Pure neo-classical Market competition is an ideal (Demsetz, 1967), in which price is the only competitive signal used by firms to produce the quantity of goods leading to a stable equilibrium at the margin. Rivalry between individual firms or pairs of firms is not identified and is not central to the neo-classical economics theory. The same holds for Industrial Organization theory which focuses primarily on Market structure (Bain, 1951), industry attractiveness (Porter, 1980) and economies of scale and scope (Chandler, 1990). Similarly, the New Institutional Economics research does not focus on rivalry between firms. Institutions of the Environment create the rules of the game and incentives for firms in general (North, 1990). The norm of transaction costs economizing is prescribed to strategists of firms for their choice between alternate and discrete Institutions of the Economy for transaction attributes identical for all firms (Williamson, 1985, 1991a and 1991b). Populations ecology theory (Hannan and Freeman, 1977) looks at firms as competing for an overall pool of resources in their quest for survival, not face to face rivalry. The resource-based view (Wernerfelt, 1984; Barney, 1991; Amit and Shoemaker, 1993) shares part of the focus of the Ecology of populations and adds the need for firms to benchmark the position of their resources and capabilities relative to competitors (Grant, 1998). All these theories look for a best or better solution. They are not interested in the complexity of strategic maneuvering for geographic territories, products, clients, technologies, resources, capabilities and allies. They do not focus on the attack/response pattern of face to face competition to gain and sustain a competitive advantage against individually identified rivals (Karnani and Wernerfelt, 1985).

Contrary to above theories, two different theoretical contributions emphasize the dynamics of competition between firms, from mutual forbearance to all out rivalry. One of the oldest comes from the German sociologist Simmel (1923, 1950). For Simmel, psychological characteristics are at the same time a precondition and a result of social and economic interactions. Individuals belonging to the same group tend towards similar behaviors revealing and reinforcing their group identity. Thus, Simmel expects non calculative tacit cooperation between firm strategists, including forbearance, a form of mutual social restraint. To borrow an analogy with competition for survival in the world of animals: “wolf does not eat wolf” coincides with “the survival of the fittest”. The second theoretical contribution owes to Edwards (1955) calculus based view that entrepreneurs have little interest in a prolonged overall rivalry because it would destroy the profit potential of their industry, while forbearance based upon deterrence is a positive sum game. Combining Simmel’s and Edwards’ theories, competition may, hence, be viewed as a mix of outright face to face rivalry and forbearance.

Building upon Edwards’ (1955) and Baum and Korn (1996, 1999) theories depicting the effects of multi-point competition on rivalry and forbearance, this study examines the dynamics of multi-territory competition occurring in the European airline industry. More specifically, we investigate the inverted U shaped relationship between multi-territory and rivalry as reflected by entries into and exits from the territory (air routes between city pairs) of a competitor. We prefer the concept of territories to “Markets” used in most previous research because of the confusion created by the different meanings of the latter. Indeed, “Market” has quite distinct senses for neo-classical and Transaction Costs economists, but also for Strategic Management, Marketing and Geography scholars. Our findings provide evidence that the mix of rivalry and forbearance exists for European airlines and could be part of a universal form of competition between firms.

Our paper is structured in four main sections. First, we review the theoretical and empirical literature on multipoint competition and suggest a set of hypotheses linking multi-territory competition and rivalry in the context of the European airline industry. Second, we describe the research methodology employed in this paper. Third, we present the statistical models estimated as well as main findings relating to rivalry and forbearance between European airlines. Finally, we highlight the main limitations of our study and propose a research agenda relating to possible future comparisons of rivalry and forbearance between airlines of different countries.

Theoretical models of multipoint competition are based upon the calculus assumptions of Edwards (1955). Firms are considered to be fully informed, with a long term survival and short term profit orientation and an ability to coordinate their actions between their operational units for attacks and/or responses. Most empirical work examining American airlines use the assumptions above. Edwards (1955) set the ground for the frequently tested hypothesis of the inverse relationship between the number of contacts between firms and the intensity of rivalry, predominantly called the forbearance hypothesis: the higher the number of multipoint contacts, the higher the propensity of forbearance.

