2.1. A Brief Overview of Innovation Supports in Turkey

Although innovation supports are also provided by private enterprises and EU grants in Turkey, government is the main actor in this environment. According to the Turkish Statistical Institute (TURKSTAT) database, it is seen that the amount of the central government budget on R&D expenditures and appropriations increased 3.5 times from 2010 to 2020 in local currency. In TURKSTAT (2021) the areas with the highest funding in 2020 are universities (48.8%), defence (13.4%) and industrial production and technology (10.4%). TUBITAK is the leading institution in terms of innovation support in Turkey. The institution is affiliated with the Ministry of Industry and Technology, supports academic and industrial R&D activities and innovations, and also acts as the secretariat of the Supreme Council of Science and Technology (SCST), Turkey’s top industry and technology policymaker (TUBITAK 2021).

KOSGEB, another institution affiliated with the Ministry of Industry and Technology, provides reimbursable and/or grant support especially to SMEs, and aims to reveal SMEs that use high technology, have a high R&D and innovative capacity and make a difference in global competition. As well as grants and support, KOSGEB also provides technical and administrative recommendations and training programs to SMEs. Supports are provided to the applicants under support programmes such as R&D and innovation, strategic product, SME development, foreign market, and business development (KOSGEB 2020).

Other institutions that provide support to companies are the Development Agencies. These are non-profit development units with their own working and financing mechanism and public legal entity, established by the decision of the Council of Ministers and under the coordination of the Ministry of Industry and Technology. Development agencies provide training within the scope of technical support to companies and assist in project preparations. In the context of financial support, some project basis grants are provided under the headings of interest-free loans and direct financing support.

The term ‘support’ within the context of this article encompasses a comprehensive array of assistance mechanisms extended by the public sector, with particular emphasis on entities such as TÜBİTAK and KOSGEB. Furthermore, this variable encompasses the various forms of support accessible from local municipalities and the EU. It is noteworthy that, in Turkey, EU funding initiatives are channelled through TÜBİTAK. Consequently, the all-encompassing variable denoted as ‘government support’ within this study encapsulates the entire spectrum of support categories available to enterprises. To summarize, ‘support’ encompasses a comprehensive range of support modalities accessible to companies.

3.1. Analysis of Innovation Determinants

To examine the microeconomic determinants of different types of innovation in Turkish manufacturing firms, a panel multinomial logit model is used in this study. The merged data from Innovation Survey and Annual Industry and Service Statistics, both received from the Turkish Statistical Institute are used in the empirical analysis and only responses from innovating firms are considered in the analysis. In the context of our research, the deliberate exclusion of non-innovating firms in favour of a focus on innovating firms does not inherently entail sample selection bias. This approach aligns with the specific research question and objectives, which are centred on the examination of innovation and its associated attributes within the subset of innovating firms. Such a targeted sampling strategy corresponds to the practice of purposive or selective sampling, wherein a subset of the population is intentionally chosen to suit the research inquiry.

Sample selection bias typically arises when the sample selection process introduces systematic errors or biases that compromise the extrapolation of findings to the broader population. In this particular research context, the focus on innovating firms is well-justified given the research’s core objective, which is to gain insights into the fundamental attributes of innovation categories within the specific subset of innovating firms. Consequently, the outcomes and interpretations are confined to the context of innovating firms, and any broad generalizations concerning non-innovating firms or the entirety of firms are prudently avoided. A panel dataset consisting of 15,615 observations covering the 2004–2014 period (in two-year periods) was obtained by combining Annual Industry and Service Statistics and Innovation Surveys. Since the dataset for Annual Industry and Service Statistics after 2014 and data from Innovation Surveys after 2016 are not compatible with prior years, 2004–2014 is the latest and largest available dataset for this evaluation.

The dependent variable in the analysis is the type of innovation activity of the enterprise (1 = product innovation, 2 = process innovation, 3 = organizational innovation, 4 = marketing innovation, 5 = multiple innovation activity, which includes a combination of several innovation activities from 1 to 4). Since the dependent variable in question cannot be ordered in any meaningful way, the multinomial logit model was preferred for the estimation of the model.

