw et al. (2006) describe IO as a complex knowledge structure which involves a “learning philosophy, strategic direction, and transfunctional beliefs.” Stock and Zacharias (2011) conceptualize IO in relation to a set of internal arrangements, including strategy, structures and processes, human resource systems, organizational culture and leadership. Firms are adopting IO foster a philosophy which reflects the deep-rootedness of innovation and creativity to challenge the status-quo (Lii and Kuo, 2016). IO is preceded by learning orientation, and other organizational and cultural factors, such as power sharing and communication, participative decision-making, tolerance for conflict and risk, as well as support and collaboration (Hurley and Hult, 1998). IO, which is sometimes used interchangeably with or in strong connection to product or technology orientation, has shown to have associations with market orientation of the firm (Grinstein, 2008). In fact, Berthon et al. (2004) maintain that customer (or market) and innovation (or product/technology) orientations are not mutually exclusive.
With such capacity, firms can be more responsive, develop new capabilities; and hence, have a higher chance for developing competitive advantage (Hurley and Hult, 1998; Chen et al., 2009). Hult et al. (2004) found support for innovativeness to be the outcome of market, learning and entrepreneurial orientation of firms. On the other hand, scholars have drawn attention to balancing the benefits and potential pitfalls of innovativeness in the short- and long-run (see also Yu et al., 2020). For instance, Simpson et al. (2006) underlined both positive and negative outcomes of IO in terms of market, employees and operations. As such, while IO could lead to outperforming competition or higher customer and employees job satisfaction, it may result in product failures, job stress or increased costs. Empirical and conceptual contributions regarding IO in SCM research are scant; even so, the limited studies have different approaches in positioning IO in the overall SC or capability building framework. Hult et al. (2002) conceptualize innovativeness, along with learning and entrepreneurship, as an indicator of cultural competitiveness in SC’s. A few studies have focused on the nexus of IO and manufacturing or SC-related capabilities (Clauss and Spieth, 2016; Chen et al., 2022). For instance, Lii and Kuo (2016) found that IO positively influences integration along the SC by fostering cooperation and trust among SC partners, especially in new products and meeting customer demand.
3.5 Firm performance
Measuring FP is a well debated topic in the SCM literature due to its multidimensionality implications for both internal and external decision-making. Generally, metrics are verifiable measures, which are “defined with respect to a reference point” (Melnyk et al., 2004, p. 3). Thereby, FP has been widely measured relative to the performance of competitors or the industry average. Predominantly, in the operations and SCM literature, FP is measured quantitatively, both in objective and subjective forms. The most prevalent operationalizations of FP are operations-related – reflecting customer service levels in terms of on-time and accurate delivery, product quality and competitive position, as well as business-related – reflecting financial performance (Flynn et al., 2010; Wisner, 2003; Gu et al., 2017). Other studies suggest including relational performance as another dimension of FP in regard to interorganizational performance of firms in the SC context (Gligor et al., 2022b). While prior research has documented the sequential relationships among the dimensions of FP, some studies opt for a unified and comprehensive approach of measurement. For instance, Green et al. (2008) provide support for operational and logistics performance resulting in financial performance via market-facing performance. Yet, to capture FP, Green et al. (2019) use a single construct composed of several indicators. Widely agreed in the literature, FP is impacted by the competencies and capabilities of firms (Hüseyinoğlu et al., 2020). Following this line of reasoning and based on ROT, we seek to investigate the mediated effects of SI on FP via MC and MF capabilities.
3.6 Research hypotheses
3.6.1 The mediated effects of supply integration on firm performance
The performance outcomes of integration are nonconclusive. Several contributions have suggested indirect effects of SI on FP. For instance, SI could have benefits for both parties in dyadic relationships, ranging from supplier development to delivery performance and overall cost reduction (Devaraj et al., 2007). The early configurational study by Frohlich and Westbrook (2001) revealed that “outward” integration appears to have the strongest association with performance among all types within the “arcs of integration.” On the other hand, given that SI is a long-term exercise, requiring significant investments in resources and mutual trust, it can incur high costs. For instance, Flynn et al. (2010) found no support for the impact of SI on operational or business performance.
Drawing on ROT, we maintain that the competitive advantage from SI can be realized once SI is translated or materialized into other capabilities. This is in line with prior research, which suggests that the effect of SI on market or competitive performance is channeled through competitive capabilities (Rosenzweig et al., 2003; Swink et al., 2007). In this regard, supplier relationships can influence operational and competitive strategies (Prajogo and Olhager, 2012). Since logistics has a coordinating mechanism within firms and along the SC’s, SI plays a significant role in facilitating time-based competitive capabilities and strategies such as JIT, especially in globally spread SC’s (Paulraj and Chen, 2007). Nowadays, manufacturing firms are facing extreme demand volatility and rapid changes in channel requirements, which generally requires adjustments to product volume and mix (MF). Furthermore, driven by recent technological advancements, MC is increasingly becoming a key capability for manufacturing firms to produce large scale product variety without increasing costs or sacrificing quality (Qi et al., 2020; Liu et al., 2021). We argue that since both MF and MC have a direct interface with the upstream facing integration and capabilities (SI), they could act as transformative and intermediary mechanisms between SI and FP in markets characterized by demand volatility.
