Following Cohen and Levinthal’s (1990) original definition presented earlier, ACAP has three dimensions: acquisition, assimilation and exploitation.

In 2002, Zahra and George proposed a reconceptualization of ACAP, defining it as “a set of organizational routines and processes by which firms acquire, assimilate, transform and exploit knowledge to produce a dynamic organizational capability” (p. 186). This definition represents a departure from earlier studies through two aspects. First it includes a fourth dimension, transformation. It also combines the four individual dimensions into two supra-dimensions – Potential Absorptive CAPacity (PACAP as a firm’s ability to acquire and assimilate new external knowledge) and Realized Absorptive CAPacity (RACAP as a firm’s ability to transform and exploit this new knowledge).

More recently, ACAP has been defined as “a firm’s ability to utilize externally held knowledge through three sequential processes: (1) recognizing and understanding potentially valuable new knowledge outside the firm through exploratory learning, (2) assimilating valuable new knowledge through transformative learning, and (3) using the assimilated knowledge to create new knowledge and commercial outputs through exploitative learning” (Lane et al., 2006, p. 856).

While we borrow some aspects to these definitions – the dynamic perspective from Zahra and George (2002) and the recognition theme from Lane et al. (2006) – we do not strictly adhere to any of those for two reasons. First, Zahra and George’s (2002) definition does not take into account the ability to recognize and value new external information, an ability that is crucial to external knowledge acquisition. Second and opposed to Lane et al. (2006) and Todorova and Durisin (2007), the recognition that transformation is a distinct step between assimilation and exploitation is important. It highlights a knowledge conversion step before exploiting it. It also strengthens the dynamic capabilities perspective through the integration of organizational learning mechanisms based partly on transformative learning.

Consequently, we define ACAP as an embedded learning process that consists of four knowledge activities, that can be considered as dynamic capabilities: (1) acquisition based on recognition and valuation of new knowledge (it implies external and internal knowledge sharing mechanisms), (2) assimilation of this knowledge in the light of existing knowledge, (3) transformation of this knowledge by extending the firm’s current knowledge base, and (4) exploitation of this knowledge to deliver high value knowledge and commercial outputs. This definition differentiates from past research as it both separates and encompasses four different knowledge activities that an individual – as well as an organization – would realize. At an individual level, it stresses the importance of knowledge sharing. It also highlights the relevance of social interactions in the context of this research (Zhao and Anand, 2009). Composed of four different knowledge activities, this definition questions the complementarity between ACAP dimensions.

Operationalizing ACAP has proved a major problem for researchers. Despite twenty years of research, “most studies have operationalized ACAP with R&D-related proxies, such as R&D intensity or patents […] leading us to question whether these studies actually measured absorptive capacity at all” (Lane et al., 2006, pp. 854). There are three main limitations to the use of “objective” measures to study ACAP, which reinforce the relevance of this research.

First, proxy measures of ACAP have weak explanatory power compared with the complexity of the dimensions of the concept (Lichtenthaler, 2009). As proxies only measure one aspect of ACAP, a great majority of past studies are liable to attribute excessive importance to one dimension at the expense of the other dimensions – ACAP is not just about R&D intensity or number of patents. In addition, “knowledge-creation” proxy measures may lead to accuracy problems, and patents may reflect strategic positioning rather than real innovation (Spender and Grant, 1996).

Second, most ACAP measures were developed for large companies and are therefore totally inadequate for SMEs (Fernhaber and Patel, 2012). This is the case of most studies measuring ACAP by not using proxies (Szulanski, 1996; Jansen, Van Den Bosch & Volberda, 2005; Lichtenthaler, 2009). For example, because SMEs do not always have a specific R&D department, it can be difficult to assess the resources allocated to research activities. Patent registration is also frequently inapplicable, as many SMEs consider the patent process to be too expensive and time-consuming. What’s more, the absence of a R&D department or a patent registration policy does not mean that a firm does not acquire knowledge.

Third, a review of prior research into ACAP reveals major inconsistencies in the results of proxy-based studies. For example, some papers report that ACAP (R&D intensity) predicts interorganizational learning, whereas other studies found that it does not (Mowery, Oxley and Silverman, 1996; Tsai, 2001). Consequently, the suitability and validity of proxy measures for ACAP are highly empirically questionable.

