A TOPSIS analysis of regional competitiveness at European level

1. Introduction

The level of development of the various regions of the European Union (EU) is highly uneven, with some capital regions experiencing significant levels of growth and peripheral ones struggling to improve. In this connection, the measurement of regional competitiveness is becoming essential for policymakers, since it is one of the major levers for economic progress (Moirangthem and Nag, 2022). Researchers have underlined the need to further investigate the competitiveness of regions, taking account of the fact that country indices fail to cast light on subnational trends and performance gaps across nations (Dagilienė et al., 2020; Huggins et al., 2013). Various approaches have been adopted to measure regional competitiveness. The construction of composite indices, with the combination of several independent dimensions examining a specific facet of the regional economy, is the predominant approach adopted (Annoni et al., 2016; Bristow, 2010; Moirangthem and Nag, 2022).

It is frequently argued that the dimensions of regional competitiveness are not independent (Cheng et al., 2018; Dagilienė et al., 2020). In fact, macroeconomic dimensions are tightly intertwined, and scholars underline how correlations need to be taken into account to provide an accurate measurement of regional development (Huovari et al., 2002; Pontarollo and Serpieri, 2021; Reyes and Useche, 2019). For instance, Franco et al. (2014) in their European Commission report, argue that competitiveness indicators such as productivity, employment growth or labour force participation are closely correlated with each other. Similarly, Cheng et al. (2018), Wenzel and Wolf (2016) and Wang and Wang (2014), in their analysis of macroeconomic indicators, show that they exhibit high correlation coefficients, with many above 0.95.

Therefore, the literature evidences how the aspect of correlation is in line with cumulative causation theory, according to which economic growth (even regional) is the result of a multi-causal approach where changes in any macroeconomic dimension will affect subsequent changes in other dimensions in a sort of self-reinforcing cumulative circle (Lehtonen and Tykkyläinen, 2018; Skott and Auerbach, 1995). As a result, to measure regional competitiveness accurately, the aspect of correlation should be taken into account, as overlooking it can lead to biased results.

Composite indices do not deal with correlations, thus causing factors to be overestimated or underestimated when ranking alternatives, leading to misleading measurements (Pérez-Moreno et al., 2016; Wang and Wang, 2014). In this connection, Multiple Criteria Decision-Making (MCDM) methods can be considered as valuable alternative techniques in the measurement of regional competitiveness, as they can rank alternatives easily and assist policymakers in designing policy interventions (Bilbao-Terol et al., 2019).

The Technique for Order of Preference by Similarity to Ideal Solution (TOPSIS) (Hwang and Yoon, 1981) is one of the most widely used MCDM methods in many fields such as human resource management, water management or supply chain management due to its ability to help decision-makers to solve real-life problems and to rank alternatives (Behzadian et al., 2012). The basic idea underlying TOPSIS is to rank alternatives on the basis of the ratio of the distance from a positive ideal solution to the distance from a negative ideal solution.

TOPSIS is an ideal MCDM method for the measurement of regional competitiveness, because it can deal with the aspect of correlation, thus providing a more accurate measurement of competitiveness, aligning it to the underlying cumulative causation theory. At the same time, it can use weights that are obtained objectively from macroeconomic variables, such as gross domestic product (GDP), in the same way as classical composite indicators, while other methods such as Decision Making Trial and Evaluation Laboratory (DEMATEL) or Analytic Network Process (ANP) are less effective in this regard. However, the application of TOPSIS in this field has been largely overlooked and only a few studies are to be found in the literature. Moreover, existing contributions usually consider only the aspect of rankings (Qian et al., 2019), and overlook the aspect of the clusters of competitiveness. In this extent, clusters refer to groups of regions with similar structural characteristics, and similar levels of competitiveness. Considering the aspect of clusters of regions is important because they provide much more information about territorial disparities, rather than simply looking at rankings, as proposed by a number of scholars (Annoni and Dijkstra, 2019; Beltran et al., 2024).

Therefore, these issues lead to the following questions:

• Q1.

  Is TOPSIS a valuable method for measuring regional competitiveness?

• Q2.

  Is it important to consider correlations when measuring regional competitiveness?

• Q3.

  Is it important to consider not only the aspect of rankings, but also the clusters of competitiveness when measuring the level of competitiveness of regions?