Several theoretical lenses are used to explain this mediated relationship, including the dynamic capability perspective (Vanpoucke et al., 2014) and strategic fit theory (Swink et al., 2007). In this regard, we argue that ROT provides a more suitable lens for explaining how the performance outcomes resulting from SI are channeled via the intermediary competitive capabilities of MF and MC. In this regard, leveraging capabilities involves resource configuration for exploiting market opportunities and value creation (Sirmon et al., 2007). We test the indirect effects of SI (independent variable) on FP (dependent variable) via MF and MC (mediating variables). The ROT perspective allows for explaining how orchestrating resources and/or resource flows with suppliers can be bundled and leveraged with internal capabilities such as MF and MC (Hitt, 2011).
3.6.2 The role of MF
SI has been widely discussed as a main contributor to increasing flexibility. Integration facilitates matching resources with demand, and supports flexibility in uncertain markets by seamless communication and complexity reduction (Swink et al., 2007). Sharing critical information regarding inventory planning and forecasting enables manufacturers to improve their decision-making regarding capacity allocation and planning (Vanpoucke et al., 2014). Therefore, SI is influential in shaping different SC configurations, which results in volume and mix flexibility (McKone-Sweet and Lee, 2009). Supplier-facing logistics integration (e.g. use of common logistics resources, equipment or third-party logistics providers, as well as delivery coordination) could also have benefits in terms of changeover times, lead-times and labor productivity (Frohlich and Westbrook, 2001). Therefore, via SI, manufacturers are in a better position to quickly change production volumes and/or change over to other products in response to demand variations (Liu et al., 2018). As a result, integration facilitates smooth operations and delivery processes and supports dynamic processes (Vanpoucke et al., 2014).
By taking an RBV and information processing theory perspective, Schoenherr and Swink (2012) elaborate on why and how integration could help internalize partners’ resources and capabilities, leading to flexibility. Therefore, the well-established literature shows a direct positive link between SI and flexibility (Devaraj et al., 2007). In turn, the effect of flexibility on FP has been an area long gaining scholarly attention, notwithstanding their respective dimensions (Upton, 1994). The types of MF have evolved and been often discussed within the context of SC flexibility or agility. Nevertheless, research on the performance outcomes of MF is prevalent, primarily regarding it as critical in gaining competitive advantage (Pérez-Pérez et al., 2018) or the costs associated with its setup and implementation (Olhager, 1993). While prior research has underlined the “intervening” role of flexibility in linking integration with firm competitive performance, they conceptualize MF as a subdimension of SC flexibility; hence, limiting conclusions regarding the individual role of MF (Jin et al., 2014). In this regard, and drawing on ROT, we argue that MF resulting from SI would create a unique capability configuration, which could lead to competitive advantage. Therefore, we posit that:
MF mediates the relationship between SI and FP.
3.6.3 The role of mass customization
To ensure raw materials, components, modules, resources and information are available to meet MC requirements, a seamless coordination with SC partners is essential. While the research on internal competencies, tools and techniques for successful MC implementation is ample (Suzić et al., 2018), we draw further attention to the boundary-spanning of SC initiatives beyond the firm. We maintain that MC requires orchestrating activities and sharing information with SC actors. SI supports leveraging MC capability in better capturing, forecasting and processing demand to more effectively procuring components, and developing products and processes (Liu et al., 2018). For instance, information-sharing not only supports synchronized decision-making but also can act as a monitor mechanism to observe the dynamics in operations and along SC’s (Jin et al., 2014). Therefore, SI is crucial to enable MC (Fogliatto et al., 2012). Nevertheless, despite the costs associated with leveraging MC, several operational and strategic benefits result from MC (Wang and Zhang, 2020), including cost efficiency, customer value, product quality, delivery and product innovation (Zhang et al., 2019; Qi et al., 2020).
MC can also manifest the effective implementation of integration in the SC (Kotzab et al., 2021). Through collaboration and SI, the assembly and configuration of resources, knowledge, skills and assets are further fostered, which enables operational productivity and enhanced customer service (Adams et al., 2014). We contend that ROT provides a proper lens in this regard. Therefore, we posit that collaborating with upstream suppliers in aligning resources and logistics activities, is critical in realizing MC and addressing customer demand. Thus, a unique configuration of orchestrated resources and capabilities with upstream suppliers could be shaped to exploit and capitalize on market opportunities, which ultimately leads to gaining competitive advantage. Thus, we posit that:
MC mediates the relationship between SI and FP.
3.6.4 The moderating effects of innovation orientation
Strategic orientations are manifested in organizations’ culture, and IO has attracted scholarly attention as a relevant contextual factor. IO becomes even more relevant in environments associated with turbulence since uncertainty necessities adopting innovations to stay competitive (Mishra and Mishra, 2019). According to Berthon et al. (2004, p. 1068), IO has the potential to even “create markets” by “determining the nature of demand.” Therefore, IO can act as a catalyzer in how capabilities are mobilized to address demand dynamics. Innovation-oriented firms support using and developing new resources, enabling them to overcome complications in implementing new idea, products, processes or systems (Hurley and Hult, 1998; Chen et al., 2022). Moreover, in meeting disruptions and challenges, an IO atmosphere allows firms to develop creative recognition of resources and capabilities at their disposal (Chen et al., 2011).