Karnani and Wernerfelt (1985) provided the most detailed theory specifying characteristics of firms and industries as well as possible outcomes of tit for tat attacks and responses in conditions of multipoint competition between firms. Their model predicts attacks and responses according to four characteristics of the attacking firm and five for the incumbent. For the attacking firm, they consider: sales volume of the incumbent, industry entry barriers, synergies with existing territories and ability to retaliate by the incumbent. The incumbent can retaliate in function of the four criteria above plus the attractiveness of the attacker’s territory. When attacked, the incumbent has four choices: 1. no response, 2. defense on his own territory, 3. retaliation on one or several territories of the attacker, 4. total war on all the attacker’s territories. Karnani and Wernerfelt (1985) predict that responses 1 and 4 will be rare because they signal causes of potential disequilibria: weakness and invitation to further attacks for the first response and risks of destruction of the attractiveness of the industry, including bankruptcies for the competitors within the dyad and eventually outside for total war. Response 2 obtains when the incumbent is protected by high industry barriers, low sales volume and resources utilized (thus the amount of profits in jeopardy is low), the synergy with other territories is high. Response 3 (partial retaliation) is based upon the opposite reasons to response 2: low industry barriers, high profit stake (high sales and resource utilization) and low synergy with other territories. As partial retaliation has a higher potential to signal future retaliations by the incumbent in case of further attacks than response 2, they predict it will be the response most frequently chosen by competing firms.

In the same year of publication of the Karnani and Wernerfelt article, Hamel and Prahalad (1985) extended the model to competition between firms on a global scale. As a result, Hamel and Prahalad (1985) suggest that multinational corporations set footprints in the home territories of their main global competitors as well as third territories to signal their ability to retaliate in case of an attack on their home base, where they usually have a combination of large market share, large investments in resources and thus a large share of their global profits. These proactive moves were instrumental in speeding up the spread of global competition with mutual forbearance concerning the home base spheres of influence of the leading competitors.

However, early empirical research testing Karnani and Wernerfelt theory in the American airline industry were disappointing. Indeed, Smith and Wilson (1995) found that 67% of the incumbents under attack did not respond, 9% went for total war, a total of 76% for the two least expected responses. Partial retaliation, the response most highly expected occurred in 15% of cases only and defense on the home territory 5%. These unsatisfactory results may come from the lack of validity and reliability of the manifest variable used to measure the concept of resources. They may also be explained by the fact that setting footprints in the airline industry is much harder to establish than other less regulated industries. This difficulty is even stronger in the context of the European airline industry. Indeed, obtaining a time slot, i.e. the right to fly on an air route between two airports at a scheduled time, requires the formal agreement of a committee staffed with national (as opposed to European) air transport bureaucrats and representatives of existing companies. They have an extremely slowly receding informal practice of favoring national carriers. Cabotage is practically unheard off. As it would require high up-front investments in airport supporting facilities, companies have little incentive to challenge the decisions of these committees in front of European courts.

To improve the understanding of the dynamic effects of multimarket competition on the pattern of rivalry, Chen (1996) added the similarity of resources to the commonality of territories covered. In the context of the airline industry, resources which grant valuable differentiation include attractive landing time slots, being a member of a global alliance network, airport hub domination and all costly to redeploy up-front investments such as hub facilities in the main airport(s) [2]. Even though aircrafts represent a kind of resources, they can however be redeployed at low cost for other routes or sold on a second hand market. Thus, they are not generally accounted for in the concept of similarity of resources in the airline industry. Combining the two dimensions (1) similarity of resources and (2) commonalities of territories, enriches the analysis of the unique characteristics of each firm and competitive interaction within a dyad. More specifically, juxtaposing the two dimensions Chen (1996) predicted four situations described in figure 1.

First, low similarity of resources combined with low commonality of territories will result in the lowest level of rivalry: firms have neither incentive nor resources for face to face rivalry. Second, low common territory coverage combined with high similarity of resources increases the ability of response of the incumbent. However, provided that the attacker knows it, the latter is likely to forbear and bring the level of rivalry close to the first situation. The attacker’s forbearance may not be complete if he wants to print a footstep signaling the presence of local resources for potential future retaliation. Third, when the number of common territories as well as similarity of resources is high, the probability of rapid response by the incumbent is the highest and thus the probability of forbearance by the potential attacker. Fourth, a high level of common territories combined with strong dissimilarity of resources provides an incentive for attack by the rival who believes he has superior resources and his opponent a low ability to retaliate. The last situation can provide the highest level of rivalry amongst the four situations specified by Chen (1996).