To address these questions, the present study applies TOPSIS to the regions of the EU Regional Competitiveness Index (RCI) 2019, taken as the frame of reference. The RCI is the main composite index of regional competitiveness at the EU level; it measures regional competitiveness of 268 territories at NUTS 2 regional level (Nomenclature of Units for Territorial Statistics) considering 74 indicators, grouped into 11 independent pillars. Various researchers have used it as a fundamental frame of reference for the analysis of regional development (Bilbao-Terol et al., 2019; Bocci et al., 2022; Borsekova et al., 2021b). Consequently, the present study takes the RCI as the frame of reference as it overlooks the issue of correlation, and it clusters regions on the basis of their level of competitiveness. Thus, it is a good basis to address these research questions.

In this study, we apply three different distance measures, namely, the Manhattan, Euclidean and Mahalanobis distance measures. The use of different distance measures on a large number of regions provides a broad application of TOPSIS to cast light on which of the distance measures should be used for the measurement of regional competitiveness, since they have different properties (Chang et al., 2010). Moreover, as two levels of analysis are considered, one based on rankings and the other based on clusters of competitiveness, this study facilitates a comprehensive measurement as rankings are highly sensitive to the distance measure used, while clusters are less so. In fact, regions can easily change their position in rankings, as the variation of even one dimension or calculation method is sufficient to cause a region to shift from its initial position to another one (Ivanová and Čepel, 2018; Pérez-Moreno et al., 2016; Scaccabarozzi et al., 2024). However, the analysis of clusters of competitiveness is more robust, as regions have more room for moving around within the cluster without changing their ranking in terms of competitiveness defined by the cluster itself (Annoni and Dijkstra, 2019; Beltran et al., 2024).

This study aims to contribute to the measurement of regional competitiveness in three different ways. Firstly, as the RCI is replicated by means of TOPSIS with a less preferred choice of distance measure, this study aims to provide a benchmark for future research into both regional competitiveness and TOPSIS applications as TOPSIS is indicated as a valid alternative method for the measurement of regional competitiveness. Secondly, the TOPSIS ranking based on the Mahalanobis distance measure provides the most robust results with respect to the other two distance measures, as it presents the lowest fluctuation in the closeness coefficient when robustness checks are applied. Hence, the study argues in favour of the Mahalanobis distance measure as the best distance measure to be applied in the measurement of regional competitiveness, underscoring the need to consider the aspect of correlations. Thirdly, the study highlights the need to consider the aspect of clusters of regions in competitiveness measurement as it provides a broader picture of regional competitiveness levels. Unlike previous studies, TOPSIS is applied to 268 European regions, demonstrating the ability of TOPSIS to rank a large number of regions.

This paper proceeds as follows. Section 2 provides a literature review on regional competitiveness in the EU and approaches to its measurement. Section 3 provides an outline of the methodology, whereas Section 4 summarizes the results of the analysis, focusing on rankings (Subsection 4.1) and clusters (Subsection 4.2). Section 5 consists of concluding remarks, policy suggestions and comments on the limitations of the study.

2. Literature review

Defining territorial competitiveness is problematic, controversial and far from being comprehensively understood. It is a matter of common observation that the socio-economic regional development is still heterogeneous and uneven in Europe (e.g. Borsekova et al., 2021b). Since the economic crisis of 2008, Europe has adopted a wide range of policy actions to improve the economic development of the European Member States. Nevertheless, not all regions have the same resilience, hence, disparities in regional development and competitiveness persist (Annoni and Dijkstra, 2019; Dagilienė et al., 2020; Moirangthem and Nag, 2022; Pontarollo and Serpieri, 2020). Möbius and Althammer (2020), in their spatial econometric analysis of sustainable competitiveness of European regions, found that northern EU regions tend to perform better on sustainable competitiveness than southern regions, while other scholars such as Borsekova et al. (2021b) argue that in Europe regional disparities persist, particularly because post-socialist regions are less developed with respect to the liberal market economy/central regions. Some strong liberal market economy regions perform particularly well on all indicators due to their economic links with the rest of Europe, while many mid-ranking competitive regions do not benefit from the same advantages. Several peripheral regions struggle to take advantage of spill-over effects due to their geographical location and structural weaknesses (Annoni and Dijkstra, 2019). In this framework, the measurement of regional competitiveness is becoming essential to promote policy actions for addressing regional disparities.

