The relationship between traditional project management, agile project management and teamwork quality on project success

2.1 Team work quality

TWQ is the level of interactions and motivations among project team members (PTMs; Hoegl and Gemuenden, 2001; Lindsjørn et al., 2016). Hoegl and Gemuenden (2001) identified aspects of TWQ to include:

(Communication, i.e., the open discussion and sharing of information; coordination, i.e. coordinating tasks between team members; balance of member contributions, i.e. utilizing team members’ knowledge; mutual support, i.e., team members supporting each other; effort, i.e. expending effort on given tasks; and cohesion, i.e. promoting team unity and consistency), holding the quality of task-related and social interaction within teams.

The definition of TWQ can be classified into aspects of interaction (communication, coordination and mutual support) and motivation (effort, balance of member contribution and cohesion). This research focuses on the interaction aspect of TWQ (collaboration, communication, trust and team environment) among PTMs as key factors contributing to project performance (Diallo and Thuillier, 2005; Chiocchio et al., 2011; Petrén, 2012). Handy (1995) found that the ability to work collaboratively is a core competency of TWQ. Communication is the ability to discuss openly and effectively inform and share information and knowledge, with other team members, without hiding critical information (Dietrich et al., 2010). Communication is the core of TWQ and critical for team collaboration. The ability to communicate directly and freely with PTMs without a mediator (i.e. coordinator or team leader) is vital in a multiple project management setting as the multiple project manager leads multiple teams; therefore, communication among team members is vital to avoid delays in processing tasks (Al-Shatti, 2018). Trust improves cooperation and collaboration processes, which contribute to an improved capacity to manage the interdependencies of tasks among PTMs. For example, collaboration enables agile teams to communicate quickly and respond rapidly to changes as they emerge. A favourable team environment creates a climate of trust where project members can freely express ideas without the fear of making mistakes. Creating such a work environment is critical to TWQ and can lead to generation of innovative ideas, which in turn influence project performance. Table 1 shows the differences between the TWQ constructs used in the current study in TPM and APM.

2.2 Traditional project management

TPM emphasizes disciplined planning and control methods and brings formality into project management (Kerzner, 2013; Salameh, 2014; Conforto and Amaral, 2016). Kerzner (2013) gives three major benefits for the plan-driven approaches: providing structure to project management, providing possible standardization in planning, scheduling and control (i.e. forms, checklists and guidelines) and allowing for a structured decision-making process. The traditional plan-driven approach is most effective in projects with stable and well-known requirements. On the other hand, the approach typically faces challenges in projects with high level of uncertainty (Bianchi et al., 2018).

2.3 Agile project management

The agile framework has four core values: individuals and interactions over processes and tools, working software over comprehensive documentation, customer collaboration over contract negotiation, responding to change over following a plan. Aguanno (2004) suggests that the core values of manifesto can be applied to APM. Unlike the TPM, which try to predict and minimize change and uncertainty, APM is seeking to adapt to uncertainty and accommodate changes even in later phases of a project (Cooke-Davies, 2002). APM relies heavily on the collaboration and communication between the project team and the customer or customer representative to create the right product in a lean fashion (Aguanno, 2004; Collyer et al., 2010; Sliger, 2011). APM is considered most effective in projects with a high level of uncertainty, such as new design, problem-solving and not-done-before work. This sort of high uncertainty work has a high rate of change, complexity and risk. Agile approaches explore feasibility in short cycles and quickly adapt based on evaluation and feedback (Bianchi et al., 2018; Highsmith, 2004). The use of agile methods promotes a working environment that supports creativity and productivity, enables rapid adaptation to change and brings value for the customer, based on better identification of needs and priorities and faster multiple delivery of functionalities (Leffingwell, 2007).

2.4 Hybrid project management, team work quality and project success

Hybrid project management is combining the plan-driven approach of TPM and the flexibility of APM to achieve PS. A good project management methodology delivers a successful project and includes better control of project scope, faster delivery, quality management process and better customer satisfaction supported by effective information exchange among key stakeholders (Kerzner, 2013). PS is a multi-dimensional construct that can be defined into two key components: short-term project management success (efficiency) and the long-term goals of the project (effectiveness) (Serrador and Turner, 2015). This study focuses on project effectiveness dimension of PS. Sommer et al. (2015) found out that the combination of agile and traditional stage-gate approach generates a healthy tension between fixed planning and iterative problem-solving that can lead to PS in product development projects. The challenge is to balance the two approaches to leverage their strengths in a given situation while compensating for their weaknesses (Boehm and Turner, 2003; Aguanno, 2004; Carlsen and Pitsis, 2020). Both agile and TPM practices have situation-dependent shortcomings that, if not addressed, can lead to project failure. APM is a combination of TPM concepts and flexible lightweight, collaborative, adaptable to frequent change, yet highly discipline practice (Salameh, 2014). Because of constant changes and frequent modifications, APM requires improved project, communication, monitoring, coordination and trust among team members to ensure the project falls within the business need and vision of the company (Haas, 2007).