The multinomial logistic regression method is an extended version of the logistic regression method with at least three or more variable levels. Let us assume that the dependent variable is three-level and code it as Y = 0,1,2. Considering the logistic regression model for the two-level dependent variable, a single logit transform is applied as Y = 0 versus Y = 1. For the three-level Y variable, two logit transformations must be made separately for Y = 1 and Y = 2, with Y = 0 being the reference category (Hosmer and Lemeshow Reference Hosmer and Lemeshow2000). For the model with p variables and constant terms, the logit function can be arranged as follows:

(1) $$\begin{gathered}{g_1}\left( x \right) = {\text{log}}\left( {\frac{{P\left( {y = \frac{1}{x}} \right)}}{{p\left( {y = \frac{0}{x}} \right)}}} \right) = {\beta _{10 + }}{\beta _{11}}{x_1} + \ldots + {\beta _{1p}}{x_p} \hfill \\ {g_2}\left( x \right) = {\text{log}}\left( {\frac{{P\left( {y = \frac{2}{x}} \right)}}{{P\left( {y = \frac{0}{x}} \right)}}} \right) = {\beta _{20 + }}{\beta _{21}}{x_1} + \ldots + {\beta _{2p}}{x_p} \hfill \\ \end{gathered}$$

The conditional probability functions are:

(2) $$\begin{gathered}lP\left( {Y = 0/x} \right) = \frac{1}{{1 + {e^{{g_1}\left( x \right)}} + {e^{{g_2}\left( x \right)}}}} \hfill \\ P\left( {Y = 1/x} \right) = \frac{{{e^{{g_1}\left( x \right)}}}}{{1 + {e^{{g_1}\left( x \right)}} + {e^{{g_2}\left( x \right)}}}} \hfill \\ P\left( {Y = 2/x} \right) = \frac{{{e^{{g_2}\left( x \right)}}}}{{1 + {e^{{g_1}\left( x \right)}} + {e^{{g_2}\left( x \right)}}}} \hfill \\ \end{gathered}$$

If the expression is generalized for the g group, the conditional probability function for any variable j can be written as follows where $${\beta _0}=0$$ and $${g_0}\left( x \right)=0$$ (Hosmer et al. Reference Hosmer, Lemeshow and Sturdivant2013):

(3) $$P\left( {Y = j/x} \right) = {{{{e^{{g_l}\left( x \right)}}}}\over {{\sum\limits_{j=0}^{g - 1} {{e^{{g_j}\left( x \right)}}}} }}$$

The definitions of explanatory variables are provided in Table 1. The independent variables were chosen in line with the existing literature in order to understand the structure of the market and the firm. The question of whether the firm produces only for the Turkish market or for both Turkey and the foreign market is used to represent the level of competition the firm faces. In other words, firms producing only for the domestic market are expected to be located in a relatively less competitive environment and, therefore, innovation activities will be limited. In a similar vein, it is possible to argue that with the innovation being new for the market or for the enterprise, the export–import capacity of the firms and the foreign capital shares are also associated with the competitive power of the firm and are expected to have an impact on innovation activities. It is widely recognized that the performance of exports and imports varies across sectors. To establish a correlation between innovation and export or import intensity, two widely adopted measures are used. The first method involves using a dummy variable to distinguish between exporters (importers) and non-exporters (non-importers). The second method involves calculating export (import) intensities by dividing exports (imports) by total revenue (Kirbach and Schmiedeberg Reference Kirbach and Schmiedeberg2008). In addition, sectoral dummies are commonly employed to highlight the differences between sectors, as mentioned earlier. In this study, we adopted an approach that uses a dummy variable to identify firms with high levels of exports (imports) within a given sector. To determine this, we utilized sectoral averages as a benchmark. Firms with a higher ratio of exports (imports) to total revenue than the sectoral average of innovators are assigned a value of 1 for the export (import) dummy. This methodology allowed us to incorporate sectoral export (import) intensity in assessing its impact on innovation. Firms with an internal R&D department and firms engaged in continuous R&D activities are expected to have a higher probability and success of innovation. The dataset includes information pertaining to the geographical locations of companies’ corporate headquarters. Upon close examination, it became evident that the companies under investigation operate across a diverse array of provinces. Originally, the intention was to incorporate this geographical diversity into the analysis under various regional definitions. However, it became apparent that the principal disparities in terms of concentration were observed primarily among the central regions, notably including Istanbul, the Ankara-centred central Anatolia region, and the Aegean region, in contrast to the remaining regions. Consequently, regional information was incorporated into the analysis as a binary categorical variable, with the purpose of accounting for the influence of regional concentration.

