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Article

The Efficiency of Offshore Wind Energy Companies in the European Countries: A DEA Approach

by
Dario Maradin
*,
Bojana Olgić Draženović
and
Saša Čegar
Faculty of Economics and Business, University of Rijeka, Ivana Filipovića 4, 51000 Rijeka, Croatia
*
Author to whom correspondence should be addressed.
Energies 2023, 16(9), 3709; https://doi.org/10.3390/en16093709
Submission received: 21 March 2023 / Revised: 8 April 2023 / Accepted: 23 April 2023 / Published: 26 April 2023

Abstract

:
Considering environmental issues such as greenhouse gas emissions associated with climate change and the depletion of fossil fuels, one of the possible solutions is the use of renewable energy sources. Wind energy is one of the most competitive and resilient energy sources in the world, which can play an important role in accelerating the global transition to green energy. The purpose of this study is to evaluate the allocative efficiency of 47 offshore wind energy companies in 9 European countries using the input-oriented BCC DEA model. The basic hypothesis is that by evaluating the relative efficiency of offshore wind energy companies in European countries, it is possible to determine a correlation between the results of efficiency between the two observed periods with slight deviations. The empirical results show no significant correlation between the score of relative efficiency and the country where the offshore wind energy company is located. On the other hand, the results are consistent with the basic hypothesis of this study. From the management perspective, significant improvements in all financial variables, i.e., tangible fixed assets, cash and cash equivalents, and current assets, are required to achieve relative efficiency. The model variables refer to the economic characteristics of offshore wind energy companies, indicating that only allocative efficiency was analysed, which is in contrast to previous studies.

1. Introduction

Greenhouse gas emissions associated with climate change and the depletion of fossil fuels have become one of the greatest challenges in the world. Considering these environmental issues, one of the possible solutions is the use of renewable energy sources. Renewable energy, apart from leaving open the possibility of using fossil fuels in the future, contributes significantly to the environmental aspect of sustainability. It is noted that renewable energy sources that use indigenous resources have the potential to provide energy services with zero or near-zero emissions of air pollutants and greenhouse gases [1]. Renewable energy sources can be considered additional forms of energy alongside existing conventional (fossil) power plants and will become even more important in the future [2]. Modern or new renewable energy sources (including small hydropower plants or modern biomass plants) emphasise sustainability and environmental preservation. Although investments in modern renewables are significant, they accounted for 12.6% of total final energy consumption in 2020 [3]. Wind energy also accounts for only a small share of global energy consumption, despite its widespread deployment. Nevertheless, the global penetration of wind energy is increasing, and its installed capacity has grown exponentially, i.e., it has almost quadrupled in the last decade [4]. In addition, technological innovation and economies of scale have established wind energy as one of the most competitive and resilient energy sources in the world. Compared to other renewable energy sources, wind energy has low maintenance costs. Further, achieving net-zero emissions requires various actions across a wide range of sectors. Wind energy can be one of the cornerstones of green recovery and play an important role in accelerating the global green energy transition [5]. Currently, the total global wind energy capacity is up to 837 GW and helps the world avoid over 1.2 billion tonnes of CO2 annually, equivalent to the annual carbon emissions of South America [6]. Rapid progress in wind turbine installation is expected to continue in the future. Offshore wind energy is characterised by its sustainability and cleanliness and is one of the fastest-growing renewable energy sources in recent years [7]. It should be noted that offshore wind will be a key driver of the global energy transition towards climate change, with some industry stakeholders calling for an installed offshore wind capacity of over 1400 GW by 2050 [8]. To achieve this goal, the development of floating offshore wind will be pursued to deploy turbines in deeper waters and unlock up to 10 times more offshore wind resources than are possible with fixed-bottom turbines alone.
In the analysis of renewable energy, the focus is on the economic attributes and the evaluation of social and environmental impacts [9]. To ensure the development of the wind energy sector, it is necessary to pay attention to the management performance of wind energy companies. Therefore, the performance evaluation of different wind energy companies is crucial for the improvement of the energy sector. In this research, the measurement and assessment of offshore wind energy companies are carried out. It should be noted that the companies operate under the same conditions to evaluate their performance for business improvement. This means that all offshore wind energy companies generate electricity solely by using wind energy. This is one of the main assumptions of the Data Envelopment Analysis (DEA) method used in this study to determine relative efficiency. This nonparametric method has become one of the most widely used approaches to measuring and evaluating different power plants or energy companies. In view of the above, the basic hypothesis of this study is as follows: by evaluating the relative efficiency of offshore wind energy companies in European countries, it is possible to determine a correlation between the results of efficiency between the two observed periods with slight deviations.
This study makes the following specific contributions to previous literature:
  • Existing offshore wind energy performance studies have focused on the technical and comprehensive characteristics of offshore wind farms. With the exception of one study evaluating capital and operating cost efficiency, the model variables in this study relate to the economic characteristics of offshore wind energy companies, meaning that only allocative (cost) efficiency was analysed.
  • To the best of the authors’ knowledge, there is only one study to date that incorporates both DEA models (CCR and BCC models) in the evaluation of offshore wind energy companies. This study also applied the two basic DEA models, and in choosing a model to measure and interpret relative efficiency, the BBC model was found to be more appropriate.
  • Unlike previous research, the paper provides insight into the average number of projections or improvements that can make relatively inefficient offshore wind energy companies relatively efficient.