Strategic orientations play significant roles in shaping business strategies. Meanwhile, matching capabilities with firm strategies is critical in achieving competitive advantage, mainly because capabilities per se may not guarantee success. Chang et al. (2003) underlined that MF does not necessarily lead to improved performance under all circumstances and that the resulting FP is contingent on firm’s strategies. In this regard, the role of contingencies in attaining FP from flexibility has been widely stressed by prior research (Vokurka and O’Leary-Kelly, 2000). Based on CT, we argue that an innovation culture within the firm fosters creativity in combining and leveraging resources, as well as seeking for alternatives in production system. For instance, if innovative ideas are supported by management and proposed by production teams, they can effectively support multitasking or reduce changeover times in production lines to meet customer demand quicker (Yu et al., 2020). Also, in addressing production challenges, IO serves as a culture supportive of creativity in providing solutions. Therefore, one can expect more efficient and profitable production operations, and hence competitive position. According to Mishra and Mishra (2019), IO helps predict requirements and grasp opportunities in the market, and as a result, supports how flexibility leads to better FP. Hence, IO supports how the performance outcomes of flexibility in manufacturing systems and processes are manifested.
Strategic orientations, including IO, lead to competitive advantage, specifically, in terms of both incremental and disruptive product and/or process innovations (Baker et al., 2022). “Pro-innovation” firms have higher inclination to better information exchange internally and externally, as well as using knowledge regarding products or markets. For instance, if the firm culture supports information sharing regarding product development and customization with key suppliers, timeliness and quality in the delivery of mass customized products is nurtured, which translates into improved FP. Wang et al. (2015) shed light on the nexus of IO and MC delineating how an innovation culture cultivates MC. While we maintain that strategic orientations of firms generally have a role in materializing capabilities (see also Lii and Kuo, 2016), our contention is more in line with that of Chen et al. (2011), which rather stress on their contingent role. Innovativeness supports addressing customer requirements, but also exceeding them, in a SC context (Hult et al., 2002). This implies that IO helps firms to prioritize MC capabilities to go beyond simply meeting customer requirements, by harvesting the potential outcomes of such capability to its utmost extent. For instance, if the top management supports innovation, firms will have a higher propensity to capitalize on creative solutions by their employees in product development, and hence improving their overall competitive position (Stock et al., 2014; Chen et al., 2009).
Reflecting on prior research emphasizing on balancing the benefits and costs of developing manufacturing capabilities such as MF and MC (Olhager, 1993; Qi et al., 2020), we posit that their interaction with IO can lead to higher FP. Such cultural factors have been regarded as influential moderators in how capabilities lead to performance (Schilke et al., 2018). Drawing on ROT, we argue that IO not only magnifies the effectiveness of capabilities but also facilitates coordinating and mobilizing them (Sirmon et al., 2007). CT holds that finding the right “fit” between the strategies or practices, and contexts leads to more effective performance gains (Sousa and Voss, 2008). Effective leveraging of resources is contingent on a clear “mobilizing” vision and shared purpose in the firm for how they shall be used (Chirico et al., 2011). We maintain that the role IO plays in how MF and MC lead to FP, can be explained by the “interaction fit,” as proposed by Drazin and Van de Ven (1985). Hence, IO can be characterized as a moderating internal contingency (Prajogo et al., 2018). In this vein, we postulate that firms associated with IO, have a higher propensity to support the benefits generated by MF and MC:
IO moderates the relationships between (a) MF, (b) MC and (c) FP.
Figure 1 illustrates the conceptual model of this study that draws on the ROT and CT to suggest two mediating and two moderating relationships.
4. Methods and results
4.1 Data collection
Data was collected using a cross-section survey on manufacturing firms in Sweden (NACE codes 10 to 31). This sample frame is believed to represent firms with fair understanding and implementation of the research constructs tested in this study, therefore, suitable for our analysis (Pashaei and Olhager, 2019). To extract a list of 9,000 manufacturers in Sweden, the BvD Amadeus database was used. Then, a random sample frame of 714 manufacturers were contacted via telephone to determine their interest in participation. Data collection was undertaken professionally by a market research firm with extensive experience in similar survey research in the Swedish language. When required, follow-up calls were made to engage with the relevant informant executive. A total of 242 useable responses were returned primarily filled in by knowledgeable executives within logistics and SCM, purchasing, operations and production (33.8% actual response rate), followed by CEO’s and owners (29.7% and 17.7%, respectively). To assess the nonresponse bias in the survey, we conducted “the extrapolation technique,” which is commonly used in SCM research (Clottey and Grawe, 2014) to test whether the nonrespondents differ from respondents in a way that would impact the results of the study. This technique assumes that late respondents are more similar to nonrespondents (Armstrong and Overton, 1977). In this regard, t-tests were carried out to compare the early (94) and late responses (148), by comparing the variances in ten randomly selected variables from the survey. As no significant differences were found between the two groups, nonresponse bias did not appear to be a concern. Table 1 summarizes the characteristics of the respondent firms, including the industry classification (Eurostat, 2008), and technology intensity. Since almost half of the respondents are either CEO’s or owner of the firms, the risk for key informant bias is minimized. Moreover, the majority of the sample consists of small and medium enterprises (SMEs), according to their reported annual turnover and number of employees (European Commission, E, 2020), which is in line with the profile of the Swedish manufacturing sector (Statistics Sweden, 2022). Furthermore, none of the firms participating in the study were publicly quoted.
