2. Concepts of Innovativeness—Literature Overview
One of the problems relevant to research on innovativeness is the difficulty of establishing a precise definition for the following constructs: innovation, invention, creativity, and entrepreneurship, definitions that would allow for the quantification of these constructs. Scholarly discourse on these definitions has created a dizzying array of differing and sometimes contradicting explanations.
Some attribute this state of affairs, at least in part to misdefinitions, or misinterpretations of what the above-mentioned constructs denote (e.g.,
Rogers 2002;
Seng Tan 2004). There seems to be agreement on considering innovation to be a novelty applied to something that already exists. The disagreement arises as to whether the change should be new to the market in general, or only to a particular company (e.g.,
Välimäki et al. 2004). The former, denoted for the purposes of this discussion as the Frascati (Frascati Manual,
OECD 2002) approach, suggests that innovation is rooted in the notion of novelty in global terms. These novelties are assessed indirectly by the level of various educational attainment statistics (European Innovation Scoreboard,
European Commission 2005;
World Bank 2006; R&D expenditures EIS,
European Commission 2005; IUS,
European Commission 2011), and patent counts (e.g.,
Griliches 1990;
Khan and Dernis 2006). The latter, the Oslo Manual (
OECD 2005) approach, takes a more micro perspective. It deals primarily with the implementation and adaptation of solutions, and is oriented toward a practitioner’s viewpoint. This approach conceptualizes innovation as an application for commercial purposes.
Inventions often originate as a result of systematically undertaken research and development (R&D) activities. The following is a definition offered by the United Nations, which is also accepted by the Organization for Economic Coopearation and Development (OECD) in the Frascati Manual: “R&D is a creative work undertaken on a systematic basis in order to increase the stock of knowledge, including knowledge of man, culture and society and the use of this stock of knowledge to devise new applications The basic criterion for distinguishing R&D from the rest of Science and Technology is that there is an appreciable element of novelty” (
OECD 2002). “Technical innovation activities are all of the scientific, technological, organizational, financial and commercial steps, including investments in new knowledge, which actually, are intended to, lead to the implementation of technologically new and improved products and processes” (
OECD 2002), and that are crucial to a company’s survival (e.g.,
Jamison and Hård 2003). From the Frascati perspective, innovations are those solutions implemented in technologically new products/processes, or to products/processes, subject to significant technological improvements, that exhibit characteristics of novelty.
When such interpretations of innovation are accepted, then the majority of small and medium-size (SMEs) do not qualify as being innovative. These types of enterprises mainly imitate and adopt solutions. It is a very sound business concept. Next, inventiveness is only one element in the innovation process. R&D activities (leading to inventions) are only initial stages of the innovation process, which can be described in many different ways (e.g.,
Kline and Rosenberg 1986;
Betz 1987;
Nasierowski and Arcelus 1999). The concept of novelty in global terms is not emphasized in these models, and hence a weakened interpretation of novelty and innovation can be adopted. Innovations in an enterprise can be defined as an economic decision made in order to carry out tasks related to taking advantage of emerging market opportunities, or to prevent threats from materializing. Such decisions are often of strategic nature. They may have consequences for the competitive position of the company and to all aspects of its functioning; in short, they may bring profits. A similar interpretation is advocated by the Oslo Manual (
OECD 2005), where the minimum requirement for something to be termed an “innovation” is for the product or process to be new or substantially improved for the specific company.
Schumpeter (
Schumpeter 1949) defines the economic phenomenon of innovation as a process that takes an invention and develops it all the way to a marketable product or service that changes the economy. It can be conceptual or perceptual, should be related to opportunities, focused, and can be breathtakingly simple (
Drucker 1985). Innovation can also be interpreted as a process specific to a period of time or particular region, which means that the introduction of an “old technology” to the region, with no previous exposure to this technology, is also an innovation. For example,
Sajeva et al. (
2005) define innovation as “the process leading to the adoption and diffusion of new technologies, aimed at creating new processes, products, and services. While the term adoption represents the final stage of an invention, diffusion focuses on the supply of new goods and services to the customer. In this context, innovation is the method to achieve competitiveness in the framework of the revised Lisbon agenda.” Such a view is also consistent with the Europe 2020 Strategy.
