Productivity development enablers in the infrastructure sector: capability maturity model integration approach

2.1 Infrastructure sector and productivity: a general perspective

The infrastructure sector is a complex system consisting of physical infrastructures and involved actors creating, managing and maintaining them. Physical infrastructure systems are, for example, transport networks and urban areas, water supply and sewage, energy and communication networks and environmental properties and resources (Lee et al., 2015). Activities in different infrastructure lifecycle phases, such as construction, design and maintenance, are closely associated with each other, as well as other operations like permitting procedure and control of use (Padgett and Vishnu, 2020; Javed et al., 2018). Additionally, infrastructure boundaries are somewhat indistinct because built environment elements and systems interact intensively with each other (Padgett and Vishnu, 2020). For example, the same energy network might serve and be a part of both a traffic light system and a building at its region of operation. At the same time, a part of a certain infrastructure system can involve several other systems. For example, a road section can involve different traffic user groups, a pavement, drainage, lighting, road markings and signs. Furthermore, an actor might own or operate several different systems and physical asset types. It is hard to define the infrastructure sector comprehensively. It can be understood as a constellation of functions that strive to provide a built environment and enable physical facilities for society, including the social organization of people in these functions.

Productivity as a concept is ambiguous, and it is applied in multiple meanings. Productivity is generally defined as the ratio between outputs and inputs. This paper approaches productivity as a rationality which aims to achieve optimal actions or results (cf. the concepts of “performance”; “effectiveness”; “efficiency”; cf. Lebas and Euske, 2007; cf. Forbes and Ahmed, 2011, 1 and 23). One might also consider the connection of “productivity” to the literature and concept of “public value” (Moore, 1995) in the context of the infrastructure sector when infrastructures are understood as societal services.

Productivity might differ for different parties in the same situation. Different actors have different perspectives of what the output should be. Furthermore, there are differences regarding the value creation logics of various sector actors: public organizations, as clients, seek value for money from a taxpayer perspective, while private actors seek profitability for shareholders. In addition, there are differences and conflicts among different private actors’ productivity views when they collaborate in the same project. However, there are common value systems between these actors, such as “efficiency”, i.e. using minimum means to achieve certain ends (van der Wal et al., 2008; Johanson and Vakkuri, 2017). This idea is the focus and glue of this paper: enhancing productivity (cf. “efficiency”; cf. “performance”) of any actor improves the potential productivity of the whole, but only when this partial optimization is consistent with serving the end users and customers of the infrastructure sector.

Productivity can be examined on multiple levels in infrastructure sector (cf. Ofori et al., 2021; Rosen et al., 2019; Munir et al., 2020; Lee et al., 2015; Javed et al., 2018). System level productivity reflects the inputs and processes needed to ensure the operability of the targeted system, such as a traffic network, an energy system, or in more detailed scale road drainage (Rosen et al., 2019). Furthermore, the system level should also consider the existence of sub-systems (Munir et al., 2020). Many studies (see Ofori et al., 2021) focus on construction productivity from the perspective of project or activity. On the other hand, sector level is traditionally seen as a stakeholder to developing construction productivity. In addition to construction, activities to maintain the desired service level of the infrastructure system are governance, information management, network planning, maintenance optimization, demand control and other (Javed et al., 2018), i.e. elements of asset management. Construction is often considered to position on the project and organizational levels, whereas sector level productivity should take into consideration the value that the physical infrastructure and sector’s operations bring to society as a whole (Lee et al., 2015). In this paper, infrastructure sector productivity means the efforts to create and maintain the built environment for the needs of the end users.

2.2 CMMI as an approach to achieve productivity development

This paper approaches productivity development as a continuous endeavor for improvement, where capability building and maturity evaluation are seen as central concepts. Furthermore, the infrastructure sector productivity improvement requires holistic total optimization for infrastructure to serve its users appropriately. In other words, development processes should be examined as a systemic and multilayered entity that recognizes linkages between individuals, projects, organizations and infrastructure systems. In this vein, this paper seeks the maturity development needs for capabilities of implementing the productivity improvement measures that previous research like Ofori et al. (2021) or Munir et al. (2020) has identified.