2. Literature Review

Many studies have been conducted to evaluate the relative efficiency of the power sector using the DEA methodology. In addition to electricity generation, the literature also includes measurements and evaluations of other electric power activities. It refers to electricity transmission [10], electricity distribution [11], and the electricity supply industry [12]. Färe, Grosskopf, and Logan [13] were the first researchers to use the DEA methodology in electricity generation and evaluated the relative efficiency of electric utilities in the state of Illinois between 1975 and 1979. Since then, many studies have provided a comprehensive review of the application of DEA models in the power industry (e.g., [14,15]).
With regard to the evaluation of the relative efficiency of offshore wind energy companies, which is the subject of this study, there has been an increasing number of relevant studies in recent years.
Using the super-efficiency DEA method and the Tobit regression model, Yi-Chia et al. [16] investigated the factors affecting the environmental performance of offshore wind energy companies based on cross-sectional data from seven locations in Taiwan in 2019. The results suggest that the performance value could be further increased by improving the factors affecting efficiency. These factors included the age of the company, the number of internal committees, the number of shareholders, the amount of research and development, ISO 45,001, government policies, the quality of personnel, and wind speed. Wpd Taiwan Energy Co. had the best environmental performance, while Copenhagen Infrastructure Partners Association had the lowest efficiency score.
Benini and Cattani [17] measure the long-run capacity of offshore wind farms and estimate the technical efficiency of 26 offshore wind farms over a 13-year period using a fully parametric model and a semiparametric Stochastic Frontier Analysis (SFA) method. This allows production factors to have a nonlinear effect on the amount of electricity generated. Next, the estimated technical efficiency is regressed against the age of the offshore wind farms, taking into account technological change in the wind energy industry, to determine the resilience of technical efficiency to ageing. As explained in the methodology section, this is necessary because technical efficiency does not support technological change in the observed Decision Making Units (DMUs). The results show that technical efficiency ranges from 83% to 98% and does not decrease with age. The results suggest that offshore wind farms can be a long-term solution for the energy transition.
Akbari, Jones, and Treloar [18] evaluate the relative efficiency of 71 offshore wind farms in 5 northwestern European countries (the United Kingdom, Germany, Denmark, the Netherlands, and Belgium) using the DEA method, a Charnes-Cooper-Rhodes model (CCR model). This is in contrast to this study, where both the CCR and the additional Banker-Charnes-Cooper model (BCC model) are applied. The number of turbines, cost, distance to the coast, and area of wind farms are chosen as inputs, while connectivity to population centres, electricity generated, and water depth are considered outputs. The results of the analysis of the DEA show the following: (I) several offshore wind farms in Germany and Denmark were highlighted as dominant in the selected sample; (II) the average CCR efficiency score of all offshore wind farms is 87%; (III) the efficiency score is not evenly distributed across countries; and (IV) the result of the statistical analysis shows that the median efficiency scores of the wind farms are not statistically different from each other and therefore the wind farms have a relatively high average efficiency score across all countries studied in this analysis. Finally, the study provides offshore wind stakeholders and policymakers with a practical and holistic performance assessment by including economic, environmental, technical, and social inputs and outputs in the analysis.
Ederer [19] analysed the relative performance of offshore wind farms in terms of costs by using the two basic DEA models (CCR and BCC models) and scale efficiency. The analysis was divided into a static model to evaluate capital cost efficiency, which refers to all one-time expenditures associated with the development and installation until the acquisition of an offshore wind farm, and a dynamic model to examine operating cost efficiency, which refers to all annualised expenditures incurred after the date of acquisition until the decommissioning of an offshore wind farm. For the assessment of capital cost efficiency (specific capital cost is considered as input and installed capacity, distance to shore, and water depth are outputs), 22 observations, i.e., 22 offshore wind farms in selected European countries, were included, and for operating cost efficiency (specific operating cost is the input and installed capacity, distance to the port of operation, energy performance, and availability are outputs), 26 observations, i.e., 7 offshore wind farms, were included. The learning-by-doing rate for capital cost efficiency shows that efficiency increases with accumulated experience. Furthermore, the Tobit regression used in the study shows increasing capital cost efficiency as a function of time and decreasing operating cost efficiency as a function of year of operation.
Additionally, in analysing the offshore wind potential on the Atlantic and Mediterranean coasts of Morocco, Daoudi et al. [20] listed 14 offshore wind farm sites and classified them based on 6 criteria to prioritise their suitability for a wind farm. The most important criterion is the wind power density calculated with the Weibull distribution function over the period of 2016–2020. Through a dynamic and static study, the application of the new approach based on the DEA method revealed favourable sites with high potential for offshore energy generation.
On the other hand, several studies on onshore wind energy can be found in the literature where relative efficiency is measured and evaluated. Of note is a study in which Maradin, Cerović, and Šegota [21], using the DEA methodology, analysed the evaluation of the relative efficiency of electricity generation of 78 onshore wind power companies in 12 selected European countries, identifying the factors that improve the efficiency of the companies. To the authors’ knowledge, this was the first study to analyse the comprehensive performance of onshore wind power companies, including their economic and technical characteristics. In addition, the paper provided insight into the modified form of the Cobb-Douglas production function (inputs of capital and fuel were used to produce outputs instead of labour and capital) in evaluating the efficiency of an onshore wind power company. Iglesias, Castellanos, and Seijas [22] evaluated only the productive efficiency of 57 onshore wind farms in Spain (Galicia region) during the period of 2001–2004 using the frontier methods of the DEA and SFA. The results show no significant changes in the annual efficiency scores for each observed wind farm. Ertek, Tunç, Kurtaraner, and Kebude [23] present a data-centric analysis of 74 commercial onshore wind turbines from leading manufacturers in the world. Among other methods, they provide benchmarking through the two DEA models to evaluate technical efficiency. Pestana Barros and Sequeira Antunes [24] evaluate the technical efficiency of 65 onshore wind farms in Portugal during the period of 2004–2008 using stochastic production econometric frontier models, considering ownership and unobserved managerial ability as factors affecting wind farm performance. Starting from the fact that the existing studies only measure the technical (productive) efficiency of onshore wind farms in one country (with the exception of the study by [21]), this research goes one step further and analyses the other approach, i.e., the allocative efficiency of offshore wind energy companies in nine European countries.
Finally, various studies can be found that address the following offshore issues: (I) a systematic literature review on the methods and theories used in decision-making for offshore wind power investment, followed by the characteristics, applicability of different methods, and discussion of representative literature during the period of 2010–2020 [7]; (II) the use of policy instruments and deployment of offshore wind power in the North Sea, viz., in Denmark, the United Kingdom, Germany, and the Netherlands between 1990 and 2020 [25]; (III) the proposed guidelines and policy implications in environmental licencing for offshore wind projects for new markets based on the research cases in the United Kingdom, Germany, Denmark, and Taiwan [26]; (IV) the analysis of the different approaches of Europe, China, and the United States to the development of the offshore wind energy industry [27]; (V) a new multi-attribute decision-making model to be applied to the location selection of offshore wind power stations [28]; (VI) the accuracy of wind speed distribution and compares offshore wind turbine performance predictions in Australia using three international reanalysis datasets: BARRA, ERA5, and MERRA-2 [29]; (VII) the development of an integrated offshore wind and wave energy system that could be one of the best solutions for the future of the ocean energy sector and the energy transition [30]. In the study of the development of the onshore wind energy market in the European Union, Germany and Spain are considered the main gross producers of electricity from wind energy in the EU. The study concludes that the cumulative installed wind power capacity will increase in most EU countries, highlighting that the highest growth will be in Croatia in 2022 [31]. Another study provides a comprehensive overview of the state of wind energy in terms of status, potential, and policy analyses and assessments, as well as recommendations for increasing the installed capacity of wind power [32]. In addition, there are studies that address climate change and its impact on the dynamic behaviour of an offshore wind turbine [33]; a review of the technical aspects of wind farm development, including the impact of offshore wind turbines and hybrid energy technologies [34]; analysing the positive and negative economic effects of renewable energy technologies [35]; or presenting the advantages and disadvantages of renewable energy sources in general without considering a single type of renewable energy [36].

