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An integrated methodology for linking capabilities with strategic goals and measures in organizations. The approach includes principles, a step-by-step method, viewpoints, and a meta-model for capability decomposition and alignment with strategic objectives. Capability maps and 'capability-oriented' strategy maps are used to represent the relationships between goals and capabilities.
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Dmitry Kudryavtsev 1,2, Lev Grigoriev 1 , Svyatoslav Bobrikov 1
(^1) Business Engineering Group, Furazhnyj, 3, 191015 Saint-Petersburg, Russia (^2) St. Petersburg State Polytechnical University, Polytechnicheskaya, 29, 195251, St.Petersburg,
{dmitry.ku, griglev, svyatoslav.bobrikov }@gmail.com
Abstract. Capability-based enterprise modeling is gaining presence in business practice. Capability is the central concept of the resource-based view of a firm, and it helps to bridge strategy with business operations. The use of capabilities for behavior modeling provides flexibility, stimulates reuse, and helps the firm to focus on its core competencies. In order to benefit from this approach, capabilities must be strategy-focused and value-oriented. In other words, strategic goals and measures must be linked to capabilities. The paper provides a methodology to solve this task, which integrates a set of principles (way of thinking), a step-by-step method (way of working), viewpoints, and a meta- model (way of modeling). The article also points to the enterprise architecture management tool, which supports the suggested methodology.
Keywords: enterprise modeling, strategy, goals, capability map, strategy map, strategic alignment, goal cascading matrices.
The primary pursuit of business is creating and maintaining value. The resource-based view suggests that firms’ resources drive value creation via the development of competitive advantage [1]. Specifically, the resource-based view suggests that possessing valuable and rare resources provides the basis for value creation. This value may be sustainable when those resources are also inimitable and lack substitutes [2]. However, merely possessing such resources does not guarantee the development of competitive advantages or the creation of value. To realize value creation, firms must accumulate, combine, and exploit resources. Prahalad and Hamel outline that the source of competitive advantage is to be found in the management’s ability to identify the core competencies of a firm, i.e. “consolidate corporate-wide technologies and production skills into competencies that empower individual businesses to adapt quickly to changing opportunities” [3]. As work on the resource-based view has
progressed, it has become clear that the resource-based view extends not only to the assets of an organization, but also to its capabilities. Capability is the ability of an organization to perform a coordinated set of tasks, utilizing organizational resources, for the purpose of achieving a particular end result [4]. From the theories of the resource- and competence-based view, a capability-based modeling paradigm was derived [5; 6; 7; 8]. By making the firm’s capabilities and their connections visible and providing corresponding performance measures, the capability map concept helps to capture the firm’s capabilities structure and to solve related problems of reengineering and outsourcing, e.g. using “heat maps”. Capability modeling provides guidance on determining how changes in particular business areas, or outsourcing particular business functions, will affect the overall business and not only a singular business process. The use of capabilities for behavior modeling provides flexibility, stimulates reuse, and helps the firm to focus on its core competencies. Since capabilities bridge strategy with business operations and information technologies, they must be linked with strategic goals [9]. In order to support value orientation, it is necessary to clarify this concept. Iacob et al [9] identified that value definitions vary from soft/qualitative to formal/quantitative: as objective functions, (economic) indices. Some value taxonomies/frameworks are mentioned: e.g., Deloitte enterprise value map [10]. It seems that the concept of value is very much related to performance, since performance measures (i.e., so-called key performance indicators) are also value measures, (e.g., costs, profit, customer satisfaction, etc.) [11; 12]. So if capabilities will be associated with the corresponding performance indicators, which measure values of different stakeholders, it will be possible to consider such capabilities to be value-oriented. There exist some frameworks, methods, and models for linking capabilities with strategic goals and measures, such as Hafeez et al framework for determining key capabilities [13], Kaplan and Norton methodology [14, 15] and Archimate capability extension [16]. However, there is a lack of the integrated model-driven methodology. Modelling and automated support is crucial for a design methodology. According to [17] “a design methodology is characterized by a way of thinking, controlling, working, and modelling. Preferably, these "ways" are supported by a coherent set of automated tools (a designers' environment or workbench).” So the objective of the current paper is to provide an integrated methodology for linking capabilities with strategic goals and measures, which will include a set of principles (way of thinking), a step-by-step method (way of working), viewpoints, and a meta-model (way of modeling).
The first principle: goal cascading follows the structure of the capability maps (or more generally, behaviour structure). On one hand, it applies to the translation of goals between levels of strategy (corporate, business and functional), which follows
We applied this decomposition concept to capabilities and received the “Capability type” as a result of specification and the “Capability component” as a result of breaking “Component” down into parts, see Fig. 1. “Capability component” becomes a capability of the next hierarchy level. Besides we use the concept “Capability value configuration” (adapted from [22, 23]), which realizes the “Capability type” and is based on the “Capability components”.