Continuous improvement of productivity requires capability for development processes. Wendler (2012) describes capability as “the power or ability in general … to fulfill specified tasks and goals”. Ariffin and Ahmad (2021) suggest that capability building is “a process by either individuals or organizations to strengthen and maintain the ability to achieve organizational objectives over time”. In this study the examined organization is infrastructure sector, and the objective is to improve productivity development capabilities.

Key contributors for perceiving potential paths to improved capability for development processes are conceptualizing the maturity levels and identifying the current state and deficiencies (CMMI Product Team, 2010). Related to capabilities, the concept of maturity refers to perfection or completeness of the capability development processes (Wendler, 2012; Facchini et al., 2020). Furthermore, maturity levels define the different stages and compile the elements of capabilities to continuous improvement (Siviy et al., 2007; CMMI Product Team, 2010). Identifying the current stage of maturities is generally called maturity assessment.

Maturity assessment is commonly applied in organizational contexts (Siviy et al., 2007, Stoiber et al., 2023; Poeppelbuss et al., 2011), but it can also be exploited in interorganizational systems and at a sector level (Frick et al., 2013; Seidel-Sterznik et al., 2018; Srai et al., 2013). Motives for deploying sector level maturity assessment include identifying areas of improvements, research results sharing, administration and future strategies facilitation, data management streamlining, knowledge sharing and communication improvements, identifying potential practical applications, inter-company benchmarking and checking the progress (Seidel-Sterzik et al., 2018; Srai et al., 2013). Sector level applications have been developed for, for example, assessing performance of smart city, Life Cycle Management and low-carbon city practices (Wei et al., 2019; Seidel-Sterzik et al., 2018; Shen et al., 2021). A sector level maturity assessment should be simple enough to attract the target audience and produce valid assessment results, but not too simple to overlook vital aspects (Frick et al., 2013).

Maturity models offer a framework for maturity assessment. Maturity models are management tools that can be used especially for assessing strengths and weaknesses of capabilities, derive prioritization and roadmaps for improvements and evaluating and supporting the development of capabilities and processes (Stoiber et al., 2023; Santos et al., 2021; Wendler, 2012; Poeppelbuss, 2011; de Bruin et al., 2005). This paper adapts the CMMI to examine and identify the enablers of improving productivity. The concept of CMMI was originally released for process improvement in 2000 and was developed based on capability maturity models (CMMs) for software and systems engineering and integrated product development (CMMI Product Team, 2010). Today, the concept is widely known and adapted, for example in systems engineering, integrated teams, project management, risk management and acquisition domains (Siviy et al., 2007; Ariffin and Ahmad, 2021; Wendler, 2012). CMMI contains maturity levels and KPAs that serve in identifying the current state, and in some applications, differences between the process areas. The KPAs are different aspects for assessing maturity, and together they form the combination of the process development entity (Siviy et al., 2007). The evolution, structure and different applications of capability maturity models are introduced in several publications (see for example Siviy et al., 2007; Ariffin and Ahmad, 2021; CMMI Product Team, 2010). Exploiting CMMI in specific field of interest requires professional judgment and interpretation of the context (CMMI Product Team, 2010; Wendler, 2012).

3.1 Analytical process

The scope of this study was to develop a CMMI framework to support the productivity development in the infrastructure sector. Thereby, the aim was to answer the research question – What kind of a capability maturity model can help in identifying the enablers of productivity development in the infrastructure sector in Finland? – by providing a new perspective to understanding the productivity development capabilities through maturity levels and KPAs.

The study was structured in 3 steps presented in Figure 2. First, a general framework of the maturity model for productivity development was constructed based on research literature. Second, the model was fitted into infrastructure sector by utilizing interview data. Third, the model was validated and refined with an expert panel. Through these steps the research ended up with a deployable model (cf. Figure 1 phases 1–4).

3.2 Developing the theoretical framework

Maturity models consist of two common components: (1) a set of levels or stages defining maturities and (2) measured objects (Wendler, 2012). In this paper, the first component is called maturity levels and the second is called KPAs.