3. Methodology

3.1. Data Envelopment Analysis Approach

DEA is a widely used method for calculating the relative efficiency of numerous DMUs operating under similar conditions. It is a type of nonparametric comparative performance analysis in which it is assumed that there are n DMUs to be evaluated, and not all DMUs are efficient. These DMUs convert multiple inputs to multiple outputs, so it is not possible (or we do not know) to develop a functional form, a relationship between them, but requires verification of the positive correlation between inputs and outputs. In other words, it is assumed that the increase in input influences the increase in output. DEA is based on mathematical programming and evaluates the efficiency of a DMU relative to a set of comparable DMUs. DEA forms an efficiency frontier, using efficient units as the standard for the best possible performance. DMUs that are not relatively efficient are below the efficiency frontier, and DEA then measures the amount of inefficiency (distance from the efficiency frontier) of inefficient units while making comparisons to the units with the best practices. DEA also provides a way for inefficient DMUs to reach an efficiency frontier based on projections, such as potential changes in inputs or outputs. When assessing relative efficiency using the DEA method, an input- or output-oriented DEA model can be assumed. Therefore, efficiency can indicate a certain/fixed level of output with a minimum level of inputs or the maximisation of output with the existing level of inputs. The methodology can be particularly useful in complex situations where there are numerous DMUs with multiple outputs and inputs that cannot be analysed using other techniques that may be too complicated for management decision-making purposes. For this reason, the DEA methodology is an interdisciplinary scientific method applied in various fields, such as financial institutions or the banking sector [37], schools, universities, hospitals, shopping centres, hotels, business units in forestry, municipal utilities, energy sector at the national level [38] and others.
Due to the limitations of the DEA method, it is important to emphasise that the minimum number of DMUs should be three times greater than or equal to the sum of the number of inputs and outputs. On the other hand, one of the advantages of the DEA method over traditional nonparametric methods is the use of multiple inputs and outputs that can be expressed in different units of measurement. The inputs represent the resources used, while the outputs represent the results obtained, their selection reflecting the interest of the analysts using the DEA method. In this study, inputs and outputs are expressed in U.S. dollars (USD), which represents the allocative (cost) efficiency of offshore wind energy companies. In fact, the relative efficiency of the studied companies is fully evaluated in monetary units, which is in contrast to previous studies where mostly only technical (production) efficiency was evaluated. According to Farrell [39], “technical efficiency of a firm means its success in producing as large an output as possible from a given set of inputs, while allocative efficiency (the original Farrell term is price efficiency) means that a firm uses the various factors of production in the best proportions, in view of their prices. The overall efficiency of the firm is equal to the product of the technical and price efficiencies.”