A very small number of studies (Szulanski, 1996; Jansen et al., 2005; Flatten et al., 2011) have assessed ACAP using other kinds of variables, leading to the development of a measurement scale. Szulanski showed that a lack of absorptive capacity (a one-dimensional scale with 9 items) of the recipient is the first variable explaining internal stickiness, which prevents knowledge transfer. Jansen et al. (2005) found that organizations in dynamic environments improve their financial performance by increasing their PACAP (a two-dimensional scale with 9 items). Results for RACAP (a two-dimensional scale with 12 items) were more ambiguous. More critical is that the variables used in these studies account for a greater percentage of the variance than R&D intensity. Flatten et al. (2011) develop a reliable multidimensional measure of ACAP based on two surveys of German companies. These works constitute key references for this research. Thus, both past research shortcomings and the promising results of the few studies that measure ACAP not by using proxies, lead to a necessary and valuable new approach of the concept.

Given that our objective is to develop a new measurement tool of absorptive capacity, we believe that adopting a multilevel approach of the concept, with a focus on the individual, is an answer to five main issues.

First, although Cohen and Levinthal (1990) argued that organizational ACAP is a function of individuals’ absorptive capacities, it is rather surprising to note that no research has been conducted on an individual level. As Lane et al. (2006, p. 853) pointed out: “The lack of attention to the process aspects of absorptive capacity has also led researchers to overlook the role of individuals in developing, deploying, and maintaining absorptive capacity”. This is a major omission. This oversight must be rectified, as “individual cognition is a critical internal driver of absorptive capacity” (Lane et al., 2006, p. 857). In addition, academics emphasize the role of ACAP in promoting innovation and this aspect cannot be fully explored through a strictly organizational lens.

Second, Cohen and Levinthal (1990) believed ACAP to be an organizational level construct that resides in firms and organizational units. ACAP has been analyzed on country, interorganizational and organizational levels, but most studies have only considered it on an organizational level. As a result, they did not take into account the composition and the links of the different dimensions of ACAP (Zhao and Anand, 2009). It leads to consider it as a kind of supra concept, disconnected from practical learning strategies within firms.

Third, the richness of the concept and of the underlying dimensions cannot be included in proxy measures that are often one-dimensional. Moreover they do not really measure ACAP in our view, but more its outcomes (innovation, number of new products/services, projects initiated…) or maybe its antecedents (R&D investments...) (Flatten et al., 2011; Jiménez-Barrionuevo et al., 2011). Mainly adopting an individual approach of the concept enables to overcome this aspect in developing specific scales for the four dimensions that can reflect the different knowledge activities undertaken by individuals at each stage.

Fourth, as absorptive capacity has already been theoretically conceptualized as the capacity of individuals to acquire, assimilate, transform and exploit external knowledge flows, some academics (Mowery and Oxley, 1995; Veugelers, 1997; Mangematin and Nesta, 1999) have used measures related to firm’s human capital (number of scientists, doctorates, investments in training…). While these metrics highlight the relevance of developing an individual perspective of ACAP research, they do not really measure the four knowledge activities that composed absorptive capacity.

Fifth, ACAP literature has not brought yet connections between the different levels of analysis to our knowledge. A direct consequence is that scholars do not refer exactly to the same concept when studying absorptive capacity. This aspects breaks the unity of this research domain.

Building on these shortcomings we now present the development of our measurement tool.

Based on our definition we consider that absorptive capacity is composed of four distinct dimensions. Before describing our conceptualization of the construct, we present the composition of these dimensions in past research in table 1.

While several studies discuss their content from a theoretical point of view, very few papers develop a scale of ACAP in building each dimension separately. Consequently, there is no empirical validity of the following themes and components. However, this table presents at least a global vision of the richness and different aspects of the concept. It also grounds some bridges between ACAP and organizational learning literature. It reinforces the belief that a single one-dimensional measure is not appropriate to measure absorptive capacity. Following the same idea, Flatten et al. (2011) propose a table gathering numerous overlaps and similarities of ACAP’s dimensions with related research streams. However we differentiate from that research in adopting a more focused approach of ACAP.

