Blockmodeling

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Blockmodeling is a set or a coherent framework, that is used for analyzing social structure and also for setting procedure(s) for partitioning (clustering) social network's units (nodes, vertices, actors), based on specific patterns, which form a distinctive structure through interconnectivity.[1][2] It is primarily used in statistics, machine learning and network science.

As an empirical procedure, blockmodeling assumes that all the units in a specific network can be grouped together to such extent to which they are equivalent. Regarding equivalency, it can be structural, regular or generalized.[3] Using blockmodeling, a network can be analyzed using newly created blockmodels, which transforms large and complex network into a smaller and more comprehensible one. At the same time, the blockmodeling is used to operationalize social roles.

While some contend that the blockmodeling is just clustering methods, and state that "it is a theoretically grounded and algebraic approach to the analysis of the structure of relations". Blockmodeling's unique ability lies in the fact that it considers the structure not just as a set of direct relations, but also takes into account all other possible compound relations that are based on the direct ones.[4]

The principles of blockmodeling were first introduced by and Harrison C. White in 1971.[2] Blockmodeling is considered as "an important set of network analytic tools" as it deals with delineation of role structures (the well-defined places in social structures, also known as positions) and the discerning the fundamental structure of social networks.[5]: 2, 3  According to Batagelj, the primary "goal of blockmodeling is to reduce a large, potentially incoherent network to a smaller comprehensible structure that can be interpreted more readily".[6] Blockmodeling was at first used for analysis in sociometry and psychometrics, but has now spread also to other sciences.[7]

Definition[]

Different characteristics of social networks. A, B, and C show varying centrality and density of networks; panel D shows network closure, i.e., when two actors, tied to a common third actor, tend to also form a direct tie between them. Panel E represents two actors with different attributes (e.g., organizational affiliation, beliefs, gender, education) who tend to form ties. Panel F consists of two types of ties: friendship (solid line) and dislike (dashed line). In this case, two actors being friends both dislike a common third (or, similarly, two actors that dislike a common third tend to be friends).

Network as a system is composed (or defined) by two different sets: one set of units (nodes, vertices, actors) and one set of links between the units. Using both sets, it is possible to create a graph, describing the structure of the network.[8]

During blockmodeling, researcher is faced with two problems: how to partition the units (e.g., how to determine the clusters (or classes), that then form vertices in a blockmodel) and then how to determine the links in the blockmodel (and at the same time the values of these links).[9]

When analyzing a social network (in social sciences), the networks are usually social networks, composed of several individuals (units) and selected social relationships among them (links). As such real-world networks can be large and complex, a blockmodeling is used to simplify them into smaller structures, that can be much easier to interpret. Specifically, blockmodeling partitions the units into clusters and then determines the ties among the said clusters. At the same time, blockmodeling can be used to explain the social roles, existing in such network, as it is assumed that the created cluster of units mimics (or is closely associated) with the units' social roles.[8]

In graph theory, the image provides a simplified view of a network, where each of the numbers represents a different node.

Blockmodeling can thus be defined as a set of approaches for partitioning units into clusters (also known as positions) and links into blocks, which are further defined by the newly obtained clusters. A block (also blockmodel) is defined as a submatrix, that shows interconnectivity (links) between nodes, present in the same or different clusters.[8] Each of these positions in the cluster is defined by a set of (in)direct ties to and from other social positions.[10] These links (connections) can be directed or undirected; there can be multiple links between the same pair of objects or they can have weights on them. If there are not any multiple links in a network, it is called a simple network.[11]: 8 

Matrix (which can also be shown as a graph) is composed of ordered units, in rows and columns, based on their names. Such ordered units are then divided (partitioned) based on the similarity: units with similar patterns of links are partitioned together in the same clusters. Clusters are then arranged together so that units from the same clusters are placed next to each other and thus preserving the interconnectivity. In the next step, the units (from the same clusters) are transformed into a blockmodel. With this, several blockmodels are usually formed, one being core cluster and others being cohesive; core cluster is always connected to cohesive ones, while cohesive ones can not be linked together. Clustering of nodes is based on the equivalence, such as structural and regular.[8] Primary objective of the matrix form is visually present relations between the persons included in the cluster. These ties are coded dichotomously (as present or absent), and the rows in the matrix form indicate the source of the ties, while the columns represent the destination of said ties.[10]

Equivalence can have two basic approaches: the equivalent units have the same connection pattern to the same neighbors or these units have same or similar connection pattern to different neighbors. If the units are connected to the rest of network in identical ways, then they are structurally equivalent.[3] Units can also be regularly equivalent, when they are equivalently connected to equivalent others.[2]

With blockmodeling, it is necessary to consider the issue of results being affected by measurement errors in the initial stage of acquiring the data.[12]

Different approaches[]

Regarding what kind of network is being blockmodeled, different approach is necessary. Networks can be one–mode or two–mode. In former all units can be connected to any other unit and where units are of the same type, while in latter the units are connected only to the unit(s) of a different type.[5]: 6–10  Regarding relationships between units, they can be single–relational or multi–relational networks. Further more, the networks can be temporal or multileveland also binary (only 0 and 1) or signed (allowing negative ties)/values (other values are possible) networks.