TWQ becomes essential to ensure dialogue, communication and collaboration in an environment of frequent changes. The climate for trust can reduce the stress and conflicts associated with changes in adopting an agile way of working. Coram and Bohner (2005) found that an APM method requires upfront planning to ensure that project requirements are met for the first release. This shows that one methodology is not enough, and both agile and TPM can use the different elements of project management methodology to capture the various aspects of both project and organizational environment to ensure PS. For example, the potential benefits of APM, which is interactive in nature, may be reduced because of insufficient coordination among team members to set boundaries and highlight effective issues (Serrador and Turner, 2015). On the other hand, the use of TPM use can prevent organizations that are continually seeking innovation from squandering resources on redundant ideas (Miller and Friesen, 1982). Consequently, dynamic tension motivates constant dialogue and debate concerning strategic issues and encourages shared communication and coordination (Henri, 2006; Sommer et al., 2015). Batra et al. (2010) found out that APM without structure/coordination can lead to chaos in large complex distributed project. On the other hand, structure without agility creates rigidity in projects that require a great deal of learning, discovery and changes (Stare, 2014). There are many ways to set up an agile–TPM hybrid model. Depending on the project type and organization, the model can be either more agile or TPM-focused. For example, only a limited part of the project could be done in a single sprint and the rest of the project completed according to the stage gate model (Bianchi et al., 2018). Organizations using a traditional plan-driven approach may improve their new product development performance by incrementally transitioning towards a more agile way of working by improving TWQ, informal communication and trust among PTMs (Cooke-Davies, 2002).

The literature presented above shows the role of team quality in both TPM and agile methods can influence PS. When team members collaborate with each other, it creates the opportunity for knowledge sharing, dialogue and exchange of ideas that can lead to innovative skills that in turn can influence PS. The hybrid approach offers the additional benefits of managing high uncertainty through incremental product versions, quick learning cycles and frequent customer involvement (Cooper and Sommer, 2016). Therefore, this paper aims to explore the different combinations of TWQ on the simultaneous use of traditional and APM on PS. This is consistent with contingency research that suggests that different project management methodologies and processes combine to affect PS (Hanisch and Wald, 2012). To do so, this study will identify different profiles of PTMs using TPM and APM and examine differences among TWQ and its impact on PS. With our results, the study aims to contribute to a better cluster of PTMs who are using both TPM and APM.

3.1 Sampling characteristics

The company is a Finnish company and a global leader in energy business and provides EPC (engineering, procurement and construction) and life cycle support services for their customers in three business areas (marine, energy business and services), and has over 19,000 employees. The company delivers three types of projects in the energy business: customer delivery projects, operational development projects and product and solutions development projects. A survey was randomly sent to 1,000 PTMs in the energy business section of the company globally. A total of 209 responded, making it a response rate of 20.9%. Out of the 209 received, the total amount of eligible answers was 202, which gives a valid response rate of 20.2%. The average age of the respondents was between 31 and 40 years and they had worked in their field for over 10 years. About 55.9% of the respondents had worked over 10 years in the company, thus having most likely a good understanding of the company practices. About 54.4% of the respondents are working in projects teams or an expert role, 12.4% as project managers, 13.9% as steering group members and 19.3% in other supporting functions. Additionally, 78.7% of the respondents are working on customer delivery projects, 11.9% on products and solutions development project and 9.4% on operational development project (see Table 2).

3.2 Assessment of reliability and validity

Content validity was obtained by using measurements derived from the literature and face validity was tested and ensured during the pretesting phase (Hair et al., 2012). To establish content validity, existing measures of TPM, APM and PS was adopted and modified. In addition, the questionnaire was pre-tested. In the pre-test, inputs were received from two Senior Development Project Managers of the company and three project managers. They were asked to review the questionnaire and to comment on the language clarity of each question as well as the overall format of the instrument. Convergent validity refers to the state when items measure their intended construct. Convergent validity is done using the principal component analysis. Principal component analysis using varimax rotation method was used because the primary goal was to identify and compute composite scores for the variables of the study. Varimax rotation ensures independence among the mathematical factors, meaning that during the rotation, the axes remain orthogonal. Bartlett’s test of sphericity and Kaiser–Meyer–Olkin (KMO) measure of sampling adequacy were performed on the data to confirm the suitability of the data for factor analysis. The KMO measure of sampling adequacy is above the recommended value of 0.6, showing that the sample from which the data was collected was adequate. Barlett’s test of sphericity was significant. All the factors loading are positive and above the minimum acceptable loading of 0.30 (Hair et al., 2012). The reliability of each construct exceeds the minimum acceptable cut-off point of 0.60 (Nunnally and Bernstein, 1994; Taherdoost, 2016).

3.3 Measurement of the variables

4.1 Statistical analysis

Cluster analysis is a multivariate statistical tool for detecting groups and patterns in a data set (Hardle and Simar, 2019). Two of the most common types of cluster analysis are hierarchical and nonhierarchical clustering. In this study, the nonhierarchical clustering (k mean clustering) was used as it reduces the data dimension by finding appropriate representatives or centroids for clusters, or groups, of data points (Subasi, 2020). A k-means cluster analysis was used to identify how team work quality differs in the different combinations of TPM and APM. PTM scores on their use of TPM, APM and team work quality were standardized and used as clustering variables. To compare the cluster solutions, one-way analyses of variance (ANOVAs) with Tukey’s post hoc comparisons were conducted to compare clusters. The data were analyzed using the SPSS version 26. The k-means cluster analysis identified a three-cluster solution that provided the best theoretical fit. The identified clusters differed in team work quality and use of TPM and APM and impact on PS. The first cluster comprised 19% of the PTM (n = 38) and comprises those characterized by relatively low levels of use of TPM, APM and team quality and PS. This cluster is labelled “pure agile” due its high score on APM compared to TPM. The second cluster included 27% of the project members in the study sample (n = 55). PTM in this cluster also scored the highest in PS and had the highest use for TPM and ranked second in the use of APM and denotes “TPM leaning hybrid”. This group is labelled as “agile leaning hybrid focused”. The third and largest cluster included 54% of the managers in the study sample (n = 109). PTM in this cluster scored the highest in PS and also had the highest use for TPM and ranked second in the use of APM and denotes “TPM leaning hybrid”. Table 8 provides the mean scores of the variables in the cluster.