3.1.1. CCR Model

One of the basic DEA models is the CCR model, which is based on the assumption of constant returns to scale (CRS) and whose efficiency is defined as the ratio of output to input, with higher output per unit of input reflecting greater efficiency [40]. Suppose there are n DMUs that convert m inputs ( x i , i = 1 , 2 , , m ) into s outputs ( y r , r = 1 , 2 , , s ) . The idea of the CCR model is to form virtual inputs ( v 1 x 1 o + + v m x m o ) and virtual outputs ( u 1 y 1 o + + u s y s o ) for each DMUj included in the analysis using the output weights ( u r ) ( r = 1 , , s ) and input weights ( v i )   ( i = 1 , , m ) and solve the following fractional programming problem [41].
Model 1
max v , u θ = u 1 y 1 o + u 2 y 2 o + + u s y s o v 1 x 1 o + v 2 x 2 o + v m x m o
subject to:
u 1 y 1 j + + u s y s j v 1 x 1 j + v m x m j 1 ( j = 1 , , n )
v 1 , v 2 , , v m 0  
u 1 , u 2 , , u s 0  
The optimal values for the weights ( u r )   ( r = 1 , , s ) and ( v i )   ( i = 1 , , m ) are obtained from the CCR model for each DMU and determined from the output and input data of all DMUs in the peer group of the data. The constraints (2) mean that the maximum value of the objective function θ is equal to or less than 1, or that the maximum efficiency result of the DMU under consideration can be 100%. This model can be rewritten as follows [42]:
Model 2
max   θ = r = 1 s u r y r o
subject to:
r = 1 s u r y r j i = 1 m v i x i j   ( j = 1 , , n )
i = 1 m v i x i o = 1  
v 1 , v 2 , , v m 0  
u 1 , u 2 , , u s 0  
Model 3 represents an input-oriented CCR model that determines optimal slack values to reach the efficiency frontier.
Model 3
Min   θ - ε ( i = 1 m s i + r = 1 s s r + )
j = 1 n λ j x i j + s i = θ x i o   ( i = 1 , , m )
j = 1 n λ j y r j s r + = y r o   ( r = 1 , , s )
λ j 0   ( j = 1 , , n )
The ε in the objective function is not Archimedean as infinitely small or smaller than any real positive number. If an optimal solution ( θ * , λ * , s * , s + * ) satisfies θ * = 1 , λ = 1, input slacks s * = 0 , and output slacks s + * = 0 , then DMUo (DMU under consideration) is relatively efficient [41] and is on the efficiency frontier. Otherwise, it is relatively inefficient and lies below the efficiency frontier. The input-oriented Model 3 optimises the slack values to achieve the efficiency frontier, called projections (target values) on the efficiency frontier, which can be calculated as follows:
Inputs:
x i o = θ x i o s i   ( i = 1 , , m )
Outputs:
y r o = y r o + s i +   ( r = 1 , , s )  

3.1.2. BCC Model

The BCC model is another commonly used DEA model based on the assumption of variable returns to scale (VRS) with a piecewise linear efficiency frontier [43]. It differs from the CCR model (Model 3) only in that it includes the convexity constraints:
j = 1 n λ j = 1 , λ j     0   j
Model 4 represents an input-oriented BCC model that obtains optimal slack values to achieve the piecewise linear efficiency frontier. Due to the difference in the efficiency frontier compared to the CCR model, the BCC efficiency scores are better than or at least the same as the CCR efficiency scores for all the DMUs studied compared to the CCR model. Therefore, it is very important to consider the type of returns to scale before evaluating the DMUs.
Model 4
Min   θ ε ( i = 1 m s i + r = 1 s s r + )
j = 1 n λ j x i j + s i = θ x i o   ( i = 1 , , m )
j = 1 n λ j y r j s r + = y r o   ( r = 1 , , s )  
j = 1 n λ j = 1  
  λ j 0   ( j = 1 , , n )
s i 0  
s r + 0  
The definition of BCC efficiency [41] states that if the optimal solution of the BCC model ( θ B * , λ * , s * , s + * ) satisfies θ B * = 1 and s * = 0 , s + * = 0 , the DMUo is BCC efficient and lies on the efficiency frontier, otherwise the BCC is inefficient and lies below the efficiency frontier. As in the case of the CCR model, the projections for all inefficient DMUs can be calculated as follows.
Inputs:
x i o = θ x i o s i   ( i = 1 , , m )
Outputs:
y r o = y r o + s i +   ( r = 1 , , s )  
Figure 1 shows the graphical representation of the CCR and BCC models.
DEA models are based on the assumption that there is a set of admissible possibilities. This set is formed by all possible combinations of inputs and outputs and is bounded by so-called efficient frontiers. Efficient units are those whose combinations of inputs and outputs lie on the efficient frontier [44]. Inefficient units, on the other hand, lie below the efficient frontier.

