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Dynamic patterns of technology collaboration: a casestudy of the Chinese automobile industry, 1985–2010
Yuandi Wang • Jian Li • Lutao Ning • Deming Zeng • Xin Gu
Received: 7 October 2013 / Published online: 6 July 2014� Akademiai Kiado, Budapest, Hungary 2014
Abstract To investigate patterns of technology collaboration within the Chinese auto-
mobile industry, this study employs a unique dataset of patent applications that reveal a
record of 64,938 collaborative relations in the industry during the period from 1985 to
2010. Our results indicate that over 60 % of the total collaborations were conducted after
China entered the WTO. The invention and utility types of patents account for 98 % of the
total collaborations throughout the sample period. Using a network analysis method, we
find that the key differences between domestic enterprises collaborating with indigenous
enterprises (DD collaboration) and with foreign firms (DF collaboration) are in patent types
and technology domains. The DF network is also denser and more centralized than the DD
network, although the amount of nodes and links of the DD network is greater than that of
the DF collaboration network. The analysis and visualization of the collaboration networks
and corresponding largest components reveal that a large number of domestic enterprises
prefer to collaborate with top global automobile manufacturers. We also find that a number
of universities have become key players in the collaborations among industry, universities
and research institutes. This study provides a deeper understanding of technology col-
laborations from various perspectives and also highlights several avenues for future
research.
Keywords Collaboration � Network � Patent � Evolution process � Automobile industry �China
Y. Wang � X. GuBusiness School of Sichuan University, Sichuan University, No. 29, Wangjiang Road,Chengdu 610064, Sichuan, China
J. Li (&) � D. ZengSchool of Business Administration, Hunan University, No.11, Lushan South Road,Changsha 410082, Hunan, Chinae-mail: lijian_phd@126.com
L. NingSchool of Business and Management, Queen Mary, University of London, Francis Bancroft Building,Mile End Road, London E1 4NS, UK
123
Scientometrics (2014) 101:663–683DOI 10.1007/s11192-014-1366-8
Introduction
Technology innovation has become a predominant driving force for economic develop-
ment in the knowledge economy era (Schmiele 2012; Yam et al. 2011). How firms choose
an innovation mode that gives them comparative advantages in both local and global
markets has become a key question in recent literature (Cassiman and Veugelers 2006;
Enkel et al. 2009; Von Hippel 2007). Chesbrough (2003) introduced the concept of open
innovation as firms search for external organizations with business models that are better
suited to commercialize a certain technology rather than relying entirely on the firms’
internal R&D efforts. An increasing body of studies have suggested that innovators may
need to link themselves to external actors more than ever to obtain network resources and
opportunities for their own innovative activities (Ahuja 2000; Gulati 1999; Inkpen and
Tsang 2005; Walter et al. 2007). This is because resources, such as human capital, financial
investment, and social capital, have become increasingly important for innovation, and the
lack of such resources may constrain the pace of innovation. Moreover, the uncertainties
and risks associated with in-house R&D produces obstacles for both R&D investment and
innovative output (Becker and Dietz 2004; Howells et al. 2008; Narula 2004).
Previous literature has primarily focused on identifying factors that can influence the
decisions of technology collaboration, such as research interests, knowledge background,
research capability, infrastructure, geopolitical location, cultural relations and languages
(Glanzel 2001; Glanzel and Schubert 2001; Schubert and Glanzel 2006; Zhou et al. 2013).
However, some scholars have indicated that the basis of technology collaboration is, in fact,
collective innovation (Allen 1983; Saxenian 1994; Schrader 1991; Von Hippel 1987). This
collective innovation is usually driven by sharing and exchange of information and knowledge
within collaboration networks that consist of groups of socially connected entities (Dahl and
Pedersen 2004). The characteristics of the collaboration network structure therefore determines
the extent to which information and knowledge can be diffused and exchanged (Cowan and
Jonard 2004; Eslami et al. 2013), and this has a huge implication for firms’ innovation success.
Although the benefits of technology collaboration and the effect of network structure
have been extensively discussed in recent years, the extant literature overwhelmingly
focuses on studying the general features of effective collaboration network structures. It is
often ignored that the heterogeneity and idiosyncratic characteristics of different types of
links between various technology collaborators might exert diverse influences on the
collaboration output (Bierly et al. 2009; Gulati 1999; Li 2011; Uzzi 1996). Therefore, more
efforts are needed to reveal the industry-specific collaboration modes and how they have
changed with the evolution of the industry.
This study aims to extend the strand of general literature on the collaboration network
structure by systematically analyzing the pattern of different types of industry-specific
technology collaboration. For our analysis, we choose the Chinese automobile sector based
on a unique dataset of patent applications in the industry from 1985 to 2010. The devel-
opment of the Chinese automobile industry started in 1953. Indigenous automobile manu-
facturers in that phase focused on assimilation of technology from former Soviet Union until
the implementation of ‘opening up’ policy in 1978, which provided access to technologies
from overseas top automobile manufacturers, such as General Motors, Volkswagen, Toyota,
etc. The National Work Conference on Automobiles held in 1991 confirmed the development
strategy of automobile sector, which switched its focus from motor truck to car manufac-
turing. The biggest joint venture in the Chinese automobile sector was established in the
same year. From then on, new modes of technology improvement, such as collaboration with
overseas partners, began to emerge. Since China entered the WTO in December 11th, 2001,
664 Scientometrics (2014) 101:663–683
123
the trend of globalization brought huge foreign investment into the automobile sector.
