Difference between revisions of "Types of Systems"
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A taxonomy is "a classification into ordered categories" (Dictionary.com 2011). Taxonomies are useful ways of organizing large numbers of individual items so their similarities and differences are apparent. No single standard
A taxonomy is "a classification into ordered categories" (Dictionary.com 2011). Taxonomies are useful ways of organizing large numbers of individual items so their similarities and differences are apparent. No single standard exists, several attempts have been made to produce a useful classification taxonomy, e.g. (Bertalanffy 1968) and (Miller 1986).
Kenneth Boulding (Boulding 1956), one of the founding fathers of [[General System Theory (glossary) | general system theory]], developed a systems classification which has been the starting point for much of the subsequent work. He classifies systems into nine types:
Revision as of 20:04, 20 May 2019
This article forms part of the Systems Fundamentals knowledge area (KA). It provides various perspectives on system classifications and types of systems, expanded from the definitions presented in What is a System?.
The modern world has numerous kinds of systems that influence daily life. Some examples include transport systems; solar systems; telephone systems; the Dewey Decimal System; weapons systems; ecological systems; space systems; etc. Indeed, it seems there is almost no end to the use of the word “system” in today’s society.
This article considers the different classification systems which some systems science authors have proposed in an attempt to extract some general principles from these multiple occurrences. These classification schemes look at either the kinds of elements from which the system is composed or its reason for existing.
The idea of an engineered system is expanded. Four specific types of engineered system context are generally recognized in systems engineering: product system, service system, enterprise system and system of systems.
A taxonomy is "a classification into ordered categories" (Dictionary.com 2011). Taxonomies are useful ways of organizing large numbers of individual items so their similarities and differences are apparent. No single standard systems taxonomy exists, although several attempts have been made to produce a useful classification taxonomy, e.g. (Bertalanffy 1968) and (Miller 1986).
Kenneth Boulding (Boulding 1956), one of the founding fathers of general system theory, developed a systems classification which has been the starting point for much of the subsequent work. He classifies systems into nine types:
- Structures (Bridges)
- Clock works (Solar system)
- Controls (Thermostat)
- Open (Biological cells)
- Lower organisms (Plants)
- Animals (Birds)
- Man (Humans)
- Social (Families)
- Transcendental (God)
These approaches also highlight some of the subsequent issues with these kinds of classification. Boulding implies that physical structures are closed and natural while social ones are open. However, a bridge can only be understood by considering how it reacts to traffic crossing it, and it must be sustained or repaired over time (Hitchins 2007). Boulding also separates humans from animals, which would not fit into more modern thinking.
Peter Checkland (Checkland 1999, 111) divides systems into five classes: natural systems, designed physical systems, designed abstract systems, human activity systems and transcendental systems. The first two classes are self-explanatory.
- Designed abstract systems – These systems do not contain any physical artifacts but are designed by humans to serve some explanatory purpose.
- Human activity systems – These systems are observable in the world of innumerable sets of human activities that are more or less consciously ordered in wholes as a result of some underlying purpose or mission. At one extreme is a system consisting of a human wielding a hammer. At the other extreme lies international political systems.
- Transcendental systems – These are systems that go beyond the aforementioned four systems classes, and are considered to be systems beyond knowledge.
Checkland refers to these five systems as comprising a “systems map of the universe”. Other, similar categorizations of system types can be found in (Aslaksen 1996), (Blanchard 2005) and (Giachetti 2009).
Magee and de Weck (Magee and de Weck 2004) provide a comprehensive overview of sources on system classification such as (Maier and Rechtin 2009), (Paul 1998) and (Wasson 2006). They cover some methods for classifying natural systems, but their primary emphasis and value to the practice of systems engineer is in their classification method for human-designed, or man-made, systems. They examine many possible methods that include: degree of complexity, branch of the economy that produced the system, realm of existence (physical or in thought), boundary, origin, time dependence, system states, human involvement / system control, human wants, ownership and functional type. They conclude by proposing a functional classification method that sorts systems by their process (transform, transport, store, exchange, or control), and by the entity that they operate on matter, energy, information and value.
Types of Engineered System
Figure 1: General types of Engineered System of Interest (SoI) (SEBoK original)
Figure 1 shows four general cases of SoI which might be the focus of a life cycle.
- A technology focused system of interest (SoI) embedded within one or more products,
- A integrated technology product SoI used directly to help provide a service,
- An enabling services SoI supporting multiple service systems
- A service system SoI created and sustained to directly deliver capability.
Products and Product Systems
The word product is defined as "a thing produced by labor or effort; or anything produced" (Oxford English Dictionary). In a commercial sense a product is anything which is acquired, owned and sustained by an [[Organization (glossary}]] and used by an enterprise (hardware, software, information, personnel, etc.).
A product systems is an engineered systems in which the focus of the life cycle is to developed and delivered products to an acquirer for internal or external use to directly support the delivery of services needed by that acquirer.
A product systems life cycle context will describe a technology focused SoI plus the related products, people and services with which the SoI is required to interact. Note, product system users (e,g, operators, maintainers, producers, etc.) sit outside of the product SoI, since they are not delivered as part of the product. However, to develop a successful product it is essential to fully understand its human interfaces and influences. The product context will also define the service systems within which it will be deployed to help provide the necessary capability to the acquiring enterprise.