3.2. Data and the Model

This study includes and analyses 47 offshore wind energy companies from 9 European countries, namely Belgium (number of offshore wind energy companies (n) in the sample = 2), Estonia (n = 1), Finland (n = 1), France (n = 4), Germany (n = 9), Poland (n = 1), Spain (n = 2), Sweden (n = 2), and the United Kingdom of Great Britain and Northern Ireland (n = 25). Offshore wind energy companies were selected for the research sample based on the availability of data from the relevant database (“Orbis Europe”). Only those companies that exclusively use wind energy (and supply to the electricity grid) to generate electrical energy were included in the sample. This is the only activity of the studied companies, so the companies that generate electrical energy from different energy sources are excluded from the sample. In this way, one of the basic assumptions of the DEA method, that the companies are comparable among themselves and operate under similar conditions, is fulfilled (cf. [45]). The inputs and output of the model are determined and presented with the following variables:
Inputs:
  • Tangible fixed assets refer to the value of wind turbines owned by a company (expressed in thousands of USD);
  • Cash and cash equivalent refer to total cash liquid assets (expressed in thousands of USD);
  • Current assets refer to the total amount of short-term assets owned by a company (expressed in thousands of USD).
Output:
  • EBIT (Earnings Before Interest and Taxes) refers to earnings before interest and taxes and is a measure of a company’s profitability that includes all revenues and expenses except interest and tax expenses (expressed in thousands of USD).
The model variables presented refer to the economic characteristics of offshore wind energy companies, which means that only allocative (cost) efficiency was analysed. Tangible fixed assets are the value of offshore wind turbines (in addition to other forms of tangible fixed assets, such as real estate, equipment, land, and others). Although tangible fixed assets are used in business operations over a long period of time, this study evaluates the contribution of property to business efficiency only for the period of the observed years. Cash and cash equivalents of offshore wind energy companies refer to highly liquid short-term assets of a company. In this study, it is reported as a separate variable because of its importance in determining relative efficiency or inefficiency. Another important input variable with relevant economic value is current assets, which refer to short-term assets that an offshore wind energy company expects to use up, convert to cash, or sell within one year or one operating cycle. The variable EBIT is used as the only output of the model. This variable directly shows the success of the offshore wind energy company, i.e., its financial performance in the considered years 2019 and 2020. In addition to analysing profitability, EBIT can also be used to evaluate the relative efficiency of the company, as it eliminates the effects of financing decisions, statutory tax rates, and the application of different accounting principles. Considering only one (mentioned) quantitative variable does not allow a complete assessment of relative efficiency, as other qualitative variables and/or other quantitative variables on the output side are missing. The limitations of the analysis are thus acknowledged in the study, as the focus was on the assessment of allocative (cost) efficiency.
In the wind energy industry, the use of labour is not required once the company starts operations because it is a highly technologically automated industry. Studies show that for every 20 MW of installed capacity, only one or two full-time employees are required to operate and maintain the wind energy company. In addition to the theoretical basis, empirical studies show a very low correlation between labour input and other observed variables [21]. This is the reason why this study does not include labour input as one of the fundamental factors in production processes in the evaluation of relative allocative efficiency.
After selecting 3 inputs and 1 output variable in the model to evaluate the relative (allocative) efficiency of 47 offshore wind energy companies, the statistics of the observed variables used for the DEA method are summarized below (Table 1).
Due to the fact that a number of wind energy companies generated a loss in the observed years (14 companies in 2019 and 13 companies in 2020) and are therefore not suitable for measuring relative efficiency, note that all values of the EBIT variable are increased for 26,100 monetary units (USD) in 2019 and 79,500 monetary units (USD) in 2020. This eliminates the negative value of the variable and allows evaluation of the relative efficiency of the positive values of the company, which is one of the important assumptions of the DEA methodology. It is possible to make data translation (shifting) without changing the efficiency frontier so that the classification of DMU entities as inefficient or efficient (due to the mentioned data transfer) is invariable or translation invariant [46]. Since negative values are not possible, in the mathematical programming of the DEA method, the value zero (0) is replaced by a very low positive value (10–8) with the same result of relative efficiency. When selecting suitable input and output variables, a positive correlation must be assumed, as shown in the following Table 2.
The most important condition in the DEA methodology should be a positive correlation between inputs and outputs, as well as between mutual inputs and mutual outputs. Table 2 and Table 3 show that all inputs and outputs have a positive correlation coefficient. In 2019, the coefficient between the tangible fixed asset input and the output of EBIT is the highest (0.83128), indicating a high correlation between the variables, i.e., an increase in assets increases the profit of the company. The same variables had the highest correlation (0.68774) between input and output in 2020.
The DEA model can be used to evaluate relative efficiency in terms of CRS and VRS. Returns to scale can be expressed as the rate at which output increases when inputs are increased proportionally. In forming the DEA model, the next step in this research is to choose the appropriate DEA model considering the envelope, i.e., constant or variable returns to scale, and given the orientation towards input or output. Without a more detailed analysis, it is not possible to predict the performance of 47 offshore wind energy companies in terms of returns to scale. Therefore, it is necessary to measure and evaluate the relative efficiency using constant (Model 3) and variable (Model 4) returns to scale for the observed years. Finally, according to the results, whether CRS or VRS, is making a choice.
Table 4 shows the results of the relative efficiency of 47 offshore wind energy companies (DMUs) evaluated by the DEA method using the software package DEA-Solver Professional Release 11.0 and applying constant and variable returns to scale. The obtained results point out a significant difference and a significantly larger number of efficient (θ * = 1) companies (DMUs) evaluated with VRS, especially in 2019. In addition, the average efficiency score with variable returns is significantly higher than with constant returns for both 2019 and 2020, indicating that offshore wind energy companies operate with VRS. However, there is another argument for using VRS. It is argued that for a model with VRS, i.e., the BCC model, translational invariance is possible [46], as mentioned earlier.
The final selection of the DEA model is made by considering the orientation. In assessing relative efficiency, the DEA model can be oriented towards inputs or outputs. The input-oriented DEA model aims to minimise the values of inputs used for the same level of outputs, while the output-oriented DEA model maximises the possible values of outputs using the same values of inputs. In this research, the relative efficiency of offshore wind energy companies is presented based on the input-oriented DEA model. The main reason for choosing the input-oriented DEA model is to better interpret the results of this research. Moreover, the input-oriented DEA model with VRS (BCC model) is suitable for translation invariance in terms of output but not in terms of inputs [47]. This means that it is possible to transform the negative values of the output variables into positive values. As mentioned above, some offshore wind energy companies have made a loss (the negative value of the EBIT variable) in the observed years. By applying the translation invariance procedure, all values of the EBIT variable were increased by 26,100 monetary units (USD) in 2019 and 79,500 monetary units (USD) in 2020, thus transforming them into positive values. Due to the translation invariance, the efficiency frontier has not changed, i.e., the number of efficient DMUs remains the same despite the changed values of the EBIT variable.