One of the most common approaches to the measurement of regional competitiveness consists of the construction of a composite index, with the combination of several indicators examining a specific facet of the regional economy. At country level, many studies are available. For instance, Huggins et al. (2021) have constructed an index for measuring the competitiveness level of UK regions, while Bronisz et al. (2008) have designed a composite index for measuring the competitiveness of Polish regions.

Nevertheless, these kinds of indices often overlook the issue of correlation, with the risk of underestimating or overestimating factors. In this connection, cumulative causation theory states that economic growth follows a self-reinforcing process, in which regional dimensions are reinforced by other dimensions. Positive (or negative) changes of one dimension will affect changes in other dimensions as a result of localized effects of returns (Lehtonen and Tykkyläinen, 2018; Martin, 2016; Skott and Auerbach, 1995). Therefore, “regional development is subject to cumulative causation, since subregions that have a high value for one sub-index also tend to have high values for other sub-indices” (Huovari et al., 2002, p. 11). Consequently, high performing regions can benefit from virtuous circles of economic growth, while low performing regions can find themselves in a vicious circle of underdevelopment (Tervo, 2005). As highlighted above, the aspect of correlation is critical in the measurement of regional competitiveness since macroeconomic dimensions tend to reinforce each other (Pike et al., 2016).

Along this veing, MCDM methods are a valuable alternative in the measurement of regional competitiveness as they can assist policymakers in sorting and ranking alternatives to make faster and easier decisions (Fernandez et al., 2013). Among the several MCDM methods in the literature, such as DEMATEL, Elimination and Choice Expressing Reality (ELECTRE) or ANP, which have been mainly adopted for the solution of real-life problems (i.e. environmental management or supply chain management) (Mardani et al., 2015), TOPSIS proved to be an appropriate method for determining the ranking of European territories when considering macroeconomic indicators (Ardelli, 2019). In particular, Balcerzak and Pietrzak (2016) applied TOPSIS to measure the sustainable development of 24 European countries, resulting in a ranking that shows that northern countries tend to be the leaders in sustainable development. Similarly, Dinçer (2011) measured the European Union Member States on five macroeconomic criteria by means of TOPSIS, whereas Ture et al. (2019) assessed the Euro 2020 Strategy of 27 EU Member States with TOPSIS. Moreover, another advantage of TOPSIS with respect to other MCDM methods is that it can easily take into account the issue of correlation, providing a more accurate measurement of regional development. In addition, with TOPSIS it is possible to use the same weighting scheme used by composite indices, facilitating the comparison of the results.

Therefore, this study aims to measure the competitiveness level of European regions by taking as a frame of reference the RCI 2019. The RCI is the main periodic study of regional competitiveness in Europe, providing a comparable and multifaceted overview of the level of competitiveness of 268 territories at NUTS 2 regional level. The framework consists of 11 pillars covering various aspects of competitiveness (i.e. macroeconomic stability, labour market efficiency and technological readiness) grouped into three nested macrodimensions: the basic dimension, the efficiency dimension and the innovation dimension. The structure of the RCI is depicted in Figure 1. The index is computed as a weighted average, with the weights related to the different stages of the development of regions (see Annoni and Kozovska, 2010 for the full methodology). A number of scholars have adopted the RCI as the basis of their analysis of regional competitiveness: Bocci et al. (2022) used the data of the RCI to analyse the main drivers of regional competitiveness using a Regression Tree analysis, whereas Borsekova et al. (2021b) used the RCI to measure regional socio-economic cohesion in Europe. However, none of these studies applied TOPSIS for the analysis of regional competitiveness.

The present study seeks to contribute to the scholarly discussion by offering a valid reference point for future research on regional competitiveness through the application of MCDM methods.