Although such interpretations enhance discussions on innovativeness, the quantification of innovativeness or level of involvement in new activities remains a perplexing, multidimensional concept. One can advocate an indirect means for the measurement of innovations. For example, levels of productivity, employment, revenues, or the betterment of competitive position can be used to measure innovativeness. Further measures may include the examination of distinctive competencies, or of quality. Such indicators, however, depend on the context of operations, market conditions, actions undertaken by competition, economic and political situations in the region, reputation of the company, and customer loyalty. These may all have a strong impact on the results of so called “indicatoring” of innovation. Quantification of these processes is almost impossible in light of the diversity of possible contextual factors. We deal with very dynamic systems, and “many of their properties emerge from interactions among the entities in them” (
Katz 2006). Interrelationships between and among these factors of innovativeness are not documented, and the measurement of innovation processes may fail to provide evidence regarding casual relationships.
Another troubling issue in the study of technological change is differentiating innovation from creativity. Innovation can be defined as an output (product, device, theory, etc.) that is somewhat new to the place, time, or purpose of its application. Innovation occurs as a result of successful implementation of creative ideas within an organization. Creativity, on the other hand, is the development of a novel and useful idea in any domain and is a seed for all innovations (
Amabile 1997).
Innovation is always creative, but not all creativity is innovative. “In this view, creativity by individuals and teams is a starting point for innovation: the first is a necessary but not sufficient condition for the second”. In short, creativity is a manifestation of a drive to shape an opportunity, whereas innovation is an attempt to apply this opportunity practically. Creativity is a process, which may not lead to implementation. To that end, identification or development of creative ideas and an ability to implement them are among the most important abilities of successful entrepreneurs.
For many practitioners, “innovation refers to the development and improvement of products and processes arising from the exchange of knowledge among firms and other players in their environment” (
CEDO 2001). Such interpretations stem from the concept advocated by the Oslo Manual (
OECD 2005), where a minimum requirement of innovation is for a product or a process to be new (or substantially improved) for the specific company: it need not be new in global terms. Thus, innovativeness deals with the implementation of new solutions in the place or for the purpose, for which these have not been used earlier. Some public institutions also take a similar micro/practitioner’s approach. For example, the Atlantic Canada Opportunities Agency (ACOA) recognizes the fact that innovation means different things to different people.
In their terms, innovation is “a process through which economic value is extracted from knowledge through the generation, development, and implementation of ideas to produce new or improved products, processes, and services. Innovation encompasses much more than R&D or technological change. Innovation makes knowledge useful and turns it into wealth and prosperity.”
It has been observed that several items from the composite indexes, which may relate to the notion of innovativeness, deal primarily with inventiveness (e.g., on the Input side-expenditures on R&D and S&E graduates, or on the Output side—patents and trademarks). Thus, these indicators fall more toward the Frascati Manual’s interpretation of innovations (hence inventions) (
OECD 2002), quite a difference from innovations as interpreted by the Oslo Manual (
OECD 2005). Consequently, it is arguable whether these common composite indexes serve the needs of practitioners oriented toward the interpretation of the innovations of enterprises aimed at the improvement of economic prosperity at a “shop floor level” (
Drucker 1985), or are primarily a manifestation of pro-innovation policies and mechanisms at the macro-economic level.