Flatten et al. (2011) propose a thorough perspective of all domains linked to ACAP studies in presenting 29 related research streams, referring for instance to collective mind, team knowledge, innovation capability or even market orientation. This approach that can be considered as really valuable in a literature review perspective appears somewhere unusable in a scale development attempt. Indeed, due to the complexity and multiple research streams linked to the composition of each dimension, it appears totally impossible to develop a measurement scale that encompasses all the different conceptions and contributions of the fields presented in their table. Moreover, they apply all these related domains to the dimensions level, making more complex the building of each ACAP factor. Indeed it includes numerous overlaps and sometimes inconsistencies between the themes referring to the same dimension. For instance, when considering assimilation, it appears really difficult to practically refer to all the 15 related research streams – collective mind, information processing, knowledge creation, knowledge dissemination, knowledge exchange, market orientation in terms of intelligence dissemination, organizational memory, etc… – to build items having a kind of unity for this single dimension. For these reasons we adopt a more narrowed approach of the concept referring partly to Lane et al., (2006) in proposing to focus on three main research fields having strong links with ACAP literature: organizational learning, strategic alliances and the knowledge-based view. It leads to practically consider about fifteen papers that may be useful in developing a pool of initial items.

Thus, based on this literature review and our qualitative study, we build a measurement scale that departs from previous research in combining individual-level variables with one organization-level variable, thereby testing a multidimensional and multileveled approach of ACAP. This part is voluntary descriptive as very few scales were developed operationalizing these four dimensions.

Our conceptualization is in line with our individual approach of the concept, based on the fact that ACAP measurement at the firm level has brought elusive results in past research. Indeed, it not only depends on R&D investments but also on several others firm and/or individual attributes, such as the existence or effectiveness of communication channels, of knowledge processes (Godfrey and Hill, 1995; Jansen et al., 2005). Taking into account the specificities of our sample (size, scarce internal resources, etc…) reinforces the importance of knowledge sharing mechanisms when designing our measurement scale.

We embark on exploratory qualitative research in order to generate new insights of the concept at an individual level of analysis. The goal was to assess the items and to pretest the relevance of the questionnaire. This work makes part of a larger study dealing with mechanisms for promoting innovation and organizational learning. It was carried out on behalf of regional institutions and associations interested in the development of high-tech SMEs. It allows us to substantiate the content of the concept (Miles and Huberman, 1994) and second to get feedback about how the items spanned the theoretical space (content validity). From one hand, we realized roundtables with SMEs’ CEOs between the Club of Techno-Performing Enterprises (CETP) and regional institutions representatives. From the other hand, we seek reviews from professors and peers during doctoral workshops. Wording, theoretical consistency and managerial relevance were the main criteria for assessing an item during the two rounds of refinement. We also asked these persons to fill out the questionnaire in order to check out problems related to this operation.

Altogether, we collected data from a set of 28 CEOs, professors and doctoral students. It resulted in some changes in the building of our measurement scale during the different stages of scale pretest and refinement (Figure 1). From the first pre-test we deleted two items of the acquisition dimension. From the second one four items were removed from this dimension. These operations point out the sufficiency of acquisition that was reduced to ensure some unity in this learning activity, measuring only the outcome of knowledge recognition and valuation. Moreover, scales were refined to practically measure the content of each dimension. Some items were also rewritten to meet their requirements. Thus, an initial set of 27 items was summarized in 21 items to measure absorptive capacity. The 6 “recognition” items removed from the qualitative assessment are presented in Appendix.

We choose to focus on small and medium-sized firms because, when compared to larger firms, SMEs have relatively fewer resources such as skilled employees, revenue, or assets which are critical to innovation. Therefore they need to develop their absorptive capacity to counterbalance this disadvantage (Liao et al. 2003). This is especially true in high-tech industries. Thus, thanks to the support of the CETP and some regional institutions at the origin of the project, the present research focused on a group of French high-tech SMEs that were active innovators. We follow Liao et al. (2003) who indicated that high-tech SMEs are adequate to study absorptive capacity because it is a key driver for their growth. Beyond this aspect firms were selected on three global criteria in order to provide a kind of unity for the firms composing our sample: size, revenue and technological performance criteria.

First, we chose firms having between 20 and 250 employees based on the European Union definition that is much closed to the OECD one concerning small and medium-sized firms. Thus we do not include very small firms, i.e. less than 20 employees.

Second, all the firms pertaining to our sample do not have a turnover greater than 50 Million Euros. Based on these two first criteria, 19 “Techno-Performing” firms were chosen from the sample of regional institutions that include more than 50 firms.

Third, firms were finally selected according to some of the technological performance criteria used by the OECD to determine a firm’s “degree” of technology: R&D investment, sales per employee, sales growth and patents. From an initial sample of 19 “Techno-Performing” firms, 10 were retained as complying with the chosen technological performance criteria. These SMEs cover several different high-tech industry sectors, including automatic control, robotics, electronics, computing and telecommunications. In all these industries that are research intensive sectors of the French economy ACAP is considered as critical. Using these three global criteria allow to control for important differences between these companies, differences that may have an impact on absorptive capacity.