4. Empirical Results

The relative efficiency of 47 offshore wind energy companies is evaluated using the input-oriented BCC model, which indicates variable returns to scale. Table 5 below shows the score and rank of the relative efficiency of 47 DMUs in 2019 and 2020, as well as the 9 countries they belong to.
Table 5 lists all 47 offshore wind energy companies (DMUs) classified into 2 groups: relatively efficient DMUs (θ* = 1) and relatively inefficient DMUs (θ* < 1). In assessing relative efficiency based on the 2019 data, 15 DMUs were found to be relatively efficient, while 32 DMUs were found to be relatively inefficient. Based on 2020 data, it can be seen that 7 companies (DMUs) were classified as relatively efficient, while 40 DMUs were classified as relatively inefficient. This can already be seen in Table 4, which shows the scores for relative efficiency.
As shown in Table 5, there is no significant relationship between the value of relative efficiency and the country where the offshore wind energy company is located. In other words, the results obtained by the model indicate that the relative efficiency of the offshore wind energy companies is not determined by external factors related to the specific circumstances in each country where the analysed offshore wind energy companies operate but by internal factors in the form of financial variables, i.e., tangible fixed assets, cash and cash equivalents, and current assets.
On the other hand, the results are consistent with the basic hypothesis of this study, which is as follows: by evaluating the relative efficiency of offshore wind energy companies in European countries, it is possible to determine a correlation between the results of efficiency between the two observed periods with slight deviations. More specifically, although there are notable differences in the score results of relative efficiency, the correlation is significant with slight deviations in the ranking of the analysed offshore wind energy companies in the observed years, i.e., in 2019 and 2020. This is confirmed by the fact that several offshore wind energy companies are ranked the same in the efficiency score in the observed years 2019 and 2020. This is true for six companies that are relatively efficient in both 2019 and 2020, as well as for companies that are ranked the same under the following numbers: 33, 34, 37, and 47. In addition, there are a few companies that are ranked nearly equally in 2019 and 2020. For example, Aberdeen Offshore Wind Farm Limited is ranked as 27th most efficient company in 2019 and as 26th most efficient company in the following year 2020.
The assessment of relative efficiency implemented by the DEA method not only provides an estimate of the current level of relative efficiency but is also of great importance in the field of efficiency management of offshore wind energy, as it provides information on how to eliminate relative inefficiency and identifies sources and amounts of inefficiency. Therefore, for a relatively inefficient offshore wind energy company to be able to become relatively efficient, it is necessary to make projections or improvements and “shift” some of the factors to the efficiency frontier. These projections or improvements are the basic objectives of this research, and besides the determination, a solution to the problem of inefficiency is proposed. When applying the input-oriented DEA model, in order to achieve relative efficiency (θ* = 1), it is necessary to reduce the input variables while maintaining the existing output, i.e., the required changes or projections (in percentage) of each variable should be reduced.
To determine the amount of relative inefficiency of offshore wind energy companies in general, significant importance is given to determining the average amounts or average improvements for each observed input in the model (tangible fixed assets, cash and cash equivalents, and current assets). With such average adjustments (the reduction of factors), a possible achievement of relative efficiency at the aggregate size level is suggested. The average percentage improvements for relatively inefficient offshore wind energy companies are shown in Table 6 below.
Table 6 shows the various amount of projections or average improvements for relatively inefficient offshore wind energy companies to become relatively efficient. Particularly highlighted are the extremely high values in both 2019 and 2020, from 46.19% to 70.14%. Such enormous values of projections indicate that the financial inputs of offshore wind energy companies will radically decrease. Although this research does not show the average improvements for each relatively inefficient offshore wind energy company, the empirical results suggest that about 10 companies (DMUs) have a value of projections above 99% for each input variable. This means that the companies have double resource capacity, which should be halved to become relatively efficient. It should also be noted that the average improvements for each observed input are higher in 2020 than in 2019, which is consistent with the relative efficiency results that show there are fewer relatively efficient offshore wind energy companies in 2020 (7 DMUs) than that in 2019 (15 DMUs). In addition, the average efficiency score in 2020 is lower (0.4542) than that in 2019 (0.546). This can be explained by the fact that the quality of management of offshore wind energy companies should be necessarily higher in 2020 than in the previous year. From the management’s perspective, significant efforts and improvements in all financial variables, i.e., tangible fixed assets, cash and cash equivalent, and current assets, are required to achieve relative efficiency.
To conclude, offshore wind energy companies should, on average, reduce tangible fixed assets by 47.42% in 2019 and 54.78% in 2020, cash and cash equivalents by 58.85% in 2019 and 70.14% in 2020, and variable current assets by 46.19% in 2019 and 63.28% in 2020 to achieve relative efficiency. The economic impact of the proposed reduction of inputs would ensure the “return” to the equilibrium point of the company.
It should be noted that this study does not examine the direct impact of the country and its reforms on the value of relative efficiency. This is indirectly contained in the economic variables (inputs and outputs) of the model.

5. Discussion and Policy Implications

Based on the results of this research, it is quite clear that they imply numerous considerations, especially in the field of managerial decision-making but also in the formation of public policies. The given information related to the necessary adjustments, i.e., amounts of projections and improvements by the relatively inefficient offshore wind energy companies, is of particular importance for all stakeholders involved in the renewable energy sector, especially in the wind energy sector. Ensuring exactly specified projections to eliminate inefficiencies would improve company performance, increase efficiency, and make the best use of resources. By increasing efficiency, more resources would be available for the company to use to further improve its operations and performance or to further stimulate its economic activity. This could also contribute to the growth of the company as a whole. If a company performs functions and activities efficiently, i.e., faster, more cost-effectively, and more competently than its competitors, it can achieve various benefits, such as higher profit levels and greater customer satisfaction.
In addition, the efficiency of the company could have an impact on the competitiveness of other companies in the industry. Therefore, efficiency is important for a company to gain a competitive advantage over its rivals. Consequently, competitiveness ensures market dominance. On the other hand, efficient offshore wind energy companies can contribute to the growth and development of the wind energy industry by ensuring a reliable and sufficient power supply.
Since the world’s first offshore wind farm was installed in Vindeby off the southern coast of Denmark in 1991, wind energy potential has been critical if Europe is to achieve its goals of reducing carbon emissions by at least 55% by 2030 compared to 1990 and becoming carbon neutral by 2050. Europe’s leadership in offshore renewables can be based on the enormous potential offered by the European Union’s seas, from the North Sea and the Baltic Sea to the Mediterranean, from the Atlantic to the Black Sea, as well as the seas around the EU’s outermost regions. The EU Offshore Renewable Energy Strategy envisages an installed capacity of at least 60 GW for offshore wind by 2030, rising to 300 GW by 2050 [48].