Further difficulties lie awaiting researchers when they try to formulate plans for stimulating innovativeness and creativity as well as entrepreneurship enhancement, along with attempting to improve the economic performance of firms. As if this is not enough, differences regarding interpretations are further amplified when micro and macro-economic perspectives are taken into account. It is observed that two perceptions of innovativeness can be identified; they refer to the same phenomenon, though from varying perspectives. One deals with a macro-economic view, suitable for big inventive companies, and levels of innovativeness are measured by composite indexes. The second perspective is more “shop-floor” oriented and deals with problems of changing ideas into commercial success. The first is leaning toward inventiveness, the second toward commercialization. Micro- and macro-perspectives are somewhat different ‘worlds’—explained by state policies and international competitiveness determinants on one side, and a drive to increase competitive position and profits of an enterprise on the other. These two ‘worlds’ coexist, and more coordination of their principles and related activities may bring positive results. It would be incorrect to attempt to discuss the two as the same phenomena, and there is a need to identify means to bridge the gap between ‘macro’ and ‘micro’ perceptions and interpretations of innovation (
Nasierowski 2009,
2010a,
2010b). Hence, a comparison of concepts of innovativeness from the viewpoint of macro-economic indicators (e.g., as expressed by the EIS (
European Commission 2005)/IUS (
European Commission 2011)), with opinions/perceptions of entrepreneurs that will provide a micro-economic perspective to the problem (
Drucker 1985) is warranted. These considerations are expected to aid in finding better means to assist companies in enhancing their performance, thus contributing to economic progress at the macro-economic level.
The European Commission adopts a comprehensive approach to the definition of innovativeness and attempts to combine both macro- and micro-approaches. The term innovation not only describes innovation as an invention or technological improvement, but also includes the implementation of new ideas, processes, and methods for leveraging existing ideas, technologies, or inventions. Discussion is no longer limited to products, processes, or technologies (e.g.,
Kedia and Bhagat 1988; or spin-offs by
Arundel and Hollanders 2005), but also focuses on an overall replication of solutions that have been used somewhere else, or used for a separate purpose. The term innovation not only describes innovation as an invention, or a technological improvement, but also includes in its scope the implementation of new ideas, processes, and methods for leveraging existing ideas, technologies, or inventions further.
3. Practicalities of Measuring Innovations and Efficiency of Pro-Innovative Approaches
Even though diverse interpretations of creativity, innovativeness, and entrepreneurship may enliven possible discourses about their nature imperatives and effectiveness, it does not help find a reasonable way to measure them. For example, studies that make the tall claim of measuring innovation (or productivity of innovation generating units) by recording the number of patents, publications, etc. seem hollow and incomplete because they completely ignore the meaty qualitative dimensions of innovation, while excessively fixating on the quantitative dimensions. This leads one to advocate for an indirect means of measuring innovation. We can measure innovation by evaluating factors such as productivity, employment, revenue, or profit increase, improvement of competitive position, creating distinctive competencies, or quality (if such indicators can indeed be measured). However, these indicators depend upon a variety of factors such as the specific context of operations, market forces, actions undertaken by competition, economic and political influences shaping the particular region, company’s reputation, and customer loyalty, all of which may significantly impact the results of innovation measurements.
It is quite a task to measure the impact of innovation upon business performances given the insidious presence of market forces. Additionally, quantification of these processes is virtually impossible taking into account the diversity and numerous possible contextual factors. It is highly unlikely that companies will disclose information regarding their innovation related procedures, nor would they allow outsiders to observe their processes. Thus, the intimacy of the relationship between these factors will not be documented. Moreover, measurement of innovation processes may fail to provide evidence regarding a not regular relationship, which additionally may be of a non-linear character.
It is at times accepted that composite indexes may serve as a policy setting mechanism (which has also been one of the objectives of the EIS/IUS approach). However, recommended innovation policies should not be considered as “an average” of responses from different sectors, by companies of different size, which operate within very different economic, political, and social contexts. An assumption that “indicators have policy implications” is difficult to endorse. Presented observations suggest that countries should adopt different innovation policies. Consequently, the power of indexes as a tool that sets direction for policy formulation is substantially decreased.
Problems arise when using composite indexes also due to the conceptual quandary between allocative efficiency (‘are we doing the right things?’) versus technical efficiency (‘are we doing things the right way?’). Further dilemmas stem from problematic definitions and the various taxonomies used to measure the consequences of the output achieved (e.g.,
Seng Tan 2004).