Thanks to the support of the CEOs, a meeting was organized in each firm to present the main objectives of the research. Thus, we had access to a representative sample of employees of all 10 firms. Sampling was realized with the CEO of each firm, keeping in mind the idea to mainly question employees concerned with knowledge absorption. In this respect, we give priority to senior executives and project/team managers within these 10 firms, all of them answering the questionnaire. The CEOs of these companies did not participate in this study for two reasons. First, they were part of the global regional project. Second, they participate in the pretest of this study consisting in roundtables to improve the questionnaire. Indeed, we consider CEO as a critical actor in terms of knowledge in their company and, for this reason, we prefer work with them in the questionnaire building and refinement than in the quantitative study. Moreover, the entire senior and project/team managers within these companies that have also a great knowledge of all their firms’ operations answer the questionnaire. These respondents were deemed to be the key decision makers in strategic, technological and market choices and qualified to speak about their firm’s operations.

At the time of the survey, eight firms out of the ten were less than 10 years old, while the two remaining companies were between 15 and 20 years old. In terms of size, nine firms had fewer than 100 employees, the remaining one employing between 150 and 200 people. In order to test the sample for informant bias, questionnaires were analyzed taking into account the hierarchical level of each respondent. Thus they have to indicate their position in their respective firm (senior executive, project/team manager, employees). From the final sample, 61 respondents were senior executives (financial, marketing, R&D directors for instance), 119 were project/team managers and 30 were employees, mainly responsible for administrative tasks (contracting, project assistance, logistics…). Analyses were realized by comparing responses coming from senior executives, project/team managers and from employees. No significant differences emerged between these three groups (individual items assessment display a narrow range) indicating that there was no bias. While we could expect some differences between the respondents, this result, putting forward by CEOs, could be explained from the fact that all of them display multiple roles and participate in the different projects within the firm.

Respondents were highly qualified, 86 % having a university master diploma (or more i.e. a doctorate) in engineering sciences. The rest of the sample is lightly less qualified with a two-year post-baccalaureate degree. Concerning tenure (job experience) 33 % of employees have less than 2 years, 37 % between 2 and 5 years and 30 % more than 5 years. The majority of respondents are in their first or second job experience. Many of them were in the firm since its creation. In terms of experience within the firm, 32 % have less than 2 years, 27 % between 2 and 5 years and 41 % more than 5 years.

Following the recommendations made by Van den Bosch et al. (2002), questionnaires were sent by email to all the employees of the firms in the sample. Of the 246 questionnaires completed and returned by the employees, 36 had values missing and therefore had to be discarded (we excluded questionnaires having missing values in order to prevent from approximation bias), giving us a sample of 210 valid questionnaires. In order to ensure confidentiality, employees were asked to mail the questionnaire to us directly rather than sending it via their company’s headquarters. All the items (description in Table 2) were measured on a seven-point Likert scale, ranging from 1 (strongly disagree) to 7 (totally agree). Finally, as the data were collected from a single informant and survey instrument, we applied the single-factor test to check for common method bias (Podsakoff, MacKenzie, Lee, & Podsakoff, 2003). This procedure based on principal components factor analyses indicated that several factors emerged. None of them accounted for the majority of the co-variance. It suggested that there was no problem coming from common method variance in our data.

The first step in this process was to check the reliability of our scales. Construct convergent validity and discriminant validity was assessed using exploratory and confirmatory factor analysis. Content reliability was checked during doctoral workshops and roundtables with SMEs’ managers. The theoretical space of each concept, the structure of the questionnaire and the formulation of the items were analyzed taking into consideration both theoretical and managerial issues. This aspect provided preliminary support for the content validity of our ACAP scale. Discriminant validity was analyzed in four ways. First, cross-loadings values (the largest loading of an item on one of the three remaining factors) have to be negligible (values lower than 0.3 support it). Second, the model fit is assessed: low modification indices and standardized results suggest no changes in correlations or loadings, and thus confirm discriminant validity. Third, the average variance extracted within factors was compared with the square of the bivariate correlations between factors (Fornell & Larker, 1981). Fourth, to assess the discriminant validity of the measures a three-dimensional confirmatory factor analysis was also performed using AMOS (more details below).