Different approaches to blockmodeling can be grouped into two main classes: deterministic blockmodeling and stochastic blockmodeling approaches. Deterministic blockmodeling is then further divided into direct and indirect blockmodeling approaches.[8]

Structural equivalence

Among direct blockmodeling approaches are: structural equivalence and regular equivalence.[2] Structural equivalence is a state, when units are connected to the rest of the network in an identical way(s), while regular equivalence occures when units are equally related to equivalent others (units are not necessarily sharing neighbors, but have neighbour that are themselves similar).[3][5]: 24 

Regular equivalence

Indirect blockmodeling approaches, where partitioning is dealt with as a traditional cluster analysis problem (measuring (dis)similarty results in a (dis)similartiy matrix), are:[8][2]

According to Brusco and Steinley (2011),[14] the blockmodeling can be categorized (using a number of dimensions):[15]

Creation of a blockmodel[]

In principle, blockmodeling, as a process, is composed from three steps. In the first step, the number of units is determined. This is followed (in the second step) by selection or determination of permitted blocks, that will occur and perhaps also the locations in the matrix. The last, third step, using computer program, the partitioning of units is done, according to the pre–set conditions and additionally, the final matrix is selected for the gained model. With this, the blockmodel is created.[16]: 333 

Specialized programs[]

Blockmodeling is done with specialized computer programs, dedicated to the analysis of networks or blockmodeling in particular, as:

See also[]

References[]

  1. ^ Patrick Doreian, Positional Analysis and Blockmodeling. Encyclopedia of Complexity and Systems Science. DOI: https://doi.org/10.1007/978-0-387-30440-3_412.
  2. ^ a b c d e Patrick Doreian, An Intuitive Introduction to Blockmodeling with Examples, BMS: Bulletin of Sociological Methodology / Bulletin de Méthodologie Sociologique, January, 1999, No. 61 (January, 1999), pp. 5–34.
  3. ^ a b c Anuška Ferligoj: Blockmodeling, http://mrvar.fdv.uni-lj.si/sola/info4/nusa/doc/blockmodeling-2.pdf
  4. ^ Bonacich, Phillip; McConaghy, Maureen J. (1980). "The Algebra of Blockmodeling". Sociological Methodology. 11: 489–532. doi:10.2307/270873.
  5. ^ a b c Doreian, Patrick; Batagelj, Vladimir; Ferligoj, Anuška (2005). Generalized Blackmodeling. Cambridge University Press. ISBN 0-521-84085-6.
  6. ^ Batagelj, Vladimir (1999). "Generalized Blockmodeling". Informatica. 23: 501–506.
  7. ^ WEBER, M. (2007), “Introducing blockmodeling to input-output analysis”. 16th International I-Ot Conf, Istanbul, Turkey.
  8. ^ a b c d e f g , and Aleš Žiberna, blockmodeling: An R package for generalized blockmodeling, Metodološki zvezki, 17(2), 2020, 49–66.
  9. ^ Batagelj, Vladimir (1997). "Notes on blockmodeling". Social Networks. 19: 143–155.
  10. ^ a b Bonacich, Phillip; McConaghy, Maureen J. (1980). "The Algebra of Blockmodeling". Sociological Methodology. 11: 489–532. doi:10.2307/270873.
  11. ^ Brian Joseph Ball, Blockmodeling techniques for complex networks: doctoral dissertation. University of Michigan, 2014.
  12. ^ a b Žnidaršič, Anja; Doreian, Patrick; Ferligoj, Anuška (2012). "Absent Ties in Social Networks, their Treatments, and Blockmodeling Outcomes". Metodološki zvezki. 9 (2): 119–138.
  13. ^ Žiberna, Aleš (2013). "Generalized blockmodeling of sparse networks". Metodološki zvezki. 10 (2): 99–119.
  14. ^ Brusco, Michael; Steinley, Douglas (2011). "A tabu search heuristic for deterministic two-mode blockmodeling". Psychometrika. 76: 612–633.
  15. ^ Brusco, Michael; Doreian, Patrick; Steinley, Douglas; Satornino, Cinthia B. (2013). "Multiobjective blockmodeling for social network analysis". Psychometrika. 78 (3): 498–525. doi:10.1007/S11336-012-9313-1.
  16. ^ Nooy, Wouter de; Mrvar, Andrej; Batagelj, Vladimir (2018). Exploratory Social Network Analysis with Pajek. Revised and Expanded Edition for Updated Software. Third Edition. Cambridge University Press. ISBN 978-1-108-47414-6.
  17. ^ a b STATS.ox.ac.uk – Social Network Analysis
  18. ^ Steiber, Steven R. (1981). "Building better blockmodels: A non–hierarchical extension of CONCOR with applications to regression analysis". Mid–American Review of Sociology. VI: 17–40.
  19. ^ a b c Batagelj, Vladimir; Mrvar, Andrej; Ferligoj, Anuška; Doreian, Patrick (2004). "Generalized Blockmodeling with Pajek". Metodološki zvezki. 1 (2): 455–467.
  20. ^ Cran.R–project.org – Package 'blockmodeling'
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