Increases in innovation and the benefits that result from such an attitude are important factors in fostering economic activity and boosting competitive advantage. The vital role of innovation in national competitiveness is recognized by most nations. Knowing a nation’s strengths and weaknesses allows a government to institute interventions aimed at fostering its innovation record. Therefore, attempts to “measure” levels of innovativeness, along with the assessment of efficiency/effectiveness of pro-innovative policies, have been undertaken. One may identify two basic approaches to estimate effectiveness:
First, probably the most popular now, where the level of innovativeness is determined as a sum, or a ratio, of inputs and outputs to the innovation processes. In such a case, one may expect that the higher the input, the higher the output, and hence the higher the level of innovativeness. This is the underlying assumption of the EIS/IUS approach, and its associated composite index of innovativeness, probably the leading approach to measure levels of innovativeness in Europe. This concept has been “developed by the European Commission, under the Lisbon Strategy, to evaluate and compare the innovation performance of its Member States” (EIS, (
European Commission 2005)); and
Second, where the efficiency of organizations (systems, approaches) is denoted with the use of the “best practice frontier” concept; here, the distance from such a frontier represents inefficiency, in other words, the inability to produce maximum output from the given inputs. This approach is linked to the effectiveness approach to National Innovation Systems, the line of thinking about the issue initiated by
Nasierowski and Arcelus (
2003) and
Balzat and Hanusch (
2004).
4. The Characteristics of the Research and the Studied Enterprises
The analysis of the research findings was carried out by the authors based on the results of the evaluation research into the support for innovative enterprises–beneficiaries of the Smart Growth Operational Program (SMOP) for the years 2014–2020. The program was implemented by the Ministry of Investment and Economic Development of the Republic of Poland via Polska Agencja Rozwoju Przedsiębiorczości-PARP (Polish Agency for Enterprise Development). The program is addressed to innovative entities including enterprises (particularly those operating in the small and medium-sized enterprises sector), scientific and research units, and institutions of the business environment. The objective of the program is to support beneficiaries which as their strategic goal set their own growth or enhancement of the innovativeness level. In the first place, it concerns enterprises which through investments, development, and implementation of innovative products of services, or through cooperation with research and development units conquer new markets and improve their products (
MIiR 2019).
The subjective research was ordered by the Polish Agency for Enterprise Development and conducted by specialized units (MCN Institute Poland Sp. z o.o., Fundacja Idea Rozwoju, Idea Instytut Sp. z o.o., Exacto Sp. z o.o., Realizacja Sp. z o.o.), and its findings were published in the report entitled Barometr Innowacyjności. Program Operacyjny Inteligentny Rozwój (The Innovation Barometer, Smart Growth Operational Program) (
PARP 2018). In the article, the research findings are analyzed with regard to the objective of the article and the research gap identified in this respect.
The aim of the research was to identify the innovativeness level of the studied enterprises and the influence of innovativeness on the functioning and development of these enterprises and their adaptability in the environment. The study was based on research carried out by the Central Statistical Office (it is the only organization that is able to conduct a survey of this type on such a large scale in the country). The results of these studies were included in various reports and many reports of the Central Statistical Office—only then were they collected jointly by the authors of the article and reworked, from which one consistent synthesis was created.
Additionally, the authors relied on the measures and indicators proposed by the Central Statistical Office (providing the primary data) and did not want to interfere with them, treating it as unauthorized. This is the main reason why they were left in their original shape. The research was carried out with the use of the CAWI technique (Computer Assisted Web Interview) on the sufficient population of SMOP beneficiaries. In the invitation to the research, the beneficiaries obtained a link to online questionnaires and tips on how to complete them. During the research, the team of consultants (the help desk) provided technical and substantive support to respondents when needed. To maximize the response rate, the entrepreneurs who had not completed the questionnaire were contacted several times (an email and phone remainder). The research was carried out between 4 June and 5 July 2018 and primarily concerned the following issues:
The character of the innovations introduced,
Obtained co-financing,
Entrepreneurs’ experiences related to the patent procedure,
An influence of innovative projects on the revenues and gross profit level in the firms taking part in the projects, and
An influence of the implementation of innovative projects on the employment in firms participating in the projects.