When conducting multilevel studies, academics need to be explicit about how data collected at one level of analysis are related to constructs at a higher level of analysis. This aspect is quite clear for absorptive capacity as already mentioned. We follow the compilation aggregation principle for identifying the relationship between lower-level data and higher-level constructs. Thus we use simple descriptive statistics to represent the processes that associate lower-level data with higher-level constructs (Hitt, Beamish, Jackson and Mathieu, 2007). Another condition is that the level at which data are analyzed should be aligned with the level of theory for the constructs involved. However, we are in extreme circumstances with absorptive capacity in the way that there is a great consensus considering that ACAP emerges at the individual level while nearly all empirical studies to date are realized at the organizational level. Our individual approach of the concept lies in the decision that most dimensions are based on individual behaviors. Moreover, we do not aggregate the last factors as it reveals individuals’ perceptions of knowledge firm intensity.

As little research on this concept has directly treated it this way, we attempt to integrate some of the critical issues surrounding multilevel phenomenon (Chan, 1998; Klein, Dansereau and Hall, 1994; Klein and Kozlowski, 2000). As Cohen and Levinthal (1990) point out absorptive capacity becomes a higher-level phenomenon through interactions between individuals and groups within the organization. In order to adopt a multilevel approach of this concept we follow Klein and Kozlowski (2000) compositional bottom-up process, which describes phenomenon that are mainly the same as processes emerge from lower to higher-level phenomenon. First, they argued that multi-level theories originate from the level at which the criteria are believed to reside. That’s the positioning we adopt to study absorptive capacity. Indeed, absorptive capacity developed from the perceptions and cognitions of individual employees based on the processes and mechanisms that encourage knowledge absorption within the firm. Even if absorptive capacity has been conceptualized as an organizational variable, it takes its origin in individuals’ actions, and it is through exposure to similar organizational practices and routines related to knowledge absorption that members develop a common assessment of absorptive capacity. Second, Klein and Kozlowski (2000) posited that theorists should articulate the level of predictor constructs and the processes by which higher-level constructs form and are related to the focal outcome(s) of interest. Demonstrating agreement across individuals within the same company regarding the development of absorptive capacity is a way to tackle level of analysis issues through a compositional bottom-up approach. In our view, absorptive capacity outcomes can only be understood by a careful measurement of the subcomponents of this concept at the level of individual actors. In this respect, the qualitative pre-test work helps identify and specify the processes and mechanisms by which absorptive capacity develop.

From a technical point of view, a multi-level analysis requires a separate and independent measurement for the higher level phenomena. We try to tackle with the problem of consistency between different levels through three ways. First, we measure the difference between respondents within the 10 firms of our sample through Levene and t-tests. Results show really weak differences between the ten organizations. Values for the Levene and the t-test are high what indicate that there are no significant differences between the respondents. Moreover the confidence interval displays the value 0, what confirms that the means difference is not significant. Moreover, it is important to indicate that differences are still weaker if we consider the assessment on every single organization. Second, we follow the recommendations for scale development from Churchill (1979) that partly takes into consideration this problem. Third, we employ in combination two data collection procedures in combining qualitative and quantitative surveys (Dansereau and Yammarino, 2005). It allows to limit the problem of compliance between multiple level of analysis.

Reliability and exploratory factor analysis was performed with SPSS. Reliability was assessed using exploratory factor analysis, which evaluates the fit of items in a scale and helps to identify factors of correlated items. The 21 items were subjected to a principle component analysis with varimax rotation (Table 2). Only items with a factor loading greater than 0.40 were retained in the analysis (below this threshold it does not well represent the underlying content). Cronbach’s alpha was used as an internal consistency reliability indicator. This was followed by a confirmatory factor analysis using the AMOS software. By carrying out structural equation modeling after a principal component analysis, it is possible to assess the content of a questionnaire and to determine the best factorial structure in terms of adjustment to empirical data. In this perspective, we follow Gerbing and Anderson (1988) and Burton et al. (1998) who recommended that conducting a confirmatory factor analysis is necessary and the best way to establish the unidimensionality of the concepts understudy.