Moreover, the implementation of the Policy of Automobile Sector Development in 2004
encouraged private consumption of cars, which has produced immense market demand in the
automobile market. Many Chinese self-owned brands, e.g., Geely, Chery, BYD, and Great
Wall, reaped valuable strategic development opportunities during this period. Since 2010, the
automobile market has entered into the ‘micro increase era.’ The adjustment of product
structure, technology structure and brand structure have been the top issues for the Chinese
automobile manufacturers. Overall, China is now the largest vehicle-producing country,
having overtaken the EU and US in 2010 (Bloomberg 2010). The automobile industry is
considered to be one of the ‘pillar industries’ because of its extensive links with other
industries and significant contribution to job creation (Wang 2003). Since China opened up
and removed protectionist industrial policies, foreign enterprises have begun to play a critical
role in the growth of the sector (Liu and Dicken 2006; Sun et al. 2010). Relatively little
though is known about the pattern of collaborations and how their collaborative links have
changed over time between various actors, i.e., collaboration between domestic enterprises,
collaboration between domestic and foreign enterprises, and collaboration among enter-
prises, universities and research institutes.
The remainder of this study is organized as follows. In the next section, we describe the
data sources and main indicators for measuring collaboration networks. The descriptive
analysis of the pattern of collaborative relations and the analysis of the evolution of three
types of collaboration network based on social network analysis (SNA) techniques are
presented in the Results section. The Discussion and Conclusions section reviews the main
implications and summarizes the findings of this study. Research limitations and avenues
for future research discussed at the end of this paper.
Data sources and methods
Data
The data used in this study was collected from the Patent Information Services Platform
(PISP) that organized and supported by the State Intellectual Property Office of PRC (SIPO).
The PISP website (http://www.chinaip.com.cn/) provides patent information for ten national
key industries in China, i.e., the automobile, steel, electronic information, logistics, textile,
equipment manufacturing, ferrous metal, light industry, petrochemical, and shipbuilding
industries. The patent data for automobile sector was downloaded in November 2012. As the
joint application is a crucial form for linking different innovators (Motohashi and Yun 2007),
we omit those patents applied for by single applicant. We define that a collaborative relation
existed between applicant A and applicant B if they jointly applied for one patent during the
period of 1985–2010. After tidying up and cleaning the patent data, we finally obtained a total
of 64,938 collaborative relations in the Chinese automobile sector over 26 years.
SNA on collaborative relations
Collaboration between innovators is commonplace for the purpose of innovation. According
to prior studies (Newman 2001), collaborative efforts can be formalized in terms of a network
in which any two nodes are connected if they are involved in a common project. Nodes can be
individuals (Cattani and Ferriani 2008), organizations (Schilling and Phelps 2007), regions
(Gao et al. 2011), or even nations (Dodgson 2009). Innovation networks can be analyzed by
Scientometrics (2014) 101:663–683 665
123
using the tool of social networks (Borgatti and Cross 2003; Butts 2008; Sorenson 2005).
Social network analysis is a widely used technique for exploring relational data and offers a
number of metrics for understanding network structure and dynamics (Butts 2008). SNA has
been employed widely in studying collaboration networks during the last two decades (Butts
2008; White and Jorion 1996). Typically, an innovation network has two categories of
properties: node-level and network-level properties (Wasserman and Faust 1994). Like actors
in a geographic space, actors in the network have different positions that are measured
through various indicators such as centrality and brokerage (Burt 2004). These indicators are
useful in exploring the roles and influence of actors in a network. For example (Cho and Shih
2011), drawing on patent citation data, constructed centrality indicators to identify core and
emergent industries. Zaheer and Soda (2009) identified structural holes in a co-membership
network in the Italian TV production industry and found that homogeneity rather than
diversity influences performance across structural holes.
Networks that are constructed through SNA
As there is very limited information about the individual applicants in our patent dataset, it
might lead to a serious bias if we constructed a collaboration network based only on the
name of individual applicants. Therefore, this study focused on the three types of col-
laboration networks at organizational level using the SNA technique: (1) co-application
network between domestic enterprises (DD collaboration network), (2) co-application
network between a domestic enterprises and foreign enterprises (DF collaboration net-
work), and (3) co-application network among enterprises and universities and research
institutes (UIR collaboration network). The nodes in the DD collaboration network are the
indigenous enterprises and their domestic collaborators only, and the links represent the co-
application relationships (e.g., joint R&D effort) among these domestic enterprises. The
nodes in the DF collaboration network are the Chinese-owned enterprises and their
overseas collaborators (foreign invested enterprises (FIEs) and overseas enterprises), and
the links represent co-application relationships among them. The nodes in the UIR col-
laboration network are enterprises and their collaborators (e.g., domestic and overseas
universities and research institutes), and the links represent co-application relationships
among one enterprise and one university or research institute.