CMMI maturity levels create a picture at one end of the unevolved state, and at the other end, the ideal state (Siviy et al., 2007; CMMI Product Team, 2010). In other words, the maturity levels define how deeply implemented the development processes are and how advanced the capabilities to continuous improvement are (Siviy et al., 2007; Ariffin and Ahmad, 2021). In this paper, the general maturity levels were developed through examining and applying previous research literature concerning CMMI applications and reflecting them through an infrastructure sector productivity development capability approach.

The KPAs’ were approached as the focal capabilities of development. Since improving productivity requires change, understanding change management is essential. In this paper, the CMMI concept was adapted by treating the “change management elements” as KPAs. Change is, however, anything but simple. For example, organizational changes have fairly high failure rates, with over half failing (Errida and Lotfi, 2021). Nevertheless, there are several models for change management that aim to reduce the risk of failure. One solution is to examine the elements that make the change successful. If one or more elements are lacking, change will likely fail. In addition, maturity models should acknowledge areas that combine to form the basis for achieving the set goals (Siviy et al., 2007).

3.3 Generating the attributes and maturity criteria based on interview data

Since exploiting CMMI convincingly requires professional judgment and interpretation of the context (CMMI Product Team, 2010), the levels are described from the infrastructure sector productivity viewpoint, based on the infrastructure sector representatives’ interview data. The maturities of the KPAs can be assessed based on the maturity level descriptions.

The research data was collected through 12 semi-structured face-to-face group interviews (Table 1). The interviews were organized by directly contacting some of the largest organizations in the Finnish infrastructure sector. Interviewees were either the persons contacted or selected by the organizations themselves. Altogether the interviews involved 45 interviewees from different positions, organizations and operations in the Finnish infrastructure sector. The interviews were a part of larger research aiming to form a roadmap to more productive infrastructure sector in Finland and to identify the opportunities and present state of digitalization within the sector and, in this vein, avenues for future research. Thus, the interviews' original purpose is similar to the purpose of this study and adapt the same change management elements as themes that this paper utilizes as KPAs. For this paper, the research data was analyzed from the aspect of enabling productivity improvement in the infrastructure sector. The interview questions are presented in Appendix. As semi-structured interviews, the data consists of richer discussion and broader perspectives than the interview outline presents.

Infrastructure sector specific attributes and preliminary maturity criteria for KPAs‘ were formed through an interview data content analysis. The interview data analysis consisted of seven steps:

1. Notion composing: identifying enablers and hindrances from the littered interview data

2. Initial coding: naming basic categories for all notions (enabler/hindrance, interview number, KPAs of change management)

3. Complementary coding: identifying arising enabler subject areas and naming them + coding the notions along with the complementary categories

4. Review and revision of the coding structure: assessing the suitability of the coding structure against credibility, applicability and explanatory power of the results

5. Forming the final coding structure: grouping enabler categories and notions by main themes into 2–3 preliminary attributes per KPA

6. Arranging the notions inside each attribute according to general maturity level features

7. Forming the preliminary criteria for attribute maturity levels

3.4 Validating the model through an expert panel

An expert panel was executed to validate and get insight into comprehensibility, suitability and applicability of the constructed model. The members of the panel were selected from experts that have a strong multidisciplinary experience and approach regarding to infrastructure sector.

The panel consisted of 5 experts representing different aspects and operations of the sector:

1. Expert A: Municipality traffic designer with versatile experience from consultancy, team management and different planning levels as well as integration of different technical fields. 20 years of working experience in the infrastructure sector.

2. Expert B: Leading consultant in infrastructure digitalization consulting company with over 30 years of extensive experience in cities’ land use planning processes, technological solutions development and managerial roles.

3. Expert C: Leading expert in Urban Environment Division of a city. Over 10 years of wide municipal and consultancy experience from project leadership of large projects, team lead and development, asset management and traffic planning.

4. Expert D: Head of Permits in a national agency with over 10 years of deep experience of operational, tactical and strategic work in permitting processes, logistics and collaboration networks.

