Overview
A design structure matrix lists all constituent subsystems/ activities and the corresponding information exchange, interactions, and dependency patterns. For example, where the matrix elements represent activities, the matrix details what pieces of information are needed to start a particular activity, and shows where the information generated by that activity leads. In this way, one can quickly recognize which other activities are reliant upon information outputs generated by each activity. The use of DSMs in both research and industrial practice increased greatly in the 1990s. DSMs have been applied in the building construction, real estate development, semiconductor, automotive, photographic, aerospace, telecom, small-scale manufacturing, factory equipment, and electronics industries, to name a few, as well as in many government agencies. The matrix representation has several strengths. * The matrix can represent a large number ofDSM Structure
A DSM is a square matrix, representing linkages between the system elements. The system elements are often labeled in the rows to the left of the matrix and/or in the columns above the matrix. These elements can represent for example product components, organization teams, or project activities. The off-diagonal cells are used to indicate relationships between the elements. A marking of the cell indicates a directed link between two elements and can represent design relations or constraints between product components, communication between teams, information flow or precedence relations between activities. In one convention, reading across a row reveals the outputs that the element in that row provides to other elements, and scanning a column reveals the inputs that the element in that column receives from other elements. For example, in the DSM, the marking in column A and row C indicated a link from A to C (output from A, input to C). Alternatively, the rows and columns may be switched (without a change of meaning). Both conventions may be found in the literature. The cells along the diagonal are typically used to represent the system elements. However, the diagonal cells can be used for representing self-iterations (e.g., rework of a code that did not pass its unit testing). Self-iterations are required when a matrix element represents a block of activities/subsystems that may be further detailed, allowing hierarchical DSM structure. Two main categories of DSMs have been proposed: static and time-based.T. BrowningDSM marking
Initially, the off-diagonal cell markings indicated only the existence/non-existence of an interaction (link) between elements, using a symbol (or the figure '1'). Such marking is defined as Binary DSM. The marking then has developed to indicate quantitative relation Numeric DSM indicating the "strength" of the linkage, or statistical relations Probability DSM indicating for example the probability of applying new information (that require reactivation of the linked activity).DSM algorithms
The DSM algorithms are used for reordering the matrix elements subject to some criteria. Static DSMs are usually analyzed with clustering algorithms (i.e., reordering the matrix elements in order to group together related elements). Clustering results would typically show groups (clusters) of tightly related elements, and elements that are either not connected or are connected to many other elements and therefore are not part of a group. Time-based DSMs are typically analyzed using partitioning, tearing and sequencing algorithms. Sequencing methods try to order the matrix elements such that no feedback marks remain. In case of coupled activities (activities that have cyclic links, e.g., activity A is linked to B, which is linked to C, which is linked to A) the results is a block diagonal DSM (i.e., blocks or groups of coupled activities along the diagonal). Partitioning methods include: path searching; reachability matrix; triangulation algorithm; and the powers of the Adjacency Matrix. Tearing is the removal of feedback marks (in Binary DSM) or assignment of lower priority (numeric DSM). Tearing of a Component-based DSM may imply modularization (the component design is not influencing other components) or standardization (the component design is not influencing and not influenced by other components). After tearing a partitioning algorithm is reapplied. Minimizing feedback loops gets the best results for Binary DSM, but not always for Numeric DSM or Probability DSM. Sequencing algorithms (usingUse and extensions
Interactions between various aspects (people, activities, and components) is done using additional (non-square) linkage matrices. The Multiple Domain Matrix (MDM) is an extension of the basic DSM structure. A MDM includes several DSMs (ordered as block diagonal matrices) that represent the relations between elements of the same domain; and corresponding Domain Mapping Matrices (DMM) that represent relations between elements of different domains. The use of DSM has been extended to visualize and optimize the otherwise invisible information flow and interactions associated with office work. This visualization via DSM allows the Lean Body of Knowledge to be applied to office and information intensive flows. A customisation of MDM has been illustrated in for the analysis of underspecified systems.References
Additional links
*Web-Portal of DSM Community: http://www.dsmweb.org *International Design Structure Matrix Conference: http://www.dsm-conference.orgFurther reading
*DSM book: http://mitpress.mit.edu/books/design-structure-matrix-methods-and-applications *{{cite book , last = Karniel , first = Arie , last2 = Reich , first2 = Yoram , authorlink = , year =2011 , title = Managing the Dynamics of New Product Development Processes: A New Product Lifecycle Management Paradigm , publisher = Springer , isbn = 978-0-85729-569-9 Systems theory Project management techniques Systems engineering