Network properties that are measured through SNA
To illustrate the dynamic changing of the three aforementioned types of collaboration
networks, several network properties were calculated using the SNA techniques. The node-
level properties were measured via the number of nodes (size of network), total number of
links (i.e., co-application relationships), density, clustering coefficient, and K-core. In
addition, we used average path (i.e., average geodesic distance of the whole network) and
degree of centralization to measure the network-level properties.
The network density is the number of actual links (the links that are realized in a network)
divided by the number of possible links between pairs of nodes present in a network.
Density ¼ 2k=NðN � 1Þ ð1Þ
where k is the amount of actually linked relationships between collaborators. N is the total
number of nodes (i.e., patent applicants). A network with a high density has more available
channels for knowledge diffusion and spillover among collaborators.
666 Scientometrics (2014) 101:663–683
123
The clustering coefficient is the degree to which nodes in a network tend to cluster together.
It measures how many of a network actor’s friends are connected to each other. This study
employed the weighted overall clustering coefficient measurement method (Newman 2001).
Clusteringw ¼ 3Ta=Tp ð2Þ
where Ta is the number of triangles in a network; Tp is the number of connected triples in
the network. The triangle is composed of three actors, any two of which are linked
together. The connected triple is that at least one of the three actors links the other two
actors. The larger the clustering coefficient of an actor is, the higher its surrounding
clustering level is (Zhu and Guan 2013).
A K-core is a maximal group of actors, all of whom are connected to some number (K) of
other members of the group. The K-core value of an actor is the largest K of the K-core network
it belongs to. The larger the K-core value of an actor is, the more important is in the network
(Zhu and Guan 2013). In other words, K-core indicates the influence range of the actor. The
parameter is usually adopted to identify the most influential and essential players in a network.
The average path measures the average number of intermediaries between any two
reachable actors in their shortest path in a network. The geodesic distances among actors in
a network may be important macro-characteristics of the network as a whole. The geodesic
path is often the ‘optimal’ or most ‘efficient’ connection between two actors.
The network degree centralization measures the extent to which entire nodes are con-
centrated in the center of a network (Wasserman and Faust 1994). It is a proxy of the level
of difference between actors in the whole network. Unlike degree centrality, which mea-
sures an actor’s direct linkage with neighborhood actors, degree centralization indicates the
concentration status at the network level.
CentralizationD ¼P
v2V maxv0 2V C�ðv
0 Þ � C�ðvÞ� �
maxP
v2V maxv0 2V C�ðv0 Þ � C�ðvÞ
� �� � ð3Þ
The numerator in formula (3) denotes the centrality variation measure of nodes that is
measured by Butts (2006), whereas the denominator is the maximum variation in the
degree centrality of a network of the same size. Therefore, degree centralization is a ratio
of variation in degree centrality of all nodes against the highest possible variation in the
degree centrality of a graph with the same size (de Nooy et al. 2005). The higher value of
the degree centralization is, the more concentrated the network is.
Both the node and network properties of the three types of co-applicant networks in this
study were calculated by using UCINET software (Borgatti et al. 2002). The visualization
of the evolution of the networks was performed using an R package (STATNET)
(Handcock et al. 2008).
Results
Descriptive statistics
Figure 1 illustrates the overall trend of the number of collaborative relations in the Chinese
automobile sector from 1985 to 2010. There were 178 collaborations existing in 1985,
which is only 2.25 % of the number of collaborations in 2010 (7,904 collaborations). In
particular, the number of co-applications in the Chinese automobile sector was approxi-
mately 1,500 before year 2002. This figure increased to nearly 3,000 in 2002, and it was
Scientometrics (2014) 101:663–683 667
123
growing gradually from then on (except in 2007). The total collaborations during the
period from 2002 to 2010 (42,856 collaborations) account for approximately 66 % of all
collaborations in the whole sample period (1985–2010). This indicates that entering the
WTO encouraged Chinese automobile manufacturers to be more open to external partners
than before. This visualizing result is consistent with some recent studies that emphasize
the surge of patenting and collaborations since China joined the WTO (Hong and Su 2013;
Li 2012; Zheng et al. 2013). Details of collaborations in each year can be found in Table 4
in the Appendix.
There are four types of applicants in the Chinese patent system, i.e., individuals,
enterprises, universities, and research institutes. Nearly 70 % of collaborations were
conducted by individual applied patents, whereas collaborations among universities and
research institutes hosting R&D projects account for only 5 %. In addition, a quarter of all
co-application relations involved enterprise patent applications. As Goncalves and
Almeida (2009) noted, a large proportion of individuals in the patenting system is very
common in the developing country context. The main reason there is a high proportion of
individual applications in China is because of the principal of the inventive activities and
the representatives of the firms’ legal person or R&D teams usually registered themselves
as the applicants of the patents rather than using the organization name (Wang et al. 2013).
Moreover, as the assessment criteria for the three types of SIPO patent (i.e., invention,
utility model, external design) are different, both the innovativeness and practical value of
inventions and utility models are higher than that of external designs (Cheung and Lin
2004). Specifically, over half of collaborations were conducted involving utility models,
and 42.52 % of collaborations were for invention patents in the Chinese automobile
industry during the sample period. This portfolio implies that collaborated innovation
outputs usually involve a higher level of innovativeness and useful knowledge (Fabrizio
2009; Hong and Su 2013; Wang and Zhou 2013).