5. Expert E: Development Manager of services in company offering site management solutions. Nearly 30 years of extensive experience from construction and maintenance works.

The success of a model is determined in accordance with comprehensibility, suitability and applicability of the model in the deployment scope viewpoint (de Bruin et al., 2005; Frick et al., 2013; Stoiber et al., 2023). The expert panel validated the model through two questions:

1. Is the criteria of attribute maturities comprehensible and suitable? How should it be refined?

2. On which prerequisites would the presented model be applicable in the Finnish infrastructure sector?

4.1 Theoretical framework for the model

In this paper, productivity development is approached as a continuous pursuit for improvement. Continuous improvement is considered as a systematic development process instead of discrete development projects or programs. Therefore, the existence and operability of development processes is seen as a key to examining the current situation and improvement capabilities. On the other hand, infrastructure sector level productivity improvement requires total optimization. Decisions regarding the application of a CMMI model adapted from De Bruin et al. (2005) are as follows:

1. Audience: Internal infrastructure sector audience of executives and management. Use case is to identify and put into practice how the sector’s productivity can be developed through identifying and improving productivity development capabilities.

2. Method of application: self-assessment or third party assisted. Application means could be for example a barometer for sector representatives or action research executed by researchers.

3. Internal driver of application and requirements: More efficient usage of budget, profitable business, more fluent workflow to ease the burden of loaded workers.

4. External driver of application and requirements: Securing the infrastructure system that serves the citizen and industrial life sustainably with a proper service level.

5. Application method: Infrastructure sector as one entity, possibly sub-system-specific sub-entities.

The characteristics for productivity development capability maturities are (applied from Thomas and Saleeshya, 2021, Facchini et al., 2020; Santos, 2021; Wei et al., 2019, Donellan et al., 2011):

1. Initial: Productivity development and KPA activities are partially performed, unpredictable, cannot be managed or controlled, difficult to withstand times of stress. Only a few processes are well defined and the success of the projects depends on individual initiative. Infrastructure sector workers have poor understanding of the productivity development concept.

2. Defining: There is a limited productivity development strategy with associated execution plans. Productivity development largely reactive and lacks consistency. There’s an increasing awareness of the subject, but accountability isn’t clearly established. Some policies might exist but are adopted inconsistently. The main productivity development processes are generally well planned, defined, to control their cost, time and functions. Process results are reproducible.

3. Adopting: Properly documented, standardized and tailor-made productivity development processes, tools and standards. Capabilities and skills are developed to contribute to productivity development. Productivity development operations are managed by common procedures and standards.

4. Integrated and adaptive: Productivity development is a core component of the infrastructure sector activities and fully integrated into processes. Detailed information regarding productivity bottle necks is systematically collected and analyzed for each process. Abilities and awareness of need for solving conflicts based on situational awareness and productivity targets. Activities are aligned to meet internal and external needs.

5. Dynamic and agile: Systemic and strategic integration of productivity development, in which continuous process improvement is a natural part of the work and creates a platform for innovations. Situational awareness is systematically generated and strategy implementation is aimed efficiently to practical work gripping points. The workers are constantly actively learning and deploying new productivity development knowledge and skills.

The characteristics of the levels are adopted from the CMMI model, and it describes the maturity of the development processes.

4.2 Input of the attributes and maturity criteria: focal enablers of productivity improvement

While literature provided the KPAs, the KPA attributes and their maturity criteria were derived from interviews to provide professional judgment and interpretation of the context. Each KPA gained 2 or 3 attributes. Altogether 18 attributes were formed. They reflect the interview discussions on challenges and development needs, which provide the enablers of productivity improvement. In the following, each KPA’s attributes, and their maturity characteristics, are presented.

4.3 Validation outcomes of the expert panel

The iProDe-CMMI-model was validated through an expert panel, which considered the model comprehensible, well-structured and applicable to infrastructure sector. Yet, Expert E argued that “the model is quite abstract and requires examples of practical applications to support the understanding on how one can advantage it in one’s own work”. Some participants felt that the content is very extensive. One participant suggested breaking the model down to comprehensible entities and another considered whether the content should be simplified.