Fig. 1. Two dimensions for activity and capability decomposition
The third principle: capability not only includes “primary” value-creating activities, but also the necessary domain-specific managerial capabilities. Additionally, it sets requirements for enabling capabilities (which can be received as a service). For greater detail, see functional system pattern in [18].
Here are the steps for linking capabilities with strategic goals and measures. The key concepts within this method are represented in the next chapter.
the capability types? 2. Differences in the underlying technology (and in capability components as a result),
The key concepts of the methodology are represented in the meta-model. This meta- model (Fig. 2) rests on the following reference meta-models and ontologies [16, 23, 25]. The definitions of core elements of the metamodel: Goal – an end state that a stakeholder intends to achieve [16]. Capability – an ability to execute a repeatable pattern of actions. A firm has to dispose of a number of capabilities to be able to offer its value proposition. Capabilities are based on a set of Resources [25].
cells of these matrices can be associated with detailed justifications for the various ratings.
Fig. 3. Goal-cascading matrices
Maps include: 1. Capability maps, 2.“Capability-oriented” Strategy maps (Fig. 4). We use specialized capability maps, which are based on the functional system’s pattern [18] and integrate ideas from [5, 6, 8]. For every Capability X functional system’s pattern (and corresponding map) will provide decomposition into capability types and components, besides it will specify capability X’s specific management and enabling elements. The “capability-oriented” Strategy map complies to the standard of traditional strategy maps [14; 19], but has two specialties: 1. It is defined for the Capability concept, while the traditional strategy maps are defined for actors (organization as a whole, business unit, department etc.); 2. Its structure (goal decomposition logic) in Internal and Learning&Growth perspectives follow the structure of the capability in question.
Fig. 4. From Capability to Strategy map
Tables with goals, measures and initiatives are standard and typically have the following structure: Goals – Measure – Target - Initiative.
The suggested methodology is mostly supported by the enterprise architecture modeling tool of ORG-Master [30]. This tool supports a domain-specific modeling concept [31] and provides visual modeling tools [32] as plug-ins. Org-Master includes the following modules: enterprise model editor, reporting and query module, diagram editor and meta-editor. Classifications and matrices are the main knowledge representation mechanisms in ORG-Master. Classification/hierarchical list - the representation format for entities, hierarchical relationships between them and values for the properties of entities. Matrix - the representation format for relationships between entities from classifiers. Advanced matrix editing capabilities of ORG- Master are suitable for work with goal-cascading matrices. The tool’s special functionality, which is relevant for this paper:
relationships. Differences: 1. This paper’s methodology provides more granularity and precision using capability type-component differentiation, capability classification into ‘primary – enabling – management’ and predefined goal groups (perspectives). 2. There is no predefined method in the EKD approach “one may start at any enterprise knowledge submodel and move to other levels, depending on the situation”. 3. Goal hierarchical structure shapes the process architecture in EKD, while in our approach goal structure follows the structure of a capability map. Hafeez, together with his colleagues, provided framework for determining key capabilities [13]. Similarities between the approaches: 1. External requirements for the ‘system’ in question are identified similarly – basis for capability evaluation: the Non-financial performance model [13] is similar to the Customer perspective goals and measures, while the Financial performance model [13] is similar to the Financial perspective goals. 2. Consecutive evaluation of different level capabilities is similar to the system of consecutive goal-cascading matrices. Differences: 1. The purpose of the method: evaluate capabilities versus providing goals and measures for capabilities. Top-level measures are only used to set the evaluation criteria. 2. [13] use more complex and precise AHP in order to evaluate capabilities. 3. We provide more granularity and precision because of the aforementioned detailed capability and goals decomposition.
The increasingly complex, dynamic, and uncertain nature of today’s world has led many enterprises to design and manage their organizations as systems of capabilities (in addition to a system of processes). A capability-based approach makes enterprises more dynamic, support reuse, helps to implement service-oriented architecture, enable companies to focus on core competencies and outsource non-core capabilities. In order to make capability modeling beneficial, enterprises must make capabilities strategy-focused and value-oriented. Such a link with goals and measures will help to prioritize capabilities and transformation initiatives, make solid investment decisions, identify differentiating requirements and criteria operational optimization. This paper provides a methodology for linking capabilities with goals and measures. It integrates a set of principles (way of thinking), a step-by-step method (way of working), viewpoints, and a meta-model (way of modeling). The article also points to the enterprise architecture management tool, which supports the suggested methodology. The main benefits of the method include more precise work with the requirements for capabilities and better identification of the capability components.