We notice that the distribution of collaborations in the six automobile technology fields
is uneven. These six technology domains can be classified into three groups in terms of the
amount of collaborations. Automobile body and chassis collaborations are classified into
the first group as each of them accounts for over 20 % of all collaborations. Engine,
electrical device and other collaborations belong to the second group, as the share of
collaborations in each of them exceeds 16 %. Fuel collaboration forms the last group,
which accounts for only 3.21 % of all collaborations.
We can also divide the collaborations into several subsets in accordance with the type of
specific applicant, i.e., enterprise, university and research institute, and individual. The
majority of collaborations were conducted by inventors (70.16 %), whereas co-applica-
tions between organizations and individuals (OI collaborations) account for only 3.95 % of
the total collaborative activities. In particular, we further divided collaborations related to
domestic enterprises into two categories, collaborations between domestic firms (DD
collaborations) and collaborations between domestic and foreign invested/owned firms (DF
collaborations).1 A further analysis revealed that the proportions of DD collaborations and
DF collaborations are very close, both of which are approximately 10–12 %. In contrast,
the relatively low level of university–industry–research institutes (UIR) collaborations
(4.22 %) indicates that the bilateral and trilateral interactions among UIR relationships in
the Chinese automobile sector are relatively weak, although the joint UIR projects can
motivate the knowledge-based strategy and speed up the rate of socioeconomic
1 Although the R&D collaborations between foreign invested/owned firms can be an important topic, thefocus of this paper is the DD, DF, and UIR R&D collaborations.
668 Scientometrics (2014) 101:663–683
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development (Park and Leydesdorff 2010). Considering the heterogeneities of domestic
and foreign firms in terms of innovativeness (Choi et al. 2011; Li 2011) and also the
decentralizing trend of UIR collaborations during the last decade in China (Hong 2008), we
hereby focus on the collaborations among organizations in the following sections.
As mentioned in the preceding sections, both the novelty and level of technology are
varied according to the patent type. Therefore, we analyzed the trend of development of
collaborations by focusing on the distribution of co-applications in invention, utility model,
and design in each year during 1985–2010. Moreover, considering the heterogeneities and
idiosyncratic features of specific technology domains, we focused on the amount of col-
laborations involving the categories of automobile body, chassis, electrical device, engine,
fuel, and others as well.
The longitudinal trend of DD, DF, and UIR collaborations
Figure 2 shows that there have been far more R&D collaborations in invention and utility
models than in design. The first design collaboration occurred in 2001, which is much later
than that for inventions (in 1986) and utility models (in 1985) collaborations. In addition,
the amounts of invention and utility model collaborations are very similar during the
sample period. A sharp growth of co-applications for invention and design was detected in
the last 5 years in the sample period (2006–2010). This indicates that a vast number of
resources and highlights have been driven by domestic enterprises engaging in joint R&D
projects for obtaining innovative output rather than for external designs.
Figure 3 illustrates that except for collaborations in the technology domain of fuel, DD
collaborations in the other five technology domains display similar development tracks
during the sample period (except for a peak value for the others domain in 1992). Since
2004, collaborations involving the automobile body, chassis, electrical device, engine, and
others domain experienced huge increases from approximately 25–300 or so in 2010. This
indicates that the collaborative focuses of Chinese indigenous enterprises are balanced in
technology domains except for the fuel domain.
Fig. 1 Overall distribution of the number of collaborations in the Chinese automobile sector by year,1985–2010
Scientometrics (2014) 101:663–683 669
123
Figure 4 depicts that there are huge differences between the number of collaborations
involving inventions and utility models and designs during the sample period. It is sur-
prising to find that there are no DF collaborations for utility models and designs before
1995, and the number of DF collaborations in the utility model and design categories
fluctuate between 10 and 30 (except for 46 utility model collaborations in 2004) from
1996. This phenomenon suggests that the aim of collaborations across national boundaries
is to create advanced knowledge or frontier technology rather than to focus on R&D with
middle- to low-level innovativeness. Moreover, the number of invention DF collaborations
decreased heavily from 1,015 to 467 in 2010, which is even less than the number of DF
collaborations in 2003 (512). A possible reason for the drop of cross-boundary collabo-
rations is that domestic firms accumulated R&D resources in their prior collaborations
(Cohen and Levinthal 1989), and they can easily collaborate with indigenous counterparts
with less communication and absorption costs than with overseas partners.
Fig. 2 The distribution of R&D collaborations between domestic enterprises by patent type
Fig. 3 The distribution of number of collaborations between domestic enterprises by technology domain
670 Scientometrics (2014) 101:663–683
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It is obviously that the six technology domains can be classified into three groups in
terms of the amount of DF collaboration (shown in Fig. 5). Specifically, the number of
collaborations in the automobile body and chassis domains is higher than for the other four
technology domains, and the gap between them has increased since 2002. The second
group includes the electrical device, engine, and others domains, and the frequencies of DF
collaboration in these three domains display a similar pattern during the sample period.