Table 1. Explanatory variable definitions

The present exposition briefly elucidates the theoretical underpinning of the explanatory variables, expounding upon their respective definitions within the context of this study. It is imperative to note that a substantial body of literature has expounded upon the pivotal significance of these independent variables in the realm of innovation processes. For instance, extant scholarly works have elucidated the salient role of R&D expenditures (Silva et al. Reference Silva, Pires and Teles2021; Kučera and Fil’a Reference Kučera and Fiľa2022), the introduction of novel products (Sok and O’Cass Reference Sok and O’Cass2015; Hottenrott and Lopes-Bento Reference Hottenrott and Lopes-Bento2016), and the provision of support throughout the innovation process (Wei and Liu Reference Wei and Liu2015; Szczygielski et al. Reference Szczygielski, Grabowski, Pamukcu and Tandogan2017).

Furthermore, extant investigations have underscored the notion that the R&D capacity of firms stands as a pivotal determinant of their innovative undertakings, positing that an escalation in R&D outsourcing may concomitantly diminish a firm’s innovative output (Berchicci Reference Berchicci2013). Within this particular context, akin to the present study, the prospect of variations in innovation potentiality contingent upon a firm’s continuity in R&D endeavours and the presence of internal R&D units warrants empirical scrutiny.

In the context of international trade, Aristei, Castellani, and Franco (Reference Aristei, Castellani and Franco2013) proffer empirical evidence substantiating a positive influence on the sales performance of exporting firms, particularly those actively engaged in product innovation. Collaborative endeavours, conversely, have emerged as a contentious and vigorously debated topic within the purview of innovation performance. While prevailing research contends that collaborations manifest a profound significance (Xie et al. Reference Xie, Liu and Chen2023), it is noteworthy that certain studies have articulated reservations regarding the efficacy of collaborations that are discontinued, interrupted (Belderbos et al. Reference Belderbos, Carree, Lokshin and Fernández Sastre2015), or characterized by a dearth of mutual trust (Lai et al. Reference Lai, Chen, Chiu and Pai2011), positing that these factors may engender deleterious effects on innovation performance.

Additionally, the extant literature has also engaged in comparative analyses of the innovation performance between indigenous firms and those with a global operational reach (Bernard et al. Reference Bernard, Jensen and Schott2009).

Descriptive statistics for the dependent variables and explanatory variables are provided in Tables 2 and 3, respectively. Although our analysis exclusively focuses on innovator firms, we have included descriptive statistics for the entire sample in order to present a comprehensive overview of the dataset. While the ratio of innovating firms among all firms considered is 31%, it is observed that a significant part of these firms make a product innovation (45%).

Table 2. Descriptive statistics regarding dependent variable

Table 3. Descriptive statistics

3.2. Analysing the Effects of Government Support on Innovation Behaviour

The evaluation of the effect of a subsidy on innovation behaviour is subject to a selection problem, which can compromise the validity of the study results. It is plausible to argue that subsidies are not randomly assigned, and that the allocation of subsidies is influenced by various factors. For instance, governments may allocate subsidies in a manner that maximizes the likelihood of achieving the policy goal, such as promoting innovation or supporting specific sectors of the economy. Therefore, firms that receive subsidies may be those that are deemed most likely to achieve the desired outcome, rather than being a random selection, which can be referred to as the ‘picking the winner’ strategy.