3. Data and methods

The data for this study comes from the 11 pillars depicted in Figure 1 for the 268 European regions and of the RCI (2019), retrieved from the website of the European Union (European Union, 2019). This website provides the final aggregated data of the 11 pillars, derived from a set of 84 indicators spanning the period 2015–2017, selected by the European Union in line with the literature and using national, subnational (i.e. World Bank, Eurostat) or regional statistics. For instance, for the institution pillar, indicators such as the corruption or political stability index were selected, whereas macroeconomic stability is based on statistics such as national savings or private-sector debt. Infrastructure consists of data such as the percentage of the population with access to rail services or the number of passengers per flight; health includes the number of road fatalities and the infant mortality rate. Basic education and higher education comprise the percentage of the population with access to information on education or the percentage of the regional population with access to university education. Labour market efficiency and market size pillars comprise indicators such as the percentage of individuals aged 15–64 in employment, and net disposable household income. Finally, the technological readiness, business sophistication and innovation pillars include indicators such as the percentage of households with access to internet, the number of organizations implementing organizational innovation and the number of scientific publications per million inhabitants.

The indicators belonging to each pillar were then standardized and finally aggregated as an arithmetic mean. Each of the indicators represents a dimension (pillar) used in the TOPSIS analysis, which was already available as aggregated outcome [1].

TOPSIS consists of five different steps (Kuo, 2017), which are outlined below. The first step involves the standardization of the data. Standardized z-scores of the 11 pillars that compose the index were used (see Figure 1), which were already available on the website. This initial data had undergone an aggregation and validation process by the European Union [i.e. sensitivity analysis, skewness analysis, principal component analysis and reverse coding to obtain the same positive impact on the final score, see Annoni and Kozovska (2010) for further details].

The second step involves weighting the 11 pillars. For the sake of comparison [2], the weighting scheme of the RCI was used (see Annoni and Dijkstra, 2019), which depends on regional GDP levels. This makes it possible to obtain a weighted normalized decision matrix V_ij, i = 1, …, 268 and j = 1, …, 11 with the input of the following steps.

The third step determines the positive ideal solution A⁺ and the negative ideal solution A⁻ as A+=(v1+,v2+,…,vn+) where vj+=max(vij), j=1,2,…,n, i=1, 2, …, m, and A−=(v1−,v2−,…,vn−) where vj−=min(vij), j=1,2,…,n, i=1, 2, …, m. The positive ideal solution A⁺ is a hypothetical region that has the best score for each criterion, whereas the negative ideal solution A⁻ is a hypothetical region that has the worst score for each criterion.

The fourth step involves the computation for each region of the distance from the positive and negative ideal solution. To this end, the Manhattan, Euclidean and Mahalanobis distance measures are used to calculate the distance from the positive ideal solution ( si+ ) and the distance from the negative ideal solution ( si− ) for each region a_i. The superscripts m, e and p are used for the Manhattan, Euclidean and Mahalanobis distance measures, respectively.

For the Manhattan distance measure, we have:

It should be noted that both the Euclidean and Manhattan distance measure consider pillars as independent from each other, thus overlooking the aspect of inherent closeness among them. The Mahalanobis distance measure, instead, can control for inherent closeness, as it considers the inverse of the covariance matrix, which accounts for the covariances of the pillars considered, thereby their correlations coefficients.

Table 1 shows the first significant finding, as the pillars of the RCI are positively and significantly correlated among each other. For instance, looking at the institution pillar, it may be seen that it is highly correlated not only within pillars of its own sub-dimension (r = 0.5, p ≤ 0.01 on average), but also with pillars of other sub-dimensions such as technological readiness (r = 0.929, p ≤ 0.01) or innovation (r = 0.676, p ≤ 0.01). This is an important finding as it confirms that the determinants of regional competitiveness are interrelated, thus marked by cumulative causation (Pike et al., 2016). Based on this finding, and considering the interdependent nature of the pillars, the Mahalanobis distance measure may be expected to be the most appropriate among the three used as it can account for the inherent closeness between pillars by considering their correlation.

The fifth step involves the computation of the relative closeness coefficients that constitute the final scores of the regions to obtain the final ranking. For each region a_i, the relative closeness coefficient Ci* is computed as follows:

Finally, to compare the rankings obtained, two permutation metrics are used: the Kendall tau and the Spearman footrule. To facilitate the interpretation, the normalized Kendall tau K* and the normalized Spearman footrule F* (Beg Sufyan and Ahmad, 2003) are applied:

If σ^r and σ^p are identical, then the value is 0, whereas if σ^r and σ^p are in the converse order, then the value is 1. The results of the rankings are examined in Section 4.1.