Greatly fewer DF collaborations are found for the fuel domain, and this is basically in
agreement with Fig. 3. The longitudinal trend shown in Fig. 5 indicates that domestic
enterprises are more willingly to conduct joint R&D projects with foreign counterparts in
the automobile body and chassis technology domains.
Fig. 4 The distribution of number of collaborations between domestic and foreign enterprises by patenttype
Fig. 5 The distribution of number of collaborations between domestic and foreign enterprises bytechnology
Scientometrics (2014) 101:663–683 671
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UIR collaboration is considered to be a facilitator for the production of knowledge,
which is helpful for building innovation systems, and innovation can in turn spur the
economic growth of developing countries (Swar and Khan 2013). Figure 6 shows that the
UIR collaborations in the Chinese automobile sector mainly focused on inventions and
utility models rather than designs during the period from 1985 to 2010. The growth trend of
UIR collaboration in the invention and utility model categories is even much stronger since
2002, as the number of collaborations grows dramatically from 41 and 40 to 405 and 334 in
2009, respectively. This huge increase reflects that UIR collaboration has been highlighted
at the industrial level, and the majority of joint R&D projects conducted by UIR alliances
are interested in innovations with higher novelty.
Comparing Figs. 7 with 3 and 5, we notice that the chassis and others domains are the
two main focuses of UIR collaborations, whereas DD and DF collaborations mainly focus
on the automobile body and chassis domains. This suggests that UIR collaborations are
complementary with collaborations between enterprises as the knowledge bases of uni-
versities and research institutes are not the same as that of enterprises (Schartinger et al.
2002).
Network analysis
As discussed in a previous section, collaborative relations can be analyzed using the SNA
technique. Specifically, three types of R&D collaboration network have been examined in
this paper, i.e., collaboration network of domestic enterprises (DD network), collaboration
network of domestic enterprises and foreign enterprises (DF network), and collaboration
network of enterprises, universities and research institutes (UIR networks). Both the node-
and network-level properties are measured to analyze the structural change of the col-
laboration networks in different phases during the period 1985–2010. We suppose that both
the joint R&D effort and co-application require some time. During this collaboration
period, it is assumed that information exchange occurs to a great extent among the patent
applicants (He and Hosein Fallah 2009). Following prior studies (Baum et al. 2003; Eslami
Fig. 6 The distribution of number of collaborations between UIR by patent type
672 Scientometrics (2014) 101:663–683
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et al. 2013; Fleming et al. 2007; He and Hosein Fallah 2009), we have assumed that the life
length of each link in the created collaboration network is 5 years. Therefore, we extracted
the collaborative relationships for five snapshots from 1985 to 2010. This procedure
resulted in five undirected one-mode networks for each type of collaboration network, i.e.,
1985–1990, 1991–1995, 1996–2000, 2001–2005, and 2006–2010.
Evolution of DD collaboration network structure
As shown in Table 1, although the size of the DD collaboration network increased from
1985 to 2010, the growth pace was not even. The number of nodes (applicants) in the DD
network from the period 2001–2005 to the period 2006–2010 increased 1,148, whereas it
increased merely 26 from the period 1985–1990 (184) to the period 1996–2000 (210). This
circumstance is vividly shown in the graph of the whole network of DD collaboration in
each period. The visualization not only depicts the huge increases of the size and links of
DD network but also indicates the features of the evolution process of the network. For
instance, the DD network becomes even less dense in the period 2006–2010 (0.0021) than
the period 1985–1990 (0.0086). This implies that although a huge number of domestic
enterprises participated in the network, the links between domestic enterprises are still very
scarce. Moreover, the increasing average path (average geodesic distance) within the DD
network during the period 1985–1990 (1.257) to the period 2006–2010 (2.021) indicates
that domestic enterprises may have opportunities to collaborate with potential partners in a
wider space of the network. In addition, with the decreasing value of centralization of the
DD network, e.g., the value dropped from 0.0126 (1985–1990) to 0.0016 (2006–2010), the
probability of a node with abundant relationships within the network decreased.
Interestingly, we find that the clustering coefficient of the DD network is much higher in
the period of 1991–1995 (1.103) than in other periods. This situation indicates that local
clustering increased when more nodes were linked with each other in a short distance. With
the huge increase in the amount of new participants into the network in the period
2006–2010, the probability of many of the domestic enterprise’s collaborators being
connected to each other is higher as the clustering coefficient reaches 0.705. Moreover, a
Fig. 7 The distribution of number of UIR collaborations by technology domain
Scientometrics (2014) 101:663–683 673
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high K-core value indicates highly influencing power (Zhu and Guan 2013). If a node has a
high K-core value, it can be considered an important player in the network. The maximal
K-core value of the DD collaboration network in the period 1991 to 1995 (K-core = 9) and
the period 2006 to 2010 (K-core = 6) implies that domestic automobile enterprises in these
periods had much wider influence range than others, and they are important players in the
whole network. The bottom row of Table 1 further provides the visualization of the largest
component within the DD collaboration network in each period, which results in various
shapes. For instance, the structure of the largest component in the period of 1985–1990 and
in 2001–2005 is a star shape, which implies the node located in the center is the most
essential player who can influence other linked players by controlling knowledge diffusion
(Wasserman and Faust 1994). Similarly, there is a key player in the largest component in
the DD network in the period 2006–2010. The largest component in the period 1991–1995
is composed of 15 nodes, and the majority of them are linked with each other. This
suggests that there are many channels to obtain knowledge or information from other
collaborators, and no single node can function as a component hub. The size of the largest
component increased from 9 in the period 1985–1990 (accounts for 4.89 % of the whole
network) to 39 in the period of 2006–2010 (accounts for 2.48 % of the whole network).