The four situations proposed by Chen (1996) have not been tested as such. Gimeno (1999) provided strong empirical support to the staking of spheres of influence from their hub relative to those of their main competitors by American airlines between 1984 and 1988. This extension of their territories and resources from their main base created credible and reciprocal threats between rivals and moved them to the third situation analyzed by Chen (1996) and leading to an increase in mutual forbearance. Their strategic moves follow the most likely response on one or several territories of the attacker predicted by Karnani and Wernerfelt (1985) and recommended by Hamel and Prahalad (1985). The concept of spheres of influence (Gimeno, 1999) proves to be a better predictor of rivalry and forbearance than industry characteristics (Smith and Wilson, 1995).

Undertaking tests of complex models such as those coined by Karnani and Wernerfelt (1985) or Chen (1996) is quite challenging, especially that initial attempts were disappointing (Smith and Wilson, 1995). Indeed, early testing of the linear effects of multimarket competition on rivalry and performance in the empirical settings of the US airline industry (Sandler, 1988) and the US financial services industry (Alexander, 1985; Rhoades & Haggestad, 1985; Mester, 1987) revealed that the magnitude of such effects are non-significant. In contrast, empirical support for the linear impact of multimarket competition on rivalry and performance has been recurrent in more recent studies, although not unanimous (see Jayachadran and al. 1999 for a review). For instance, in the context of the US airline industry, Baum and Korn (1996), Gimeno and Woo, (1996), Miller (2010), Prince and Simon (2009) and Singal (1996) found that multi-routes contacts reduce, in a linear fashion, the level of rivalry as reflected by increases in fares and decreases in the quality of service (e.g. delays, etc.). In contrast, Zhang and Round (2009) study indicates that increase in multimarket contact between Chinese airlines in the period 2002-2004 did not result in higher airfares in Chinese city-pair markets. Furthermore, Bilotkach, (2011) found that multimarket contact between US airlines has an effect on their flight frequency decisions, although this effect has diminished over time. Finally, other recent studies have shown that the consequences of multimarket contact on rivalry are observable in the context of industries other than the airlines, such as the US newspaper industry (Fu, 2003), the pharmaceutical industry (Guedri & McGuire, 2011) and the insurance industry (Greve, 2008).

In this paper, we suggest a more complex pattern than the linear relation between the level of multipoint contact and rivalry tested in most previous research. Indeed, unlike most previous studies, which measured rivalry through market share stability, price levels, performance or collusion, and building upon population ecology theory (Hannan and Freeman, 1977), we examine rivalry through the lenses of rates of entries to and exits from competitor territories. We view the interactions of contacts on multiple territories and forbearance behavior in the perspective of two distinct periods in the history of competitive interactions within a dyad (Baum & Korn, 1999; Haveman & Nonnemaker, 2000; Stephan et al., 2003 Fuentelsaz & Gomez, 2006). First, when territory overlap is low, attackers can be attracted by several new territories and incumbents willing to counterattack on third territories to signal their willingness to respond mildly and/or more aggressively on the home base of the initial attacker to create a position of mutual hostages. Once initiated, this pattern of attacks and responses can escalate as long as the potential for a complete territorial overlap is not exhausted. This process of increased rivalry helps competitors observe and understand each other’s competitive behavior. Second, once territorial overlap and mutual learning are high, firms are prevented from further entries in each other territories by the prospect of benefits of future escalation becoming unworthy of the risks of mutual destruction. Forbearance obtains together with recognition of stable dominant/subordinate patterns. Such a historical modeling of the competitive relation within the competitive dyad leads to hypothesize an inverted U-shaped relation between a firm’s rate of entry in competitors’ territories and the level of multipoint contact.

Our rationale for exits is basically symmetrical. At the outset, when multipoint contact is low, exits signaling weaknesses or subordination are rare. When the number of attacks and multipoint contacts increases, so is defense through lower prices or counter-attacks. Increasing exits by losers or incumbents willing to signal a subordinate position on selected dyads follows, eventually to call for an exchange from subordinate to dominant position on other dyads. In the process, firms increase their learning of each other competitive behavior. When reaching a moderate level of multipoint contacts, exit rates attain their maximum. Afterwards, the increase in multipoint contact does not necessarily offer the possibility to find additional exits. Firms want to show the limits of their exiting behavior and their willingness to increase their level of subordination or domination. Thus, forbearance and competitive stability follow. Accordingly, we hypothesize an inverted U shaped relation between the rate of exit of a firm from the territories of competitors and their level of multipoint contact. Hence, we suggest the following hypotheses:

Hypothesis 1. The relationship between the rate of entry of a European airline into a competitor’s territories and the level of multi-territory contact with the competitor exhibits an inverted U-shape.