4.2 Measurement instrument
The survey was designed using established and valid scales (seven-point Likert) and was then translated into Swedish by an SCM researcher. Since this study was part of a university-industry collaboration project, it provided access to six large industrial manufacturers to carry out a pilot study for refining the questionnaire. SI was measured using Chen and Paulraj (2004). MC was adopted from Huang et al. (2008) and IO from Chen et al. (2009). Various operationalization of flexibility has been used in the literature, which mainly either focus on internal competencies and/or wider SC capabilities (D'Souza and Williams, 2000; Sáenz et al., 2018; Jafari et al., 2022b). For instance, Chaudhuri et al. (2018) use two single items for capturing volume and mix flexibility. For measuring MF, and acknowledging the lack of consensus in operationalization of MF (Pérez-Pérez et al., 2018), we adopted Zhang et al. (2003)’s conceptualization since it captures various dimensions of volume and mix flexibility.
To capture FP, items related to overall product quality, competitive position and customer service levels were adopted from Wisner (2003). These items have proven to rank high among the relevant reflective items of FP (Tan et al., 1998) and have been widely used in the literature (Jafari et al., 2022a; Hüseyinoğlu et al., 2020). Overall customer service levels primarily indicates the relative productivity of the firm’s logistics operations in on-time and accurate delivery, and service provision (Murfield et al., 2017; Mentzer et al., 2001). Overall product quality, as an operational performance, measures the relative level of meeting the specifications, and conformance to standards in manufactured products (Gu et al., 2017). Overall competitive position represents competitiveness in the marketplace, and can be associated with market share and performance (Wisner, 2003; Tracey et al., 2005; Chahal et al., 2020; Zhang et al., 2019). We used number of employees, annual sales, total assets and technological intensity (Eurostat, 2008) as control variables, in line with prior research indicating their relevance for SC and manufacturing capabilities and performance (Wang and Sarkis, 2017).
4.3 Data analysis
4.3.1 Confirmatory factor analysis
To assess model fit, we conducted a confirmatory factor analysis (CFA) in AMOS 27. The measurement model fit was acceptable as χ2/df = 1.96, comparative fit index (CFI) = 0.912, Tucker–Lewis Index (TLI) = 0.900, incremental fit index (IFI) = 0.913, root mean square error of approximation (RMSEA) = 0.061 since all measures met the recommended thresholds (Hair et al., 2018). The factor loadings for all constructs were close to 0.7 (Table 2).
In addition, we adopted different procedures to assess the convergent validity of the results, as reported in Table 3. The values for average variance extracted (AVE) was greater than 0.50 cutoff for all constructs (with the exception of FP, which scored a close 0.47). As for internal consistency, the composite reliability (CR) values ranged from 0.72 to 0.85, which is considered a satisfactory level (Hair et al., 2018). Altogether, convergent validity was established. Also, discriminant validity was supported since the square roots of the AVE’s for the constructs were larger than the respective correlation coefficients, as suggested by Fornell and Larcker (1981).
4.3.2 Common method bias assessment
To assess the potential problems in relation to common method bias, we conducted two methods of procedural and statistical analysis. First, following Podsakoff et al. (2003), in designing the questionnaire and after the pilot study, we took measures to reduce social desirability and ambiguity. We also assured the respondents about anonymity and voluntary participation. Furthermore, we employed “proximal separation” between independent, mediating and dependent variables to reduce the risk of common method bias (Chavez et al., 2021; Krause et al., 2018).
Second, we adopted Harman’s one-factor statistical test. The exploratory factor analysis results confirmed that five factors had eigenvalues exceeding 1 following the conceptual model. The percentage of variance that corresponded to all five factors was 62.56%, whereas as the highest loading factor accounted for only 31.3% of variance. In addition, we conducted CFA by connecting all items of all constructs into a single factor. The model fit result was poor: χ2 = 1,120.70, df = 166, χ2/df = 6.751, CFI = 0.437, TLI = 0.356, IFI = 0.445, RMSEA = 0.154. Also, we carried out a further test by adding a common latent factor to the constructs of the research model. The CFA model fit was slightly changed (ΔCFI = 0.006, ΔTLI and ΔIFI = 0.007). The marginal difference indicates that common method bias is not a concern in our data (Chavez et al., 2021). Based on the results of both procedural and statistical analysis, we confirmed that common method bias was not an issue in our research data.