Within the research, two measurements were taken: the first (initial) one referred to the assumptions of the projects implemented, and the second one (the final one) referred to the effects of the implementation. A total of 1238 enterprises were invited to participate in the survey. The average response rate for the first measurement was 45%, and for the other measurement, it was 19%.
Of the studied enterprises, the biggest number of them were located in the following voivodeships: Masovian (23%), Silesian (13%), Greater Poland (10%), and Lesser Poland (9%), whereas the smallest number of entities was from Opole voivodeship (0.5%), Lubusz (1%), and West Pomeranian (1%). As for the size of the enterprises, 38% were micro-firms, 34% were small firms, and 28% were medium-sized firms. A total of 6% of the studied enterprises were start-ups (0–2 years of activity), 28% were young firms (3–5 years of activity), and 66% were other firms with market activity longer than six years. According to the criterion of core activity, the biggest number of entities declared their activity in the industrial processing sector (57%), followed by the information and communication sector (13%), professional, scientific and technical activity sector (13%), wholesale and retail sale sector (12%), and construction sector (5%). With regard to the legal form of activity, 50% were limited liability companies, 21% natural persons conducting business activity, 12% joint stock companies, 7% general partnerships, 6% limited partnerships, and 4% others. Of the studied enterprises, 85% were manufacturers of a final product, 15% played the role of a supplier of a direct product, 9% were suppliers of a service for the manufacturer of a final product, 7% were an intermediate service provider, and 5% were suppliers of an intermediate product. Within the scope of Krajowe Inteligentne Specjalizacje-KIS (National Intelligent Specializations) classification (see Endnotes), the most frequently represented were: KIS 1: Health and society (13%), KIS 2: Innovative technologies of the agricultural and food sector (13%), KIS 14: Automation and robotics of technological processes (12%), KIS 12: Intelligent networks and ITC (12%), KIS 8: Minimization of waste production (10%), KIS 3: Biotechnology (8%), KIS 5: Intelligent and energy-efficient construction (8%), and none of the above (24%).
6. The Final Assessment of the Studied Enterprises (the Other Measurement-after the Implementation of Innovative Projects)
The final assessment, realized within the second measurement, was a leading assessment, fulfilling the main research aim. Therefore, it was made in the following research areas, referring to the studied enterprises:
6.1. Analysis of Innovativeness
The assessment of the innovative potential of the studied enterprises began from examining the resources necessary from the point of view of the implementation of an investment project. The results of this assessment are included in
Table 2.
Then, the analysis of innovativeness was conducted based on the following measures:
The ratio takes the maximum value of 10, if the firm planned innovations in the global scale and of breakthrough character, it planned to launch new products in the form of final goods and has a strategy of managing innovation in the firm. The minimum value of the ratio (0) is obtained by firms who do not plan any of the aforementioned innovations and have no strategy of innovation implementation.
Innovation scope ratio—the ratio was created as a weighted average of the scope of innovation (the national, the European, the global scope). The larger the scope of innovations, the higher the value of the ratio. The score of 10 is obtained by firms who planned global-scale innovations. Firms planning Europe-scale innovations obtain 5 points. Firms in the case of which the largest scope of innovations is nationwide obtain 1.5 points. We should remember the ordinal character of the innovation scope scale. A global innovation has at the same time the European and national scope, and the European-wide innovation is by definition an innovation of the national scope. Therefore, for example, world-scale innovators obtain an extra score due to the fact that their innovations are at the same time on the European and national scale. This additionally promotes the most innovative ventures undertaken by the studied entities.
Innovation character ratio—the ratio was created as a weighted average of the innovation character (evolutionary, derivative or breakthrough). The more the character of innovation changes the status quo, the higher the ratio value. The score of 10 is obtained by firms who planned breakthrough innovations. Firms planning derivative innovations score 5 points. Firms in the case of which innovations are of evolutionary character obtain 1.5 points.
Final goods ratio—the ratio was created as the average of the percentage of final goods out of product innovations planned by the firm. The ratio does not consider the number of planned product innovations being final goods, and only their percentage out of all planned product innovations.