Additionally, firms that apply for and receive subsidies may differ from those that do not in terms of their characteristics, such as their level of information, past innovation success, or level of human capital. These factors can affect the likelihood of receiving a subsidy, and may also influence the effect of the subsidy on innovation behaviour. For instance, firms with high levels of human capital may be more likely to innovate in response to a subsidy, as they have the necessary skills and resources to take advantage of the funding.

Addressing the selection problem is important to ensure that the study results accurately reflect the effect of the subsidy on innovation behaviour, rather than being biased by the factors that influence the allocation of subsidies. This can be achieved through various methods, such as employing rigorous statistical techniques to account for selection bias, or using natural experiments to compare the outcomes of firms that receive subsidies to those that do not, while controlling for other relevant factors. (Mulligan et al. Reference Mulligan, Lenihan and Doran2019). Even if it is the ‘picking the winner’ strategy or self-selection on behalf of the firms, subsidy evaluation is prone to a selection bias. In order to overcome this endogeneity problem, several methodologies have been offered. PSM is one of those non-parametric matching methodologies to be employed in this study. PSM allows researchers to match subsidy recipients and non-recipients on selected, key characteristics, which yield a similar propensity to innovate after a subsidy (Görg and Strobl Reference Görg and Strobl2007).

In this study, the PSM method is used to examine the effects of government support on innovation behaviour on enterprises. PSM is a statistical technique utilized to mitigate bias in research studies (Wang Reference Wang2021). Due to the inability to randomly allocate individuals or observations into different groups, there is a possibility that the groups being compared are not truly comparable. Propensity score matching addresses this issue by creating a ‘pseudo-randomized’ comparison between groups with similar characteristics.

PSM involves matching observations from treatment and control groups based on their estimated propensity scores. This process entails selecting individuals from the treatment group who have similar propensity scores to individuals in the control group, and vice versa. Various methods, including one-to-one matching, nearest neighbour, and caliper matching (Torche and Costa-Riberio Reference Torche and Costa-Ribeiro2012), can be employed to match individuals. Following matching, the balance of covariates between the treatment and control groups is assessed to ensure that they are comparable. A primary benefit of PSM is that it helps to reduce bias by balancing the covariates between treatment and control groups, resulting in similar characteristics and reduced risk of confounding.

To summarize, the steps involved in PSM analysis include the acquisition of representative and comparable data for both treatment and control groups, the estimation of observations using probit, logit, or other discrete choice models as a function of observable characteristics, and the matching of pairs using techniques such as nearest neighbours, nonlinear matching, or multiple matches. Once matching is complete, the impact is calculated by comparing the means of outcomes across observations and their matched pairs.

PSM has the advantage of improving the precision of the estimated treatment effect by reducing the variance of the treatment effect estimator. This can be particularly important in small sample sizes or when there is a large number of covariates that need to be controlled for. Additionally, propensity score matching is a flexible method that can accommodate both binary and continuous treatments or exposures and can be used with a variety of statistical models.

However, researchers should also be aware of the potential disadvantages of propensity score matching. This method can only control for observed confounding variables, and it cannot account for unobserved confounders. This means that there is still a risk of bias if there are important confounding variables that are not included in the analysis. Furthermore, propensity score matching relies on the assumption that individuals who receive the treatment or exposure have the same propensity to receive it as those who do not receive it. If there is selection bias in the observational data, the propensity scores may not accurately reflect the true likelihood of receiving the treatment or exposure.

Propensity score matching can also result in a loss of sample size if there are no suitable matches for some individuals in the treatment group. This can reduce the statistical power of the analysis and increase the risk of Type II errors. Additionally, the results of the analysis can be sensitive to the choice of model and the inclusion/exclusion of certain variables, and the method may be difficult to interpret for non-experts.