4.4 Results
We used structural equation modeling (SEM) to test our hypotheses in AMOS 27, and the overall fit was acceptable (χ2 = 314.995, df = 297,83 χ2/df = 1.850, CFI = 0.916, TLI = 0.902, IFI = 0.918, RMSEA = 0.059). We tested the mediation paths by using a boot strapping approach, including 5,000 bootstrapped samples and 95% confidence intervals (Wang and Sarkis, 2017). The findings show that the path from SI to MF (PC = 0.387, p < 0.01) and MC (PC = 0.326, p < 0.01) is positive and significant. Also, the paths from MF to FP (PC = 0.190, p < 0.05) and from MC to FP are both positive and significant (PC = 0.179, p < 0.05). The indirect effect of SI on FP through the mediation roles of MF (PC = 0.071, p < 0.05) and MC (PC = 0.060, p < 0.05) were significant. The relevant p-values and path coefficients indicate that the indirect effects from SI to FP through MF and MC are significant, while the direct effect from SI to FP is not significant. Thus, the relationship between SI and FP is fully mediated by MC and FP. Accordingly, the findings support the two mediation hypotheses of H1 and H2 (Table 4). The mediation test results reveal that the effect of SI on FP is channeled through the internal capabilities of MF and MC. Hence, to improve FP, manufacturing firms cannot solely rely on increasing integrative activities with their key upstream suppliers (SI), but they should also consider increasing their internal capabilities (MF and MC). Furthermore, to test the moderating effects of IO, we considered the interaction of IO with MF and MC, respectively. Interestingly, the results show that the interaction effect of MF and IO is negatively significant (PC = –0.161, p < 0.05); hence, H3a is not supported. Therefore, IO negatively moderates the relationship between MF and FP. On the other hand, considering that the standardized beta coefficient is significant and positive (PC = 0.146, p < 0.05), H3b is supported (Table 5). Hence, IO positively moderates the path from MC to FP.
5. Discussion
5.1 Theoretical implications
Our theoretical contributions are multifold. First, by taking an ROT perspective, we delineate how leveraging bundled resources, and capabilities could lead to competitive advantage (Sirmon et al., 2011). In this regard, we conceptualized and empirically tested the specific capability configurations of SI with MF and MC for competitive advantage. Theoretically, we have contributed to the literature by proposing a unique configuration of three types of capabilities of internal production related capabilities, supplier facing capability, the strategic orientation of firm toward embracing innovation, and how firms could develop competitive advantage by orchestrating such configuration. The empirical support for the full mediation effects show that the positive impact of SI on FP is only realized if manufacturing firms also have internal manufacturing capabilities such as MF and MC. This finding provides new insights to the literature because the prior work, such as Swink et al. (2007) with apparently contradictory findings, may have suffered from a narrow theoretical conceptualization. The ROT perspective has brought the focus on how the strategic resources can be configured into a complementary combination of capabilities. For instance, integrating inbound and outbound flows of goods with suppliers, allows firms to improve their capability to adapt production volumes, range and variety, which, in turn, could contribute to superior competitive position or customer service levels. In fact, bundling and synchronizing interorganizational capabilities allow firms to create value for customers by problem-solving or need satisfaction (Sirmon et al., 2007; Zacharia et al., 2011).
Second, at a broader scale, we contribute to the extant literature on integration in contemporary SC’s. Specifically, we highlight the strategic importance of integrative practices with suppliers in achieving superior performance (Droge et al., 2004). We engage in the overall debate in the SCM literature regarding the positive and negative performance impacts of integration (Prajogo and Olhager, 2012). Our findings indicate a mediated relationship between SI and FP, which is in line with a noticeable body of literature (Amoako-Gyampah et al., 2020). Our results further underline the significant role SI plays in enhancing internal and customer-facing capabilities of MF and MC. Also, SI may involve facilities in distribution, transportation or warehousing (Chen and Paulraj, 2004). From an ROT point of view, pooling or establishing a portfolio of such resources with key suppliers could be crucial in explaining how they lead to competitive advantage (Malik et al., 2021). In fact, suppliers have a critical role in bundling and leveraging resources, and, in turn, how firms implement their strategies to gain sustainable competitive advantage (Hitt, 2011). In line with prior research (Prajogo and Olhager, 2012), we further stress that seamless integration with suppliers and acting as a unified entity in logistics processes or resources, equips firms to have higher MF and improve their MC capability; both key contributors to FP (Olhager, 1993).
Third, we reflect upon the notable, yet relatively under-researched, role the strategic orientation of firms plays in realizing and capitalizing on capabilities in the SCM literature (Baker et al., 2022). We use CT to explain how IO can moderate the way MF and MC translate into FP. Interestingly, our results indicate the dual and contrasting impact of IO, accordingly. On the one hand, we found that the effect of MC on FP is contingent on the IO of firms. This implies that fostering a supportive culture for innovative ideas, strengthens the ability of manufacturing firms in realizing the benefits expected from MC initiatives. We argue that this may be due to the natural complementarity between IO and MC. Since firms with higher IO have a better inclination in succeeding in developing and implementing new ideas, products, processes or systems (Hurley and Hult, 1998), presumably, they can expect superior success in capitalizing on MC. For instance, firms with higher IO may be more inclined to applying digital technologies and tools – including those within the Industry 4.0 framework – which support MC. The developments in digital technologies, and the resulting transformation, are believed to further contribute to the “paradigm shift” in MC (Kim and Lee, 2022). The ample literature suggests that digital tools are extremely valuable in connecting with customers, particularly with involving them in the processes, offering further variety and increasing the sense of belonging and attachment, and hence increasing satisfaction (Jafari et al., 2015).