The strategic management of innovation ratio—the ratio was created as the weighted average of firms declaring the possession of a strategy of the implementation of innovations in the firm. It takes values from 0 to 10. If a firm declares possessing such a strategy in the written form, it obtains 10. If a strategy exists but has not been written down, the firm obtains 5. If a strategy does not exists, the firm scores 0.
Table 3 presents the average values of the innovativeness analysis ratios for all the studied enterprises.
What arises from
Table 3 and from the research findings not published in the article is that a great majority of the studied enterprises are planning to introduce at least one innovation within their innovative activities. Every third innovation is supposed to be a European-scale innovation, and every fifth one a global-scale one. A total of 35% of the total number of respondents defined at least one of the planned innovations as a breakthrough one. The scale of filed applications for industrial designs or utility models as well as inventions, although it increased slightly in the years preceding the research, is still very low. In the years preceding the research, the activeness of the studied firms in the area of R&D increased (in comparison with the previous year), and the expenditure on research and development was conducted inside the enterprise. Two-thirds of the firms had capabilities (machines, devices) to conduct R&D works, and every third firm had its own infrastructure (separate buildings, premises) to perform such works. At the same time, the percentage of firms having a strategy including, among others, the problems of implementing innovations was 78%, 13% of which had a written, formalized strategy. The greatest strength of the studied enterprises as for the implementation of innovations is possessing adequate human resources, whereas the greatest weakness is possessing adequate financial resources. The lack of sufficient financial resources in the first place tackles micro-firms (26%).
6.2. Analysis of Competitiveness
During the survey before the commencement of the research (the first measurement), it was established that:
At the end of the research, within the second measurement, it was found that:
A total of 53% of the enterprises thought that the implementation of innovations positively influences the level of annual revenues, 20% pointed to no influence, and 0.5% to negative influence; and
A total of 46% of the enterprises thought that the project positively influences the profit level, 16% indicated no influence, and 6% indicated negative influence.
Within the research into the level of competitiveness of the examined enterprises, their sources of competitiveness were determined. The results of that survey are included in
Table 4.
Unique knowledge is the most frequently declared (as the most important) source of competitiveness of the studied firms. The second most important factor for competitiveness is proper price. At the same time, the price and possessing appropriate business reliability are factors that for some entrepreneurs are the third most important factors of their competitiveness.
Within the assessment of competitiveness, the synthetic ratio of competitiveness was also calculated, which was created as the average of the following components:
The percentage of firms declaring that carrying out the project has a beneficial influence on the level of annual revenues on the sales of products (goods/services), merchandise, and materials, and
The percentage of firms declaring that carrying out the project has a beneficial influence on the value of gross profit.
The ratio takes the maximum value of 10 if the firm assesses that the implementation of innovations beneficially influences those two ratios: 5 if it influences one of them, and 0 if it influences none of them.
The average value of this ratio for all the studied enterprises was: 4.1.
To sum up, it can be noted that in the initial measurement, the values of basic ratios describing the economic situation of the enterprises for the year preceding the research were determined. The picture achieved is static, in this stage of the research, there is no possibility yet to observe the dynamics of the economic ratios of the firms. In the year preceding the research, the entrepreneurs achieved revenues at the level of 14.5 million PLN on average. A total of 83% of the firms making revenues generated profit in that year, which is a value similar to the totality of national economy entities according to the Central Statistical Office. About a half of those firms already during the research marked (subjectively) a beneficial influence of the implementation of innovations on revenues and the level of gross profit.
6.3. Analysis of Employment
During the survey, it was established that:
The average employment level in the year of the commencement of the innovative project was 42 people (39% women), of which 90% were full-time,
The average number of people with whom civil law contracts were concluded was 1.5 people (no y/y change),
The average number of people employed in R&D activity was 0.8 person (no change in comparison with the previous year),
A total of 35% of firms thought that the implementation of the project translated into the growth of employment, and 34% thought that the project had no impact on employment, and
The change in employment (in the year of the project in comparison with the preceding year) was as follows: 56% increased their employment, 27% did not mark any changes in their employment, and 17% decreased employment.
