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Social network analysis in business and economics Marko Pahor Agenda • What is social network analysis • Short overview of social network analysis techniques • Applications of social network analysis in business and economics • Learning networks • Ownership relations Why do we need (social) network analysis? • Different types of data: • Attribute (properties, opinions, behavior,…) • Ideational (meanings, motives, definitions,…) • Relational (contacts, ties, connections…) • Different data needs different analysis • Variable analysis for attribute data • Typological analysis for ideational data • Network analysis for relational data What is social network analysis • Network analysis is a series of techniques (mathematical, statistical,…) designed to analyze relation data • Mathematically funded in graph theory • Social network analysis is the application of network analysis in the social sciences context What are networks • Imagine a closed set of units, call them actors or nodes • For example people, companies, web pages, • Networks are a set of actors or nodes connected by one or more relations Social networks • Thinking: • … well, yes, but not really what social network analysis is about • Social networks is any network with social entities (persons, groups, companies, social events,…) as actors Social network analysis techniques • “Descriptive statistics” of networks • Actors’ properties • Network properties • Statistical methods • Blockmodelling • Probability models • One-time networks • Dynamic networks Descriptive statistics • Properties of actors • Measures, that describe the position and importance of individual actors in the network • E.g. Degree, betweeness,... • Properties of network • Describe the entire network • Centalization, degree distribution, triadic census,... Statistical methods of social network analysis • Blockmodelling • A clustering methods • Permutations of the adjacency matrix in order to find some apriori expected blocks • Probability models for one-time networks • Modeling the probability of existence of a tie given parameters • Network parameters (e.g. reciprocity), covariates (e.g. gender) and dyadic covariates (e.g. other relation) • Probability models for dynamic networks • Modeling the probability of creation or dissolution of a tie given parameters Applications of social network analysis in business and economics • Example 1: Organizational learning and through learning networks • Example 2: The evolution of the cross-ownership network in Slovenia The Network Perspective to Organizational Learning – A Comparison of Two Companies Organizational learning and learning networks • Organizational learning: individuals’ acquisition of information and knowledge, analytical and communicative skills • Twodivergent perspectives for organizational learning • the acquisition perspective • the participation perspective • Elkjaer’s (2004) ‘third way’ - a synthesis of the participation perspective and communities of practice • Critisim: too much emphasis on the participation perspective and neglects some vital aspects of the acquisition perspective The learning network perspective • The individual is recognized as the primary source and destination for learning • Learning takes place primarily in social interaction • The network perspective helps develop an organizational learning culture Learning networks • External • an extended enterprise model and comprise relationships that a firm has with its customers, suppliers and other stakeholders • Internal • a set of internal relationships among individual members of the firm and other constituencies such as product/service divisions and geographical units • Components of learning networks • learning processes • learning structures • actors Propositions P1: Learning in the network will mostly occur in relatively dense clusters. P2a: More experienced employees will be more sought after to learn from. P2b: More experienced employees will have less of a need to learn from others. P3a: People higher up the hierarchical ladder will be more sought after to learn from. P3b: People higher up the hierarchical ladder learn as much or even more than those on lower levels. P4a: An opportunity (working in the same location or in the same business unit) will increase the probability of learning. P4b: Homophily has an effect; it is more probable you will learn from those who are similar in terms of gender, position, tenure... Data – first company • a software company • 93 employees in three geographical units • 81 employees participated in the study • 59 from Ljubljana (Slovenia), 11 in Zagreb (Croatia) and another 11 in Belgrade (Serbia) • 56.7% of the respondents have a university degree or higher (even one PhD) • 74% of the respondents are male • average tenure 38.9 months Learning network in the first company Data – second company • main business engineering and production of pre-fabricated buildings • 860 employees, 470 of which on the main location • One production and several sales subsidiaries • 348 employees from the main location participated • 59 % of respondents have finished high school, 29 % have a university degree • 79% of the respondents are male, • average tenure is 12.7 years Learning network in the second company Methodology • Network analysis is