On the other hand, contrary to our initial expectation, IO negatively moderates the MF–FP relationship. Therefore, it appears that higher IO is counterproductive in firms prioritizing MF. In other words, cultivating a culture which is overly receptive to new ideas (Hurley and Hult, 1998; Chen et al., 2009), apparently could incur higher complexity. Meanwhile, there is consensus in the literature that simplicity and discipline are key to flexibility (Fogliatto et al., 2012), which may juxtapose the notion of IO, especially in its extreme. From a different angle, IO is highly associated with the market orientation of firms (Grinstein, 2008). Following the lines of Salvador et al. (2020), we argue that new ideas must be aligned with the solution designed to serve customers, especially given that any flexible system has a threshold beyond which its performance deteriorates. Based on this, we posit that under circumstances of high IO, MF begins to lose its effectiveness and efficiency. For instance, since IO may involve seeking new resource development and deployment (Hurley and Hult, 1998), it may impair the performance of flexible systems in the way that the alignment with market requirements would diminish (e.g. due to higher costs, lower quality or longer lead-times). This could be further supported in accordance with the findings of Simpson et al. (2006), who underline the possible negative role of IO in relation to product failures, job stress or increased costs. From a different perspective, our moderated model may imply that manufacturers operate separate organizational units focusing on flexible production operations, and innovation/R&D, which may increase operational and coordination costs (Yu et al., 2020). Therefore, based on the CT, we maintain that firms should find a fit between their strategic orientation and capabilities to achieve competitive advantage (see also Aslam et al., 2020; Baker et al., 2022). This contributes by highlighting the contexts in which best practices in SCM research can be expected (Sousa and Voss, 2008). Specifically, we further engage in the call to elaborate on the contingent factors in flexibility research (Ketokivi, 2006). Moreover, we draw attention to addressing the interplay of the strengths and weaknesses of capabilities in achieving competitive advantage (Sirmon et al., 2010).
5.2 Managerial implications
The above theoretical contributions also have strong managerial implications. Most importantly, we draw the attention of managers on how to bundle firm capabilities into complementary configurations to create a sustained competitive advantage and to consider the contingencies of the relevant organizational factors (Hughes et al., 2019). Manufacturing firms pursue different strategies to remain profitable and competitive. Some capitalize on integrating processes with suppliers through establishing shared understanding and investment in both physical and cyber systems, which is regarded as a desirable attribute for cost reduction, quality improvement and new product development. On the other hand, some invest heavily in manufacturing systems that are capable to respond quickly and efficiently to market dynamism, including variations in volume and mix of products, but also increasing customer demand for MC. While both are essential, the literature highlights the isolated operationalization of such efforts as the result of asynchronistic nature of manufacturing and procurement functional roles (Wiengarten et al., 2019; Won Lee et al., 2007). We emphasize that the investment in developing both internal and supplier facing capabilities (SI) should not be absorbed independently; rather, an orchestrated effort across functional areas is required to maximize the expected outcomes. Recognizing the link between SI and internal manufacturing capabilities could also overcome “silo mentality,” a well-known issue within manufacturing environments. With the emergence of SCM, firms are recognizing the value of streamlining and aligning upstream logistics processes with their internal production activities to develop competitive advantage. We stress the harmonizing role of SC managers to convene and leverage SI to manufacturing capabilities and the consequential performance outcomes.
Furthermore, we investigated how the relationship between internal manufacturing capabilities and FP is contingent upon the existence of innovation culture and supporting environment. Promoting innovative thinking and creativity has become a key practice within manufacturing ecosystems. Specifically, IO is known as an indicator of firm behavior toward the development of innovation-enabling competencies related to resource allocation, technology, employees, operations and markets (Siguaw et al., 2006). In resource-constrained environments, IO is known as a desirable organizational attribute that promotes creativity, leading to new forms of resource mobilization and solutions. Relevant to the context of this research, IO could act as an effective catalyzer for the transformation of internal manufacturing capabilities into FP. For example, innovative manufacturers may identify new methods to minimize machine setup and down times when accommodating for a different volume and mix of products demanded by customers, which could be a source of reduced labor and machine-related expenses. Similarly, to address the operational challenges of MC, creative manufacturing workforce could observe and seize opportunities in minimizing the required efforts by identifying the right configurations between product design, manufacturing processes and systems functionalities. From a managerial perspective, however, management support accompanied with appropriate incentive and risk sharing mechanisms are prerequisites to create such innovation-enabled culture.
Previous studies have highlighted that innovation could act as a “double-edge sword”. Manufacturing environments are known for their deadline-oriented and process-intense attributes. Therefore, to create a change culture in an industry where productivity gains were traditionally defined through standardization, innovation must be defined through a synchronized people-process-technology approach.
Finally, with the development of modern technologies, especially those within the framework of Industry 4.0, MC can be achieved by involving other downstream SC actors, including the consumers (e.g. via 3D printing or artificial intelligence). For instance, machine learning could have high potential for tackling the major challenges in MC, namely, production planning and scheduling. As such, sophisticated demand forecasting and marker estimation techniques could be applied to plan even without knowing future customer requirements (Kim and Lee, 2022). Moreover, our study could have implications for managers in making a strategic choice between MF or MC capabilities in achieving competitive advantage, especially, if they are considering fostering an innovative culture within their firm. This could be notably beneficial for SMEs, which have relatively limited resources to invest, as opposed to their larger counterparts. Therefore, given the complexity in contemporary global SC’s, such indications could be valuable in practice to tackle “causal ambiguity” and formulate decisions (Sirmon and Hitt, 2009).