Within the assessment of employment, the synthetic ratio of employment was also calculated, which was created as the average of the following components:
The percentage of firms increasing employment in the year preceding the year of submitting the application for co-financing the innovative project; and
The percentage of firms assessing that the implementation of the project causes an increase in employment.
The ratio takes the maximum value of 10 if the firm both increased employment and assigned the growth to the implementation of the innovative project; the value of 5 if one of those conditions occurred; and 0 if none of them occurred. The average value of this ratio for all the studied enterprises was: 4.6.
To sum up, we can claim that the studied enterprises employed 42 people on average. In the year of the implementation of the innovation, more than a half (56%) increased employment in comparison with the previous year (by 10% on average). The growth of employment was first of all declared by small and medium-sized enterprises as well as exporters (especially those which are small or medium-sized enterprises). On the other hand, the percentage of people employed in R&D activity did not change, and stayed at a low level of 0.8. Out of firms with their own infrastructure for R&D works, the average number of people employed in R&D activity was 1.5. Every third firm declared that the project implemented influenced an increase in employment, and a similar percentage of people thought that the project did not translate into an increase or decrease in employment.
6.4. Analysis of Internationalization
In the course of the research, it was found that:
The percentage of firms selling to foreign markets was 73%;
Exporters came most often from the following voivodeships: Masovian (19%), Silesian (11%), and Lesser Poland (11%);
The average length of the existence of an exporting firm was 12 years against the total number of respondents where the average was 11 years;
The average level of employment in an exporting firm was 51 workers against the total number of respondents, where the average was 42 workers;
The average time of conducting activity on foreign markets was eight years;
The average number of countries to which sales were made before the implementation of the innovation was 12;
The average value of sales revenues (export) per firm before the project was PLN 4.7 million, and after the project, it was PLN 5.4 million; including to European Union countries: before the project PLN it was 2.2 million, and after the project, it was PLN 3.1 million; and
The method of sales to foreign markets was as follows: independent 62%, mixed 32%, and via intermediaries 6%.
During the research, it was also found that a studied enterprise cooperated with 20 business partners on average including six from abroad (the average number of business partners for micro-firms is 11, for small firms 21, and for medium-sized firms 30). The median of the number of business partners was, however, four, which means that among beneficiaries, there is a division into a relatively small group of firms that cooperate with a large number of partners and a relatively large group of firms that cooperate with a small number of business partners. The number of business partners increases with the size of the enterprise.
To sum up, as many as three-fourths of the studied firms generated revenues on sales for export in the two years preceding the implementation of an innovative SMOP project. The percentage of exporters was distinctly bigger in the group of entrepreneurs who participated in a SMOP project in comparison with the total enterprises on the market. It also increased in each next range of the size of the firm’s employment (micro—57%, small—66%, and medium-sized—89%). Exporters are basically firms from the industrial processing sector and trade. Before the commencement of the project implementation, export revenues were growing year to year. In the year before the commencement of the implementation of an innovation, they constituted about one-third of the total revenues of the enterprise.
6.5. Analysis of the Administrative Environment
During the evaluation of the administrative environment, the quality, flexibility, and adequacy of the support provided to entrepreneurs with regard to carrying out projects of the implementation of an innovation within the SMOP program was investigated. The results of that evaluation are presented in
Table 5 and
Table 6.
Within the evaluation of the administrative environment, the synthetic ratio of the evaluation of the SMOP implementation system was also calculated. It averages detailed evaluations of the system (the process, procedures, and co-financing), made on a scale from 1 to 10. The average value of this ratio for all the studied enterprises was 5.2.
To sum up the analysis of the administrative environment based on the conducted research, we can formulate conclusions that relatively low scores occur in it, particularly with regard to the clarity of the procedures of the purchase of goods and services for the needs of the project and the clarity of the reporting system. The highest scores were obtained for the support from the project manager and the usefulness of the website (PARP), and lower scores were obtained for the usefulness of briefings and the functioning of the help desk.