Evolution of DF collaboration network structure
A huge growth in the average path is shown in Table 2, as it increased Compared with the
DD collaboration network (as shown in Table 1), the size of the DF collaboration network
(see Table 2) is much smaller. For instance, there are only 31 nodes with 38 links within
the DF network in the period 1985–1990, but the DD network in this period has 184 nodes
with 216 links. This indicates that collaboration between domestic automobile enterprises
and foreign enterprises was very scarce at the very beginning of the ‘‘opening up’’ policy.
Table 1 Collaboration networks between domestic enterprises
Indices 1985–1990 1991–1995 1996–2000 2001–2005 2006–2010
Node 184 208 210 426 1574
Link 216 376 260 522 2270
Density 0.0086 0.0111 0.0085 0.0057 0.0021
Average path 1.257 1.126 1.382 1.378 2.021
K-core 2 9 3 2 6
Clustering 0.509 1.103 0.627 0.393 0.705
Centralization 0.0126 0.0120 0.0082 0.0036 0.0016
Whole network
Largest component
Source Compiled by authors
674 Scientometrics (2014) 101:663–683
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An increasing number of both indigenous enterprises and foreign enterprises participated in
the R&D collaboration network of the Chinese automobile sector from 1991 to 2010 as the
number of nodes and links reached 933 and 1,924, respectively, in the period 2006–2010.
Although the size and linkages of the DF network are still smaller than that of the DD
network, the average number of links of each node of the DF network (2.06 in 2006–2010)
is higher than that of the DD network (1.44 in 2006–2010). Moreover, the overall trend of
the DF network indicate a decreasing density compared with earlier periods, e.g., the
density of the DF network decreased from 0.0731 in the period of 1985–1990 to 0.0045 in
the period of 2006–2010, and the density of the DF network is greater than that of the DD
network in each period, which provides further evidence that linkages between domestic
automobile enterprises and foreign enterprises are more prosperous than the collaborations
between indigenous enterprises.
A huge growth in the average path is shown in Table 2 as it increased 222.6 % in the
period from 1985 to 1990 (1.552) to the period from 2006 to 2010 (5.007). This fact
indicates that domestic automobile enterprises could increasingly engage in collaborations
with potential overseas partners in a much wider scope than with indigenous partners. A
comparison between the DD network and DF network in terms of the average path reveals
that the collaborations between domestic enterprises are more likely to happen in a scope
within a short distance. This argument is proven by the higher level of clustering coeffi-
cient of the DD network than that of the DF network. In particular, except in the first period
(1985–1990), the DF network has a smaller probability to include a cluster in which a
node’s neighbors are connected with each other than the DD network. In addition, the
smaller K-core value of the DF network compared with the DD network in each period
(except 2001–2005) indicates that the size of the subgroup in which each group member is
connected with other members of the DF network is smaller than that of the DD network.
Therefore, it is not surprising to find that degree of centralization of the DF network is
greater than that of the DD network in each period, which implies that the probability of
Table 2 Collaboration networks between domestic and foreign enterprises
Indices 1985–1990 1991–1995 1996–2000 2001–2005 2006–2010
Node 31 82 218 676 933
Link 38 104 308 1262 1924
Density 0.0731 0.0232 0.0148 0.0070 0.0045
Average path 1.552 1.175 2.432 4.438 5.007
K-core 2 2 2 4 5
Clustering 0.750 0.625 0.267 0.222 0.309
Centralization 0.0404 0.0130 0.0185 0.0096 0.0093
Whole network
Largest component
Source Compiled by authors
Scientometrics (2014) 101:663–683 675
123
the existence of a hub node within the DF network is higher than that within the DD
network. In other words, it is more likely that an enterprise will be found as the center of
the DF network with abundant relationships with other enterprises.
The visualization of the DF network and its largest component in Table 2 provides
intuitive evidence of the evolution of collaborations between domestic automobile enter-
prises and foreign enterprises. It is obvious that an increasing number of enterprises in the
DF network began to link with others from 1991. The size of the largest component grew
from 6 (accounting for 19.4 % of whole network) in the period 1985–1990 to 454
(accounting for 23.6 % of whole network) in the period 2006–2010. More importantly, we
notice that the size of other components is much smaller than the largest component during
the period of 2001–2010. For example, the second largest component within the DF
network in 2006–2010 includes only seven nodes. This indicates that a technology alliance
that includes the main technology sources of the supply chain may exist in the global
automobile sector, and Chinese indigenous manufacturers are more willing to be a member
of this large alliance to obtain advanced knowledge and valuable opportunities rather than
to ally with domestic enterprises.