6. Concluding remarks
In this research, we used ROT to explain the mediating effects of MF and MC on the SI–FP relationship. As we found support for full mediation in both cases, we contend that to effectively leverage integrative activities with upstream suppliers, manufacturers may consider capitalizing on MF or MC capabilities. Hence, our study addresses the mixed results from prior research regarding the performance outcomes of SI. Furthermore, we applied CT to shed light on the contingent effects of IO on the MF–FP and MC–FP relationships. Our findings reveal that while IO positively moderates the latter relationship, it appears to negatively impact the former. Therefore, we contribute to the literature on the role of strategic orientations of firms in configuring and leveraging capabilities (Aslam et al., 2020; Baker et al., 2022). The results of our study provide insightful implications for decision-makers regarding prioritizing capabilities and fostering an innovative culture in their organizations.
Despite this, we believe there are still promising directions for future research which were not covered within the scope of this study. First, our conceptualization only considered integrative capabilities with upstream SC actors. Future studies could consider other dimensions of SC integration (i.e. customer or internal) to investigate whether the findings remain true regarding orchestrating these capabilities with MF and MC. Second, we acknowledge the importance of the trade-offs in optimizing manufacturing capabilities and strategizing. For instance, customer value is intrinsically influential in whether or not standardization or MC should be considered (Shao, 2020). In this regard, we encourage complementary studies to explore the discrepancies related to the mis-fit of MF and/or MC considering the product type or other determining factors. Third, future studies could consider other mediating capabilities (e.g. responsiveness and agility) or their synergetic effects, in the SI-FP relationship. This could be of interest given the recent technological developments in contemporary manufacturing. As digital technologies evolve, the resulting transformation would be an attractive research area in manufacturing capabilities, especially in relation to enablers such as human-robot interaction, virtual reality and machine learning (Kim and Lee, 2022; Suzić et al., 2018). Fourth, other dimensions of FP (e.g. financial performance) can be incorporated into the conceptual model to provide a different picture of competitive advantage. Fifth, future studies could consider more specificity in the type of innovation performance (e.g. incremental/disruptive, product/process) could further delineate the role of other strategic orientations of firms and to capture their complementarity effects. According to Chavez et al. (2021), the strategic orientations of a firm can lead to superior synergetic effects on realizing competitive advantage. For instance, the role of SC orientation as a facilitating mechanism to support resource orchestration can be an interesting arena for investigation. On a different note, the possible negative role of strategic orientations is worthy of further exploration. Based on our findings and the work of Simpson et al. (2006), firms should not always expect positive outcomes from IO. Also, while we used firm as our unit of analysis, the role of SC managers for resource orchestration comes with research value in future. Moreover, we acknowledge the importance and relevance of digital technologies in supporting and enabling innovative SC and manufacturing capabilities. Hence, we suggest future studies explore the symbiosis interplay between digital orientation and IO within manufacturing organizations. Furthermore, such digital advancements along with the blurring of boundaries among SC actors, could provide opportunities for downstream players, such as retailers, to consider flexibility and MC (Jafari et al., 2022a). Moreover, there exists great potential in exploring the leveraging aspect of MF and MC capabilities in specific sectors within the manufacturing industry via in-depth qualitative case studies. Also, the lack of consensus in operationalizing manufacturing capabilities, underscores the potential for purifying or further developing the measures (Pérez-Pérez et al., 2018; Liu et al., 2021). Finally, our research did not include external contingent factors. Given the current developments resulting from the pandemic, we encourage future studies to investigate the moderating effects of turbulence, disruption and complexity along SC’s.