Hypothesis 2. The relationship between a European airline rate of exit from a competitor’s territories and the level of multi-territory contact with the competitor exhibits an inverted U-shape.

Given the nature of our two dependent variables (1) airline’s rate of entry into a competitor’s routes and (2) airline’s rate of exit from a competitor’s routes, we used negative binomial regression models to test our two hypotheses. This technique is suitable for estimating models predicting the number of discrete occurrences of some events, in this case, entries to and exits from focal routes. Negative binomial regressions were preferred over poisson regressions because they correct for overdispersion, that is, when data variance exceeds the mean (Barron, 1992). The examination of the distribution of count measures in our data revealed the presence of overdispersion (at p <.05), which justified the need to use binomial regression models. In addition we used White’s (1980) heteroscedasticity adjusted standard errors (robust standard errors) to correct for heteroscedastic residuals. Data analysis is based on 4154 market entries (5454 competitor- dyad-semesters) and 4139 market exits (5464 competitor-dyad-semesters).

Tables 3 and 4 report unstandardized negative binomial regression coefficients, robust standard errors and incidence rate ratios obtained by exponentiating regression coefficients. Models 1 and 3, the baselines, includes all controls variables pertaining to demand, load factors, alliances, airlines’ age, size, international focus, country of origin, number of rivals, number of past entries and exits, route dominance, characteristics of routes served and available to be served, competitor’s relative size, multimarket contact with other competitors and seasonality. Models 1 and 3 indicate that several control variables have statistically significant impacts on airline’s rate of entry into and exit from a competitor’s markets. In particular, airline i rates of entry into and exit from a competitor’s j route are lower if both airlines i and j are partners in codeshare agreements (beta = -0.545; p<0.01 for entry; beta = -0.404; p<0.05 for exit). This result suggests that strategic alliances mitigate the extent of competitive entries and exits in the industry. Similarly, models 1 and 3 suggest that the older the airline i the lower its rates of entry into and exit from routes served by competitor j (beta = -0.017; p<0.001 for entry; beta = -0.005; p<0.05 for exit). This result suggests that airline aging is associated with some inertia in terms of rates of entries and exits. In contrast, airline size seems to have opposite effects on the rates of entry and exit. Indeed, the larger the airline i the higher its entry rate into routes served by competitor j (beta = 0.282; p<0.001). On the contrary, the larger the airline i the lower its exit rate from routes served by competitor j (beta = -0.333; p<0.001). This result indicate that large airlines, which have superior access to resources, are able to initiate an extended scope of attacks (more entries) and are better able to defend their positions (less exits). Models 1 and 2 also indicate that airlines’ international focus has significant effects on entry and exit rates. More specifically, the larger competitor j international focus the lower airline i entry rate into routes served by competitor j (beta =-0.438; p<0.05). Furthermore, the larger airline i international focus the lower its exit rate from routes served by competitor j (beta = -0.921; p<0.001). Interestingly, models 1 and 2 suggest that rates of entry are higher if airlines i and j belong to the same country of origin (beta = 1.142; p<0.001) while co-nationality does not impact significantly rates of exit. Moreover, models 1 and 2 suggest that competitive attacks initiated at period t-1 trigger several counter-attacks at subsequent period t. For instance, the larger the number of entries undertaken by competitor j into routes served by airline i at period t-1, the larger airline i rate of entry into routes served by competitor j at period t (beta = 0.029; p<0.05). In addition, models 1 and 2 indicate that airline’s route dominance mitigates the extent of subsequent entry and exit. Indeed, the higher the percentage of routes on which airline i meets competitor j and in which airline i is dominant (has the largest share) at period t the lower airline i rates of entry to and exit from routes served by competitor j (beta = -0.004; p<0.001 for entry; beta = -0.005; p<0.001 for exit). Moreover, the higher relative multimarket contact, defined as multimarket contact between airline i and competitor j divided by average multimarket contact airline i has with other competitors than j, the higher airline i rates of entry to and exit from routes served by competitor j (beta = 0.106; p<0.001 for entry; beta = 0.177; p<0.001 for exit). Finally, rates of entry into routes served by competitors are significantly lower in summer semesters than in winter semesters (beta = -0.810; p<0.001).