Evolution of UIR collaboration network structure
Table 3 illustrates that both the size and links of the UIR network increased during the
period of 1985–2010, which indicates that an increasing number of enterprises began to
realize the benefits of collaborating with universities and research institutes. Compared
with the DD and DF networks, the UIR network is denser but has a lower K-core value
overall. This may be because universities and research institutes are usually the key players
linking enterprises through joint R&D efforts (Hong and Su 2013), whereas those enter-
prises linked with key universities and research institutes may not connect with each other.
Table 3 Collaboration networks between enterprises and universities and research institutes
Indices 1985–1990 1991–1995 1996–2000 2001–2005 2006–2010
Node 95 93 111 238 724
Link 112 106 146 330 1076
Density 0.0161 0.0164 0.0180 0.0101 0.0042
Average path 1.273 1.315 1.448 2.545 4.501
K-core 1 1 2 2 2
Clustering 0.000 0.000 0.323 0.143 0.030
Centralization 0.0162 0.0240 0.0186 0.1110 0.0029
Whole network
Largest component
Source Compiled by authors
676 Scientometrics (2014) 101:663–683
123
Moreover, the relatively low level of the clustering coefficient implies a low probability of
the UIR network including a cluster in which a node’s neighbors are connected with each
other. A further comparison between the UIR network with DD and DF networks indicates
that the average path of in the UIR network is longer than in the DD network but smaller
than in the DF network, which indicates that the collaboration scope of UIR is even larger
than that of collaboration between domestic enterprises but is still narrow relative to
collaboration between indigenous automobile enterprises and foreign enterprises. In
addition, the relatively high level of centralization of the UIR network may be due to the
predominant role played by some first-tier universities and the limited number of UIR
collaborations. In addition, the large decrease in the centralization of the UIR network from
0.1110 in the period 2001–2005 to 0.0029 in the period 2006–2010 may have been caused
by the huge increase of nodes and links within the network, which decreases the probability
of a single node being the center of the UIR network.
The visualization of both the whole UIR network and its largest component shows that
the network structure evolved gradually from 1985 to 2010. Furthermore, the largest
component of the UIR network is a bit more complicated than that of the DD network and
includes much fewer participants than the DF network. Specifically, the size of the largest
component increased from 3 in the period of 1985–1990 to 113 in the period of 2006–2010,
which accounts for 9.67 and 12.11 % of the whole network, respectively. A deep analysis
of the degree centrality in the last two periods (2001–2005 and 2006–2010) identified key
players in the UIR network, including Tsinghua University, Zhejiang University and Jilin
University, among others. All of these universities are first-tier higher education institu-
tions in China.
Discussion and conclusions
Although the benefits and importance of the R&D collaboration with external partners
have been investigated and highlighted by recent literature (Doloreux and Shearmur 2012;
Zheng et al. 2013; Zhou et al. 2013), we still understand very little about the pattern and
evolution of industry-specific collaborative activities. The overall circumstances of the
64,938 technology collaboration relations in the Chinese automobile sector during the
period 1985–2010 have been assessed through several perspectives, e.g., descriptive sta-
tistics, longitudinal trends, and collaboration networks in this study. Considering the levels
of innovativeness of inventions, utility models and external designs are not the same
(Cheung and Lin 2004; Li 2012), and the heterogeneity and idiosyncratic features of six
technology domains of automobile sector, we analyzed the longitudinal trend of specific
collaborations separately by patent type and technology domain. More importantly, we
systematically analyzed the changing structure and evolution process of DD collaboration,
DF collaboration and UIR collaboration by measuring network properties and visualizing
the whole networks and their largest components.
One of our major findings suggests that the majority of collaborations are embedded in
invention and utility rather than in design. This fact implies that both individuals and
enterprises are more willing to make joint efforts to pursue R&D with a higher level of
innovativeness. Therefore, the open innovation mode is a preferable manner for innovators
to obtain advance knowledge and valuable opportunities from networking with external
exchange partners in the Chinese automobile sector. With the exception of the fuel domain,
the collaborations are distributed evenly in the other five technology domains (automobile
body, chassis, electrical device, engine, and others). This suggests that there is no ‘‘hot
Scientometrics (2014) 101:663–683 677
123
topic’’ that attracts most R&D efforts in that area. Approximately 22 % of collaborations
are joint efforts made by enterprises, which indicates that there is still large room for
enterprises to search for open innovation partners in the near future. Considering the high
proportion of individual applicants in collaborative patents, we suggest policy makers
should launch specific regulations to adjust the procedures for patenting application,
assessment and registration and make an effort to adopt the standards used in developed
countries so that more analysis can be performed to support future policy designs. The
relatively small proportion of collaboration between organizations and individuals
(3.95 %) implies that it is difficult to bridge organization R&D with personal innovations,
and some institutional efforts should be made to improve the level of transformation of
personal R&D output into commercial usage.
The main result from the descriptive analysis of the longitudinal trend of collaborations
implies that the majority of collaborations were conducted after China entered the WTO in
2001. A more open environment has proven to be an encouragement for innovators to
engage in open innovation (Chesbrough and Crowther 2006; Laursen and Salter 2006).