6. Conclusions

Offshore wind energy has emerged as a viable alternative to conventional energy resources to reduce greenhouse gas emissions and thus affect climate change. Today, the offshore wind industry faces the challenge of becoming competitive and thus significantly reducing the cost of electricity from offshore wind. In view of this, there is a need to measure and evaluate the operational performance of offshore wind energy companies. Therefore, the purpose of this study is to evaluate the allocative efficiency of 47 offshore wind energy companies in 9 European countries in 2019 and 2020 using the input-oriented BCC DEA model. The basic hypothesis is that by evaluating the relative efficiency of offshore wind energy companies in European countries, it is possible to determine a correlation between the results of efficiency between the two observed periods with slight deviations. The empirical results show no significant correlation between the score of relative efficiency and the country where the offshore wind energy company is located. On the other hand, the results are consistent with the basic hypothesis of this study. From a management perspective, significant improvements in all financial variables, i.e., tangible fixed assets, cash and cash equivalents, and current assets, are required to achieve relative efficiency. This pan-European analysis is useful in understanding the current state of offshore wind energy companies and is intended to provide a benchmark for future analysis as well as further insight into the financial factors that influence wind farm efficiency. Certain limitations of this study lie in the limited research period of only two years due to data availability. A better analysis of the performance evaluation of offshore wind companies would be possible through a dynamic component of efficiency, the so-called “DEA window analysis”, which represents the change in efficiency over time. To fill this research gap, further research should examine relative efficiency over several years to provide a clearer picture of company performance.

Author Contributions

Conceptualization, D.M. and S.Č.; methodology, D.M.; formal analysis, S.Č.; resources, S.Č.; data curation, D.M.; writing—original draft preparation, D.M.; writing—review and editing, B.O.D.; visualization, B.O.D.; supervision, B.O.D. All authors have read and agreed to the published version of the manuscript.

Funding

This research received no external funding.

Data Availability Statement

The research data are taken from the “Orbis Europe” database (https://orbiseurope.bvdinfo.com, accessed on 15 January 2023).

Acknowledgments

This work has been fully supported by/supported in part by the University of Rijeka, Croatia under the project “New Energy Paradigm—How to Reconciliate Sustainability and Feasibility”, and project numbers “uniri-drustv-18-61” and “uniri-drustv-18-255-1424”.

Conflicts of Interest

The authors declare no conflict of interest.