As a last step, to compare the results with the RCI, the clusters of competitiveness are analysed, and the results are shown in Section 4.2.

4. Discussion and findings

5. Concluding remarks, limitations and future research

Various authors have argued in favour of further investigating the measurement of regional competitiveness, as regions are major levers for the development of a country. In this regard, researchers suggest considering the issue of correlation since competitiveness dimensions are usually interrelated (Pontarollo and Serpieri, 2021). In this sense, cumulative causation theory underlines how economic growth is driven by interrelated factors as changes in one macroeconomic dimension affect changes in others (Lehtonen and Tykkyläinen, 2018). Some scholars indicate MCDM methods as a valuable alternative to composite indices in this regard, which can also deal with the aspect of correlation. By addressing three different research questions, this study recalculates the RCI 2019 by means of TOPSIS based on the Manhattan, Euclidean and Mahalanobis distance measures, and considers in the analysis rankings and cluster of competitiveness, taking the RCI as a frame of reference.

The findings are important in two respects. The first point to consider is that regarding the method used, the application of TOPSIS was extended to regional competitiveness at the European level, which has attracted limited attention so far, arguing in favour of TOPSIS as a valuable alternative method in the assessment of regional competitiveness with respect to the others in the literature (Borsekova et al., 2021a; Bronisz et al., 2008). In particular, as the RCI can be obtained as a result of a TOPSIS application with a less preferred choice of distance measure (Manhattan), constitutes a strong point in favour of TOPSIS in the analysis of regional competitiveness, as the study provides the same results as the European Union with a different calculation method. In addition, consistent with cumulative causation theory, the findings highlight the importance of considering correlation, as neglecting them can distort the analysis, which is a common issue in composite indicators (Wang and Wang, 2014). In fact, as the Mahalanobis distance measure deals with this aspect, this constitutes an additional point in favour of the application of TOPSIS by policymakers for the purposes of regional analysis. In particular, the Mahanalobis ranking was found to be the most robust among the three rankings obtained, as it shows the lowest fluctuation in the closeness coefficient, even when robustness checks are applied. This finding emphasizes the importance of considering correlation in the measurement of regional competitiveness, as it accounts for the interdependencies across the various dimensions. Hence, this result enriches the theoretical discussion about cumulative causation and the importance of self-reinforcing cumulative circles of macro-economic dimensions, with a significant impact on the measurement of regional development.

At the same time, the result contributes to policymaking discussions, as considering or failing to consider the aspect of correlation can lead to different results and decisions. There is good reason for policymakers to use TOPSIS with the Mahalanobis distance measure when analysing the competitiveness level of regions, as it is a valid alternative for dealing with certain critical aspects in the use of composite indices, providing a more accurate measurement of regional development (Arcagni et al., 2021; Bristow, 2010).

The second point to consider is that the comparison between the rankings and between the cluster of competitiveness obtained casts light on the persistent differences and disparities in regional development within the European Union (Borsekova et al., 2021b; Dagilienė et al., 2020; Moirangthem and Nag, 2022). In particular, the results provide further evidence of a small number of leading regions that can be considered as the economic backbone of European prosperity, while others present persistent weaknesses. This finding aligns with and confirms prior findings that highlight how the process of regional development is still far from being fully accomplished (Beltran et al., 2024; Borsekova et al., 2021b). At the same time, the findings should be an alert for public institutions dealing with regional development, because, while some leading regions are always placed in the most performing cluster, others some less competitive are consistently placed into the lowest performing cluster, regardless the distance measure used. As a result, as argued in the literature (Pinheiro et al., 2022), this pattern can create problems regarding the effective implementation of regional development policies because less developed regions benefit less than more developed ones and the persistent difference in regional development can give rise to geographical inequality loops. The findings of this study emphasize the importance of considering clusters in the analysis of regional development, to obtain a more comprehensive measurement and richer insights.

The present analysis considers cross-section data, which provide only a snapshot of the regional competitive situation in Europe. However, when investigating regional competitiveness or territorial disparities, most researchers rely on time-series data (Bartkowska and Riedl, 2012; Bosker, 2009). As a result, as a further step of this analysis, it would be useful to replicate it at different points in time, by examining the RCI from 2010 to 2019 to investigate how the rankings of regions and the composition of clusters change over time.