concerned with the structure and patterning of these relationships • Logistic model for social networks known as the exponential random graph model (Snijders, 2002, Snijders et al., 2004) • What makes a learning tie more probable? • Structural effects • Actor covariate effects • Dyadic covariate effects Model 1 Model 2 Model 3 Model 4 Model 5 reciprocity 1.32 (0.24) 0.75 (0.29) 0.53 (0.26) 0.54 (0.3) 0.54 (0.31) alternating out-k-stars, par. 2 -0.63 (0.23) -0.6 (0.2) -0.74 (0.22) -0.83 (0.26) -0.8 (0.21) alternating in-k-stars, par. 2 0.46 (0.13) 0.23 (0.15) 0.23 (0.14) 0.21 (0.16) 0.22 (0.17) direct + indirect connections 1.24 (0.13) 0.15 (0.17) 0.2 (0.18) 0.26 (0.21) 0.17 (0.2) Clu steri ng alternating k-triangles, par. 2 1.14 (0.11) 0.8 (0.12) 0.76 (0.14) 0.79 (0.14) alternating independent twopaths, par. 2 -0.2 (0.03) -0.19 (0.02) -0.21 (0.03) -0.2 (0.03) Opp ortu nity location (centered) 1.68 (0.26) 1.63 (0.26) 1.72 (0.23) sector (centered) 0.62 (0.11) 0.81 (0.13) 0.72 (0.11) Exp erie nce tenure ego 0 (0.02) -0.02 (0.02) tenure alter 0.02 (0.01) 0.05 (0.02) hierarchy ego -0.04 (0.06) -0.06 (0.07) hierarchy alter -0.12 (0.04) -0.15 (0.06) Gen der gender ego 0.26 (0.15) gender alter 0.07 (0.13) Homop hily Structural effects Effect Seni orit y Results – first company tenure similarity 0.47 (0.16) hierarchy similarity 0.78 (0.41) gender identity 0.47 (0.22) Model 1 Model 2 Model 3 Model 4 Model 5 reciprocity 1.38 (0.27) 1.4 (0.26) 1.33 (0.34) 1.27 (0.31) 1.22 (0.35) alternating out-k-stars, par. 2 -0.47 (0.12) -0.33 (0.12) -0.55 (0.11) -0.57 (0.13) -0.6 (0.13) alternating in-k-stars, par. 2 0.7 (0.08) 0.79 (0.08) 0.86 (0.09) 0.74 (0.09) 0.72 (0.09) direct + indirect connections 1.63 (0.11) 0.77 (0.24) 0.92 (0.31) 0.75 (0.26) 0.93 (0.24) 0.73 (0.18) 0.66 (0.26) 0.82 (0.18) alternating independent twopaths, par. 2 -0.13 (0.02) -0.17 (0.03) -0.17 (0.02) -0.16 (0.02) 1.14 (0.11) 1.23 (0.11) 1.18 (0.12) tenure ego 0.1 (0.09) 0.08 (0.1) tenure alter -0.05 (0.04) -0.03 (0.07) hierarchy ego 0.16 (0.21) 1.09 (0.93) hierarchy alter -0.02 (0.13) 0.86 (0.89) Clus terin g 0.79 (0.3) alternating k-triangles, par. 2 Exp erie nce Effect Seni orit y Structural effects Results – second company Homop hily Gen der Opportunity sector (centered) gender ego -0.31 (0.18) gender alter 0.02 (0.09) education similarity 0.04 (0.27) hierarchy similarity -1.84 (1.8) gender identity 0.05 (0.15) Discussion of results • findings offers support for the network perspective to organizational learning • learning often occurs in project settings and mainly involves the transfer of tacit knowledge through participation • a particular learning setting is dependent on corporate culture and it is hard to capture all of its parameters Paths of Capital: The Creation and Dissolution of the Slovenian Corporate Network Corporate networks • Networks between corporate entities (companies) • Different types of links • • • • • • Interlocking directorates Financial links Strategic alliances Cross-ownership Multilink … Corporate networks configurations • Corporate networks evolve through time • Self-organized or guided • The configuration of a network is a reflection of the current situation (and historical path) • Some configurations: • Groups around financial centers (US, Mizruchi, 1982) • Pyramidal structures (Belgium, Renneboog, 1997 and 1998) • Cross-owned groups (keiretsu system in Japan, Gerlach, 1992) • Sparse (“dismanteled”) network (Hungary, Stark, 2001) The Slovenian corporate network • Basically no corporations before 1992 • Socially (not state!) owned companies • “Ownership allocation” (privatization) • Began in 1992 • Was over by 1998 • “Voucher” privatization • In 1998 almost no connection between (nonfinancial) corporation • By the year 2000 a rather dense network and growing Data • Ownership relations • Owns a share in a public limited company • Only non-financial companies • 476 public limited companies • Companies that existed in 2000 and their legal successors • Were connected at least once in the observed period • 10 years (2000-2009), two observations per year Changes in the network • Network is evolving • Changing links • Changing composition • Two distinct periods are visible • Network creation period • Dismantlement period Network in 2000 Network in 2002 Network in 2004 Network in 2006 Network in 2008 Number of ties ties 1000 900 800 700 600 500 400 300 200 100 0 Disconnected companies 350 300 250 200 150 100 50 0 Size of the largest strong component 45 40 35 30 25 20 15 10 5 0 How it happened? • Some patterns can be observed • Two phased process • Preparatory phase • Execution phase • Coincides with changes in network • Examples • 2000 – 2004 comparisons for the first phase • 2005 – 2009 comparisons for the second phase First phase: Building a portfolio Second phase: Cashing out First phase: making a group Second phase: Closing the deal Findings • Slovenian corporate network is dissolving after a rise early in the decade • Reason: ownership changes • Shows how networks are used to gain control Conclusions • Social network analysis is an emerging technique for the analysis of relations data • Networks are everywhere • Many possibilities for applications in business and economics • Interpersonal relations • Interorganizational relations • Marketing applications: products and customers networks