Model 2 provides a test for the U-inverted shape relationship between the level of multi-market contact and airline’s rate of entry into a competitor’s routes. This test is accomplished by including in the model the variable measuring the level of multi-market contact between airlines i and j (MMCij x 100) and the squared value of this variable. Results presented in model 2 do provide support for such a curvilinear relationship since the coefficient for the squared term is statistically significant at p<0.001. Indeed, the coefficient for variable “MMCij x 100” is positive (beta= 0.174) and statistically significant at p<0.001 while the coefficient for the squared term “(MMCij)² x 100” is negative (beta= -0.670) and statistically significant at p<0.001. Moreover, the two goodness of fit indicators Pearson Chi² and Log Likelihood improved significantly after including the linear and quadratic forms of the variable “MMCij x 100”. Thus, hypothesis 1 is supported.

Model 4 illustrates the results of negative binomial regression testing the U-inverted shape relationship between airline’s rate of exit from a competitor’s routes and the level of multi-market contact with the competitor. Again, our findings do provide support for the U inverted shape relationship as the coefficient for variable “MMCij x 100” is positive (beta =0.213) and statistically significant at p<0.001 while the coefficient for the squared term “(MMCij)² x 100” is negative (beta= -0.871) and statistically significant at p<0.001. Moreover, the two goodness of fit indicators Pearson Chi² and Log Likelihood were enhanced significantly after including the linear and quadratic forms of the variable “MMCij x 100”. Hence, hypothesis 2 is supported.

Figure 3 presents graphically the relationships between multimarket contact and rates of entry to and exit from competitor’s markets suggested in hypotheses 1 and 2. The two curves indicate that inflection points for both entry and exit occur at relatively low levels of multimarket contact (MMCijt = 0.129 for entry and MMCijt = 0.122 for exit) [4]. That is, the effect of multimarket contact on airline i’s rates of entry to a competitor’s j market is positive when multimarket contact between airlines i and j ranges from 0 to 0.129. Beyond this level, any increases in multimarket contact reduce the rates of market entry. Similarly, any increases in multimarket contact further than 0.122 reverse the sign of the effect and decrease the rates of exit from a competitor’s market. This finding suggesting that mutual forbearance behavior, which results from multimarket contact in the European airline industry, is triggered at low levels of multimarket contacts is interesting. Several industry-specific characteristics may explain this finding. For instance, the gradual saturation of major European airports and the unavailability of timeslots reduce the scope of competitive dynamics in the industry, which in turn may lead to rapid establishment of mutual forbearance behavior[5]. Moreover, as the airline industry is capital intensive, there is little incentive for airlines to relocate operations in competitor’s hub airport. The resulting “hold up effect” as well as airline hub domination may provide an additional explanation for the occurrence of mutual forbearance behavior at low levels of multimarket contact. Finally, familiarity between European airlines ensuing from long history of competitive interactions (i.e. average airline age in our sample is 49.31 years) increases mutual dependence recognition, and as a result, may triggers mutual forbearance dynamics at low levels of multimarket contact.

The empirical findings presented in our study provide support for the inverted u-shaped relation between the degree of multi-territory contact and the level of rivalry and forbearance in the context of the European airline industry. Our study also points to significant seasonal and alliance mitigating effects. These results are in line with previous studies, most notably, Baum and Korn (1996, 1999) studies. However, it does not follow that such conclusions can be generalized to other areas of the world, across time or industries. Further research with a wider scope would be required in order to draw such conclusions. Comparing our results with previous empirical work on non-European airlines such as Baum and Korn (1996; 1999), Gimeno and Woo, (1996), Miller (2010), Prince and Simon (2009), Zhang and Round (2009), Bilotkach, (2011) and Singal (1996) naturally raises difficult obstacles. Indeed, beyond the fact that only Baum and Korn (1999) and our study theorized and tested a curvilinear relationship between multimarket contact and rivalry in the airline industry, other obstacles to generalization relate primarily to (1) the choice of time periods studied and differences in institutional environments, (2) stages in the competitive life cycle (3), maturity of strategic groups (4) differences in propensities to enter into alliances and (5) Competition for timeslots. We assess each of these five dimensions in the following sections.