Therefore three different conceptualizations for testing complementarity between ACAP dimensions are tested (Becker, Klein & Wetzels, 2012): ACAP as a unified concept, i.e. a one-factor model, ACAP as a two-factor model referring to Zahra and George (2002) conceptualization: PACAP and RACAP and ACAP as four separate dimensions, i.e. a four-factor model. This procedure is all the more justified in our study for two reasons. First, the concept of ACAP is not stabled from a dimensionality perspective. Indeed, should we consider ACAP as a single four-factor model? Does the proposition of Zahra and George (2002) of a two-factor model with PACAP and RACAP is preferable? Or, lastly, can we consider that the four underlying activities that are really different in nature constitute four single factors, not directly linked the one with the other? Second, Andrews et al. (2004, p. 115) indicated that they “specified the individual items used to assess each theme as manifest indicators of their respective first-order factors”. We also find the same testing procedure in Lynch et al. (2010) who specified that all the analyses may be applied to the overall first-order factor and, in case, to the underlying dimensions. Our testing procedure tries to answer partly to this internal issue dealing with complementarity between the four dimensions.

Convergent validity was assessed using two complementary criteria: a significant t-statistic for each item level path (t > 1.96 and p < 0.05) and a path loading greater than twice the standard error (Fornell and Larcker, 1981). All four ACAP dimensions passed both convergent validity tests (Table 4). The quality and validity of the scales was checked using six adjustment indicators: χ²/df, GFI, AGFI, SRMR, RMSEA and CFI. The χ²/df is indicated but, as this measure is subject to sample size and items number effects, no major consideration should be given to it. Values of GFI and CFI greater than 0.90 and for AGFI greater than 0.80 indicate a good model fit (Pedhazur and Pedhazur Schmelkin, 1991). Considering the SRMR, values lower than 0.08 report an acceptable fit (Hu and Bentler, 1999). For the RMSEA, Browne and Cudeck (1993) indicate that values lower than 0.05 indicate a good fit, that values of 0.08 represent reasonable errors of approximation and that with values greater than 0.1 the model must be respecified. The results of the principal component analyses are presented first, followed by the results of the confirmatory factor analyses. Three different conceptualizations for analyzing ACAP dimensions’ complementarity are tested: ACAP as a unified construct, ACAP as a two-factor model (Zahra and George, 2002) and ACAP as four separate dimensions.

The first analysis examined the global ACAP model. The results of the principal component analysis showed good reliability for the global ACAP scale. Extraction through a varimax rotation provided four factors that conformed to our expectations and to previous ACAP conceptualizations (Table 1). Total explained variance was also satisfactory. All items loaded significantly on four different factors, strongly corroborating the multidimensionality of the absorptive capacity concept (Table 2).

A confirmatory factor analysis was conducted in order to investigate the global ACAP model and to examine the structural relationships between the four dimensions. It should be noted that a second order model could not be validated because of weak regression weights (< 0.5). It questions the complementarity of the dimensions. In addition, although ACAP achieved a satisfactory Rho (0.85), the results of the confirmatory analysis were ambiguous. Satisfactory values were obtained for GFI and AGFI, but the RMSEA was not significant and the CFI value was weak (Table 3).

The next step was to analyze the classic PACAP/RACAP model (Zahra and George, 2002), in order to determine its validity and to further investigate the relations between the four dimensions. Principal component analysis showed satisfactory results for both PACAP and RACAP. Cronbach’s alphas for PACAP and RACAP indicated quite good internal reliability. Total explained variance was acceptable.

However, the confirmatory analyses were less positive. Although the results for RACAP were acceptable (Rho = 0.50), they were poor for PACAP, which gave a very weak Rho (0.10) and a non-significant RMSEA (Table 3). A second order model did not emerge. Therefore, the results for the PACAP and RACAP scales were ambiguous, questioning here the empirical suitability of this conceptualization.

As noted above, second-order models could not be validated because of weak regression weights. Taking into consideration this point it appears quite usual to check the reliability and unidimensionality of the underlying factors within a global model.

The scales are satisfactory with Cronbach’s alphas for internal consistency indicating very good reliability for all dimensions (Table 2). However, when using a varimax rotation, two items of the transformation phase did not appear in the same dimension as the other four items. In addition, the rotated component matrix gave very different values for these two items compared with the others. Consequently, these two items were removed from the transformation scale leaving four items to be considered in all analyses (see Appendix for the two deleted items). The total explained variance for each factor was also high.

The confirmatory analyses indicated that the scales for the ACAP dimensions are reliable (acquisition, Rho = 0.89; assimilation, Rho = 0.89; transformation, Rho = 0.88; exploitation, Rho = 0.87). All the statistical tests gave satisfactory results (Table 4).

Taking into account the results of the confirmatory analyses, it appears that the four-factor model is superior in comparison with the two other operationalizations. It calls into question in high-tech SMEs both the concept of ACAP as a unified construct, at least for measuring it, and the classic division of ACAP into two subsets.