While propensity score matching has some limitations, it can still be a useful method for estimating treatment effects in observational studies. In the case of innovation, research often involves observational studies, where individuals or firms are not randomly assigned to receive the innovation or not. In such cases, as mentioned above, confounding variables may influence the outcome of interest, and without proper control for these variables it is difficult to isolate the effect of innovation. Propensity score matching can help to address this issue by creating a comparison group that is similar to the treatment group in terms of observed characteristics, thereby reducing the bias that may arise from uncontrolled confounding variables. Furthermore, PSM can also improve the precision of the estimated treatment effect by reducing the variance of the treatment effect estimator. This can be particularly important in innovation research, where the effects of innovation may be small or difficult to detect without precise estimates.

In this context, innovative firms that do not receive any government support constitute the control group, while firms that are supported by the government compose the experimental group. Balanced and stabled blocks are formed by using observable characteristics in each group and matching these characteristics with the PSM method. It is possible to calculate propensity scores of these blocks by using parametric or semi-parametric methods. PSM involves estimating the probability of receiving the treatment (propensity score) based on observable characteristics, and then matching individuals with similar propensity scores between the treatment and control groups. There are two main approaches for estimating the propensity score: parametric and semi-parametric methods.

Parametric methods assume a functional form for the relationship between the covariates and the treatment assignment, such as a logistic regression model. The advantage of parametric methods is that they can produce more precise estimates of the propensity score, especially when the functional form is correctly specified. However, if the model is misspecified, the estimates can be biased.

Semi-parametric methods, on the other hand, do not make strong assumptions about the functional form of the relationship between the covariates and the treatment assignment. Examples of semi-parametric methods include generalized boosted models (GBM) and generalized additive models (GAM). The advantage of semi-parametric methods is their flexibility, as they can capture complex relationships between covariates and treatment assignment. However, they may produce less precise estimates of the propensity score than parametric methods.

Once the propensity scores are estimated using either parametric or semi-parametric methods, matching can be performed using various techniques, such as nearest neighbour matching or kernel matching. The goal is to create balanced and stable blocks of individuals with similar propensity scores in the treatment and control groups, so that any differences in outcomes can be attributed to the treatment effect rather than confounding variables.

In summary, both parametric and semi-parametric methods can be used to estimate propensity scores in PSM, with parametric methods providing more precise estimates but requiring stronger assumptions, and semi-parametric methods offering more flexibility but potentially less precision. The choice of method should depend on the specific research question and data characteristics.

In this study, the probit method which is used in the literature widely is chosen for the calculation. Following the calculation of propensity score with the probit method, the average effects of the intervention on the intervened by the PSM method can be defined using equation (4) (Cameron and Trivedi Reference Cameron and Trivedi2009).

(4) $${ATT = E({Y_{1}} \,– \,{Y_{0}} | D = 1) = E({Y_{1}} | D = 1) – E({Y_{0}} | D = 1)}$$

where Y ₁ and Y ₀ in equation (4) denote the presence and absence of the intervention by D, respectively. The calculation of the expected value of Y ₁ in this equation is quite easy, but E(Y ₀|D=1) is not observable by definition. In this case, it is necessary to calculate propensity scores in order to calculate ATT. By using propensity scores, it is possible to select firms with at least as much intervention possibility as the experimental group but not to be intervened. In this case, the PSM estimate of ATT can be made through equation (5).

(5) $${ {ATT_{PSM}} = {E_{P(X) | D = 1}} \{E[{Y_{1}} | D = 1, P(X)]\,– \,E[{Y_{0}} | D = 0, P(X)]\} }$$

Here, P(X) is the conditional probability function of the intervention. In this study, it represents the possibility of a firm receiving government support for innovation activities and can be estimated using observable variables.

First, propensity scores are calculated by the probit method for the PSM analysis, then using these scores, the effects of intervention are calculated by the PSM analysis. When estimating equation (5), various matching methods are used for the robustness check. These methods are basically the same but differ only in the selection and weighting techniques of non-treated observations (Caliendo and Kopeinig Reference Caliendo and Kopeinig2008).