Interestingly, we found that DD collaborations are interested in both inventions and utility
models, whereas DF collaborations only are interested in inventions rather than utility
models. This reflects that when Chinese indigenous enterprises collaborate with overseas
partners, they are only concerned about absorbing frontier technology via joint R&D
efforts. This is in line with the argument of the technology-seeking strategy in IB (inter-
national business) theory (Dunning 1988; Luo and Tung 2007). Moreover, we found that
the year 2001 was the turning point; from then on, a huge increase in DD and DF col-
laborations was detected. This interesting phenomenon implies that the technology gap
between Chinese indigenous enterprises and foreign counterparts is becoming smaller than
before, and therefore, more domestic enterprises have begun to collaborate with external
partners. A further analysis suggests that DD collaborations are interested in all technology
areas expect for fuel, whereas DF collaborations are more likely to focus on the automobile
body and chassis domains. This difference in interests implies that domestic enterprises
have a clear technology focus when collaborating with foreign counterparts.
Additionally, the DF collaborations in invention patents experienced a notable drop
since 2007. Two possible explanations for this phenomenon are follows. One reason is that
domestic enterprises have accumulated a certain level of R&D capabilities and they can
obtain interested knowledge through cooperating with indigenous exchange partners with
relatively less coordination costs than with foreign counterparts. Another reason may be
due to the Chinese government launching the ‘‘Medium- to Long-Term Plan for the
Development of Science and Technology’’ (MLP) in 2006, in which policy makers
emphasize the importance of cultivating independent R&D capabilities of domestic
innovators (Abrami et al. 2014; Cao et al. 2013). Chinese automobile manufacturers may
therefore have a propensity to enhance their independent innovation capabilities against
this background.
A further investigation of the evolution process of the DD network, the DF network,
and the UIR network provided many more details about the dynamic changing of net-
work structure during the period of 1985–2010. To better understand this evolution
process, we measured both node and network properties, e.g., number of nodes and links,
density, average path, K-core, clustering coefficient, and degree of centralization. In
addition, we visualized the whole network and the corresponding largest component for
each of the five snapshots. The findings suggest that although the DD collaboration
network is much larger than the DF network, the DF network is denser than the DD
network. In addition, the average path of the DF network is usually longer than that of
678 Scientometrics (2014) 101:663–683
123
the DD network. This phenomenon may be caused by the fact that domestic automobile
enterprises could obtain limited technology support from collaborating with indigenous
enterprise but gain relatively more advance knowledge and valuable opportunities via
making joint R&D efforts with foreign enterprises. Moreover, the size of the largest
component of the DF network (454 in 2006–2010) is much larger than that of the DD
network (39 in 2006–2010). We identified the top three enterprises in terms of degree of
centrality within the DF network in the period of 2006–2010, i.e., Toyota Motor Co., Ltd.
(degree of 281), Honda Motor Co., Ltd. (degree of 121), and Hyundai Motor Co., Ltd.
(degree of 101). The first two are famous automobile manufacturers in Japan, and the
latter is a top vehicle manufacturer in Korea. Therefore, the largest component within the
DF collaboration network is actually a R&D alliance that centers on these foreign
enterprises. This indicates that the majority of Chinese automobile manufacturers have
absorbed advance technologies through collaboration with several top enterprises during
the last decade. The evolution process of the UIR network implies that first-tier uni-
versities, e.g., Tsinghua University, Zhejiang University and Jilin University, are the key
players in the UIR collaboration network. An increasing number of collaborations
between those key universities and enterprises are found in the UIR network, but both
the size and links of the largest component are much smaller than those in the DF
network. This suggests that more effort should be expended by knowledge-intensive
business services (KIBS) to facilitate commercialization of technology innovations made
by universities and research institutes (Yam et al. 2011).
This paper provides a fuller picture of the patent collaboration pattern in the Chinese
automobile industry. However, it is not without its limitations, which warrant future
studies. First, this paper focuses on the collaborations between organizations rather than
individuals as the SIPO patent records do not include any personal information except
individuals’ names. We are unable to distinguish between namesakes and further con-
struct collaboration network at the individual level. Future research might be in a good
position to re-examine some of these issues when more detailed data become available.
Second, we have visualized both the whole network and the largest component for
collaboration networks, but we have not analyzed the influential actors in the network,
namely those enterprises with the highest K-core value (Zhu and Guan 2013). Third, this
study did not discuss the small world network properties of these collaboration networks,
which is an avenue for future research. Finally, this study only focused on the patent
collaborations in the Chinese automobile industry. A comparison study of the patent
patterns and evolution processes with other industries or in cross-cultural settings, e.g.,
between China and European countries or the U.S., might reveal additional points of
interest.
Acknowledgments This research is funded by national Science Foundation of China (grant no.71302133;grant no.71233002), Youth Project of Ministry of Education, Humanities and Social Sciences PlanningFunding (grant no.13YJC790154), and the Sichuan University’s Special Research Program for the Philos-ophy Social Science from the Subordinate Universities of Ministry of Education’s Basic Research Foun-dation (SKYB201302; SKX201004).
Appendix
See Table 4.
Scientometrics (2014) 101:663–683 679
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