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Figure 1. CCR and BCC models.
Figure 1. CCR and BCC models.
Energies 16 03709 g001
Table 1. Statistics of inputs and output in the DEA model for 2019 and 2020.
Table 1. Statistics of inputs and output in the DEA model for 2019 and 2020.
Tangible Fixed AssetsCash & Cash EquivalentCurrent AssetsEBIT
20192020201920202019202020192020
Max2,589,1532,996,115173,763158,2071,252,3131,196,154299,885359,841
Min10.079.580.070.033.716.2889.5623.21
Avg.507,115558,95424,74418,076100,000105,23863,310121,472
SD644,258722,45343,25330,816221,661220,46160,25971,735
Source: Authors’ calculation evaluated by the Data Envelopment Analysis method using the software package DEA-Solver Professional Release 11.0.
Table 2. Coefficients of inputs and output correlation in 2019.
Table 2. Coefficients of inputs and output correlation in 2019.
Tangible Fixed AssetsCash & Cash EquivalentCurrent AssetsEBIT
Tangible fixed assets10.753450.432190.83128
Cash & cash equivalent0.7534510.565630.61764
Current assets0.432190.5656310.64641
EBIT0.831280.617640.646411
Source: Authors’ calculation.
Table 3. Coefficients of inputs and output correlation in 2020.
Table 3. Coefficients of inputs and output correlation in 2020.
Tangible Fixed AssetsCash & Cash EquivalentCurrent AssetsEBIT
Tangible fixed assets10.72960.48840.68774
Cash & cash equivalent0.729610.481780.34794
Current assets0.48840.4817810.4791
EBIT0.687740.347940.47911
Source: Authors’ calculation.
Table 4. Relative efficiency with the use of constant and variable returns to scale.
Table 4. Relative efficiency with the use of constant and variable returns to scale.
20192020
Relative Efficiency ScoreCCR Model (CRS)BCC Model (VRS)CCR Model (CRS)BCC Model (VRS)
Number of efficient DMUs 141537
Number of inefficient DMUs43324440
Average efficiency score0.16190.5460.1480.4542
Max. efficiency score1111
Min. efficiency score00.000100.0001
Source: Authors’ calculation. 1 Because of the constraints in the software package, the number of fully efficient and weakly efficient entities with the highest efficiency score (θ* = 1) is shown.
Table 5. Relative efficiency of 47 offshore wind energy companies (DMUs).
Table 5. Relative efficiency of 47 offshore wind energy companies (DMUs).
Rank (2019)Score (2019)DMUsCountryRank (2020)Score (2020)
11AMRUM-OFFSHORE WEST GMBHGermany11
11AN AVEL BRAZ OFFSHOREFrance11
11DUDGEON OFFSHORE WIND LIMITEDUnited Kingdom11
11GYM OFFSHORE ONE LIMITEDUnited Kingdom11
11INNER DOWSING WIND FARM LIMITEDUnited Kingdom11
11RWE BERGHEIM WINDPARKBETRIEBSGESELLSCHAFT MBHGermany11
11GYM OFFSHORE TWO LIMITEDUnited Kingdom100.9839
11GYM OFFSHORE THREE LIMITEDUnited Kingdom110.9216
11BEATRICE OFFSHORE WINDFARM LIMITEDUnited Kingdom180.4896
11GODE WIND 1 OFFSHORE WIND FARM GMBH & CO. OHGGermany190.4777
11GREATER GABBARD OFFSHORE WINDS LIMITEDUnited Kingdom200.4678
11GODE WIND 2 OFFSHORE WIND FARM P/S GMBH & CO. OHGGermany230.413
11SEARENERGY OFFSHORE HOLDING GMBH & CIE. KGGermany290.2936
11BARROW OFFSHORE WIND LIMITEDUnited Kingdom310.2461
11NEART NA GAOITHE OFFSHORE WIND LIMITEDUnited Kingdom360.0991
160.9736LYNN WIND FARM LIMITEDUnited Kingdom90.9958
170.952RWE RENEWABLES UK ROBIN RIGG EAST LIMITEDUnited Kingdom120.891
180.7121THANET OFFSHORE WIND LIMITEDUnited Kingdom150.6423
190.6897NORTH HOYLE WIND FARM LIMITEDUnited Kingdom130.8752
200.6408GLOBAL TECH I OFFSHORE WIND GMBHGermany240.3557
210.6205SUURHIEKKA OFFSHORE OYFinland11
220.5911RODSAND 2 OFFSHORE WIND FARM ABSweden270.3309
230.5797SCIRA OFFSHORE ENERGY LIMITEDUnited Kingdom250.3409
240.5346BORKUM RIFFGRUND 2 OFFSHORE WIND FARM GMBH & CO. OHGGermany220.4365
250.4681ASPIRAVI OFFSHOREBelgium210.4563
260.4296RWE RENEWABLES UK ROBIN RIGG WEST LIMITEDUnited Kingdom170.5045
270.4208ABERDEEN OFFSHORE WIND FARM LIMITEDUnited Kingdom260.3328
280.4107MEDITERRANEAN OFFSHORE WIND ENERGY SLSpain320.2196
290.3915SVEA VIND OFFSHORE ABSweden80.9999
300.3885RAMPION OFFSHORE WIND LIMITEDUnited Kingdom140.8676
310.3776RWE RENEWABLES UK SCROBY SANDS LIMITEDUnited Kingdom160.5604
320.3236ASPIRAVI OFFSHORE IIBelgium280.3141
330.3232MERKUR OFFSHORE GMBHGermany330.2032
340.2424WALNEY (UK) OFFSHORE WINDFARMS LIMITEDUnited Kingdom340.1291
350.2135BLYTH OFFSHORE DEMONSTRATOR LIMITEDUnited Kingdom300.2466
360.1822LINCS WIND FARM LIMITEDUnited Kingdom350.119
370.1736HIIUMAA OFFSHORE TUULEPARK OUEstonia370.0746
380.0064PARC EOLIEN OFFSHORE DE PROVENCE GRAND LARGEFrance420.0016
390.0056RWE OFFSHORE WIND POLAND SP. Z O.O.Poland410.0017
400.0041MORAY OFFSHORE WINDFARM (WEST) LIMITEDUnited Kingdom390.0067
410.0026EAST ANGLIA OFFSHORE WIND LIMITEDUnited Kingdom380.0389
420.002OW OFFSHORE SLSpain440.0011
430.0018EOLIENNES OFFSHORE DES HAUTES FALAISESFrance400.0054
440.001KINCARDINE OFFSHORE WINDFARM LIMITEDUnited Kingdom450.0009
450.0006DOTI DEUTSCHE OFFSHORE- TESTFELD- UND INFRASTRUKTUR-GMBH & CO. KGGermany460.0007
450.0006EOLIENNES OFFSHORE DU CALVADOSFrance430.0015
470.0001MORAY OFFSHORE WINDFARM (EAST) LIMITEDUnited Kingdom470.0001
Source: Authors’ calculation evaluated by the Data Envelopment Analysis method using the software package DEA-Solver Professional Release 11.0.
Table 6. Average improvements for relatively inefficient offshore wind energy companies (DMUs) (%).
Table 6. Average improvements for relatively inefficient offshore wind energy companies (DMUs) (%).
Tangible Fixed AssetsCash & Cash EquivalentCurrent Assets
201920202019202020192020
47.4254.7858.8570.1446.1963.28
Source: Authors’ calculation.
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Maradin, D.; Olgić Draženović, B.; Čegar, S. The Efficiency of Offshore Wind Energy Companies in the European Countries: A DEA Approach. Energies 2023, 16, 3709. https://doi.org/10.3390/en16093709

AMA Style

Maradin D, Olgić Draženović B, Čegar S. The Efficiency of Offshore Wind Energy Companies in the European Countries: A DEA Approach. Energies. 2023; 16(9):3709. https://doi.org/10.3390/en16093709

Chicago/Turabian Style

Maradin, Dario, Bojana Olgić Draženović, and Saša Čegar. 2023. "The Efficiency of Offshore Wind Energy Companies in the European Countries: A DEA Approach" Energies 16, no. 9: 3709. https://doi.org/10.3390/en16093709

APA Style

Maradin, D., Olgić Draženović, B., & Čegar, S. (2023). The Efficiency of Offshore Wind Energy Companies in the European Countries: A DEA Approach. Energies, 16(9), 3709. https://doi.org/10.3390/en16093709

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