In addition to sector level deployment, the panel found potential and interest in exploiting it in organizational assessment. The panel saw high importance in raising discussion in the sector upon the iProDe-CMMI KPA attributes and criteria to enable productivity development. The experts agreed that the model supports the linkage between strategic and operative level.

Dialogue between high-level strategies and details of the practical work is certainly needed. Further, understanding of core processes, tasks and required skills in different fields, levels and phases is essential. Solving bottle necks of practical work should be aligned with broader strategies. Infrastructure projects contain several different perspectives and phases, that might be contradictory. Awareness of these contradictions makes it possible to achieve a successful outcome. On the other hand, sometimes it is critical to accomplish the work fast and all the optimal information might not be on hand quick enough. These kinds of acute situations would benefit from pre-organized support and steering structures. The ability of identifying uncertainties, asking the right questions, and assessing the situation might be even more important than the abilities of solving certain technical matters. (Expert A)

The model provides some targets that challenge current business logics, which is certainly valuable and induces discourse. (Expert B)

All of the expert panel participants indicated, that the KPA criteria illustrate the infrastructure sector well and is comprehensible. The expert panel offered also a few detailed ideas for refining the criteria related to highlighting the understanding of lifecycle piercing information needs, knowledge transfer structures compensating the challenges of organizational changes, contract’s spirit in project management, feedback from projects to procurement development, processes ensuring proper preparation before processing, need of silo-specific terminology in addition to the common terminology and money and time investments needed for productivity development actions.

4.4 iProDe-CMMI-model for examining the infrastructure sector’s capabilities for productivity development and discussion

Table 2 presents the final refined infrastructure productivity development (iProDe) CMMI-model. The final model integrates the literature framing on CMMI model and change management, while utilizing the professional judgment and interpretation of the context from interviews and considerations of the expert panel.

The general phases of developing a CMMI-model are presented in Figure 1. According to them, adapting and advantaging the iProDe-CMMI-model requires demonstrating the model and defining the administration mechanisms, deployment of the model and maintenance of the model. Demonstration and deployment of the model are suggested to be carried out by:

1. Analyzing the current maturity levels of all KPA attributes.

2. Identifying the attributes and KPAs with lowest maturity.

3. Mapping the enablers of productivity development that are activities needed to (1) improve the maturity of the attributes with lowest maturity, (2) embrace the attributes that inspire the overall productivity development and, (3) prevent the attributes from falling on lower maturity level.

4. Enforcing the identified enablers of productivity development.

5. Repeating the steps 1–4 with an appropriate cycle.

This paper answers the research question: “What kind of a capability maturity model can help in identifying the enablers of productivity development in the infrastructure sector in Finland?” Previous development work related to infrastructure sector productivity has focused on limited targets and they are often executed from the perspective of an organization’s top management, which has formed an incoherent and mind-bending view to the practical work focusing on projects (e.g. Aziz et al., 2017; Götz et al., 2020; Lee et al., 2015; Munir et al., 2020). Instead, the model introduced in this paper offers a perspective of productivity development capabilities, infrastructure system and lifecycle. The model challenges current business logics by suggesting that reaching a more mature level on productivity development capabilities requires an open alignment of the internal and external incentives (cf. goal incongruence in Johanson and Vakkuri, 2017) and a strong integration of education and development into practical work.

The study shows that the CMMI offers an adaptable framework for examining the capabilities as the enablers of productivity development in the infrastructure sector. This is supported by Srai et al. (2013), who indicate that CMMI has been utilized in interorganizational context successfully before and here this appliance is continued through infrastructure sector perspective. The enablers arisen from the interview data bring important topics to discuss to enable the productivity development. The suggested attributes and maturity level criteria form a basis for further examination of the sector’s current situation and development targets. Yet, the enablers, attributes and maturity level criteria should be considered as a starting point and future studies should contain an assessment of improvement needs of the model. In conclusion, this paper adopts the CMMI approach and presents a novel iProDe-CMMI-model for examining and improving productivity development capabilities in the infrastructure sector.