Figures
Sample characteristics
| Characteristic | Frequency | (%) |
|---|---|---|
| Technology intensity | ||
| Low technology | 82 | 33.9 |
| Low-med Technology | 99 | 40.9 |
| Med-high Technology | 49 | 20.2 |
| High technology | 12 | 5.0 |
| Industry classification | ||
| 25. Manufacture of fabricated metal products, except machinery and equipment | 72 | 29.8 |
| 28. Manufacture of machinery and equipment | 27 | 11.2 |
| 16. Manufacture of wood and of products of wood and cork, except furniture | 20 | 8.3 |
| 10. Manufacture of food products | 17 | 7.0 |
| 22. Manufacture of rubber and plastic products | 17 | 7.0 |
| 32. Other manufacturing | 15 | 6.2 |
| 26. Manufacture of computer, electronic and optical products | 12 | 5.0 |
| 31. Manufacture of furniture | 11 | 4.5 |
| 27. Manufacture of electrical equipment | 10 | 4.1 |
| 23. Manufacture of other nonmetallic mineral products | 7 | 2.9 |
| 13. Manufacture of textiles | 7 | 2.9 |
| Others | 27 | 11.2 |
| No. of employees | ||
| 0–10 | 165 | 68.2 |
| 11–50 | 65 | 26.9 |
| 51–250 | 12 | 5.1 |
| Size | ||
| Large | 12 | 5.0 |
| Medium | 9 | 3.7 |
| Small and micro | 221 | 91.3 |
| Position | ||
| Logistics, SC, operations and production manager | 77 | 31.8 |
| CEO | 72 | 29.7 |
| Owner | 43 | 17.7 |
| Marketing manager | 28 | 11.5 |
| CFO | 12 | 4.9 |
| Others | 20 | 8.2 |
Constructs, items and loadings
| Constructs and items | Standardized loadings |
|---|---|
| Supply integration (SI) | |
| Our interorganizational logistics activities are closely coordinated with our suppliers | 0.73 |
| We have a seamless integration of logistics activities with our “key” suppliers | 0.83 |
| Our logistics integration is characterized by excellent distribution, transportation and/or warehousing “facilities” | 0.75 |
| Our inbound and outbound distribution of goods is well-integrated with our suppliers | 0.74 |
| We have a smooth flow of information and materials with our suppliers | 0.60 |
| Mass customization (MC) | |
| We are highly capable of large-scale product customization | 0.72 |
| We can easily add significant product variety without increasing cost | 0.61 |
| We are able to add product variety without sacrificing quality | 0.74 |
| We are highly capable of responding quickly to customization requirements | 0.78 |
| Innovation orientation (IO) | |
| We emphasize the need for innovation for development | 0.71 |
| We promote the need for development and utilization of new resources | 0.77 |
| We embrace, accept and measure innovation | 0.73 |
| Management actively seeks innovative ideas | 0.76 |
| Our teams and employees are encouraged for new ideas even if they are risky or do not work | 0.60 |
| Manufacturing flexibility (MF) | |
| We are able to operate efficiently at different levels of output | 0.67 |
| We can quickly change the quantities for our products produced | 0.76 |
| We are able to build different products in the same plant(s) at the same time | 0.72 |
| Firm performance (FP) | |
| Overall product quality | 0.72 |
| Overall competitive position | 0.62 |
| Overall customer service levels | 0.70 |
Reliability and validity tests
| Share | Mean | SD | Cronbach’s alpha | CR | AVE | LI | EF | CU | IO | FP |
|---|---|---|---|---|---|---|---|---|---|---|
| LI | 4.68 | 1.19 | 0.85 | 0.852 | 0.538 | 0.733 | ||||
| MF | 5.50 | 1.11 | 0.70 | 0.760 | 0.514 | 0.320** | 0.717 | |||
| CU | 5.66 | 1.16 | 0.79 | 0.806 | 0.512 | 0.29** | 0.644** | 0.715 | ||
| IO | 4.85 | 1.27 | 0.83 | 0.839 | 0.513 | 0.285** | 0.194* | 0.197* | 0.716 | |
| FP | 5.35 | 0.85 | 0.62 | 0.720 | 0.462 | 0.218** | 0.303** | 0.319** | 0.147 | 0.68 |
*P < 0.05, **P < 0.01; square root of AVE’s in italic
Mediation results
| Hypothesis | Indirect effect | Direct effect | |||||
|---|---|---|---|---|---|---|---|
| Effect | S.E. | 95% CIs | Effect | S.E. | 95% CIs | Findings | |
| H1: SI → MF → FP | 0.071* | 0.049 | [−0.006,0.205] | 0.090 | 0.105 | [−0.061,0.376] | Full mediation |
| H2: SI → MC → FP | 0.060* | 0.041 | [0.005,0.195] | 0.090 | 0.105 | [−0.061,0.376] | Full mediation |
*p < 0.05, **p < 0.01
Moderation results
| Path main effect | Path estimate | S.E. | 95% CI lower | 95% CI upper |
|---|---|---|---|---|
| Main effect | ||||
| SI → EF | 0.394** | 0.070 | 0.172 | 0.517 |
| SI → CU | 0.338** | 0.079 | 0.170 | 0.529 |
| SI → FP | 0.095 | 0.062 | 0.031 | 0.330 |
| MF → FP | 0.120 | 0.077 | −0.102 | 0.352 |
| MC → FP | 0.203** | 0.063 | 0.014 | 0.381 |
| IO → FP | 0.052 | 0.043 | −0.055 | 0.148 |
| Interaction | ||||
| MF × IO → FP | −0.161* | 0.064 | −0.127 | 0.186 |
| MC × IO → FP | 0.146* | 0.097 | 0.032 | 0.294 |
| Control | ||||
| Size | −0.106 | 0.004 | −0.011 | 0.002 |
| Annual sales | 0.203 | 0.018 | 0.002 | 0.068 |
| Total assets | −0.055 | 0.087 | 0.002 | 0.143 |
| Low-med tech | 0.087 | 0.120 | −0.104 | 0.454 |
| Med-high tech | 0.119 | 0.151 | −0.019 | 0.582 |
| High tech | 0.052 | 0.249 | −0.226 | 0.709 |
*p < 0.05, **p < 0.01
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Acknowledgements
The data collection in this research was done as part of the KOPtimera project funded by the Swedish Knowledge Foundation. More support during the write-up was provided by the Wallanders & Tom Hedelius Stiftelse and Tore Browaldhs Stiftelse. The authors would like to thank Fredrik Tiedemann, as well as the participating firms in the study.