In a product life cycle this wider context defines the fixed and agreed relationships within which the SoI must operate, and the environmental influences within which the life cycle must be delivered. This gives the product developer the freedom to make solution choices within that context and to ensure these choices fit into and do not disrupt the wider context.
A product life cycle may need to recommend changes to enabling services such as recruitment and training of people or other infrastructure. Appropriate mechanisms for the implementation of these changes must be part of the agreement between acquirer and supplier and be integrated into the product life cycle. A product life cycle may also suggest changes in the wider context which would enhance the products ownership or use, but those changes need to be negotiated and agreed with the relevant owners of the system elements they relate to before they can be added to the life cycle outputs.
A more detailed discussion of the system theory associated with product systems can be found in History of Systems Science and an expansion of the application of systems engineering to service systems in the Product Systems Engineering KA in Part 4.
Services and Service Systems
A service can be simply defined as an act of help or assistance, or as any outcome required by one or more users which can be defined in terms of outcomes and quality of service without detail to how it is provided (e.g., transport, communications, protection, data processing, etc.). Services are processes, performances, or experiences that one person or organization does for the benefit of another, such as custom tailoring a suit; cooking a dinner to order; driving a limousine; mounting a legal defense; setting a broken bone; teaching a class; or running a business’s information technology infrastructure and applications. In all cases, service involves deployment of knowledge and skills (competencies) that one person or organization has for the benefit of another (Lusch and Vargo 2006), often done as a single, customized job. TO be successful, service requires substantial input from the client and related stakeholder, often referred to as the co-creation of value (Sampson 2001). For example, how can a steak be customized unless the customer tells the waiter how the customer wants the steak prepared?
A service system is an engineered system that provides outcomes for users within an enterprise. A service system context contains the same kinds of system elements as a product system context, but allows greater freedom for what can be created or changed to deliver the required service.
A service system life cycle may deliver changes to how existing products and other services are deployed and used. It may also identify the need to modify existing products or create new products, in which case it may initiate a related product life cycle. In most cases the service developer will not have full freedom to change all aspects of the service system context without some negotiation with related system element owners. In particular people and infrastructure are part of the service context and changes to how system elements are used to provide desired outcomes are part of the service life cycle scope.
The description of product system context above might be viewed as a special case of a service system context in which a specific product is created and integrated into a fixed service system and used by the owner of that service system to provide a capability.
In a general service system context it is not necessary to deliver all hardware or software products to the service provider. The hardware, software or human elements may be owned by a third party who is not responsible for the service directly, but provides enabling outputs to a number of such services. Nor is it necessary for the exact versions of products to be defined and integrated prior the service delivery. Some service system elements can be selected and integrated closer to the point of use. To allow for this late configuration of a service system it will contain some method of discovery, by which appropriate available elements can be found, and an overall service control element to implement and direct each version of the service. The use of a service system approach gives greater freedom for acquirers in how they obtain and support all of the capital equipment and software in order to obtain the capabilities needed to satisfy users.
Services have been part of the language of systems engineering (SE) for many years. The use of the term service system in more recent times is often associated with software configurable and information intensive systems, i.e.,
...unique features that characterize services – namely, services, especially emerging services, are information-driven, customer-centric, e-oriented, and productivity-focused. (Tien and Berg 2003, 13)
A more detailed discussion of the system theory associated with service systems can be found in History of Systems Science and an expansion of the application of systems engineering to service systems in the Service Systems Engineering KA in Part 4.
Enterprises and Enterprise Systems
An enterprise is one or more organizations or individuals sharing a definite mission, goals, and objectives to offer an output such as a product or service.
An enterprise system consists of a purposeful combination (network) of interdependent resources (e.g., people; processes; organizations; supporting technologies; and funding) that interact with each other (e.g., to coordinate functions; share information; allocate funding; create workflows; and make decisions), and their environment(s), to achieve business and operational goals through a complex web of interactions distributed across geography and time (Rebovich and White 2011, 4, 10, 34-35).
Both product and service systems require an enterprise system to create them and an enterprise to use the product system to deliver services either internally to the enterprise or externally to a broader community.
Enterprise systems are unique, compared to product and service systems, in that they are constantly evolving; they rarely have detailed configuration controlled requirements; they typically have the goal of providing shareholder value and customer satisfaction, which are constantly changing and are difficult to verify; and they exist in a context (or environment) that is ill-defined and constantly changing.
While an enterprise system cannot be described using the general system context above, an enterprise may wish to create a model of the capabilities and services it needs to achieve its strategy and goals. Such a model can be extended to describe a baseline of service system and product system contexts related to its current capabilities, and to proposed future capabilities. These are referred to as enterprise architectures or enterprise reference architectures.
A more detailed discussion of the system theory associated with service systems can be found in History of Systems Science and an expansion of the application of systems engineering to service systems in the Enterprise Systems Engineering KA in Part 4. The notion of enterprises and enterprise systems also permeates Part 5 Enabling Systems Engineering.
Systems of Systems
A product, service or enterprise context can be defined as a hierarchy of system elements, with the additional definition of which elements are part of a SoI solution, which form the related problem context and which influence any life cycle associated with that context. The additional concepts of a Systems of Systems (SoS) or Federations of Systems (FoS) is used for some life cycle contexts In terms of the general description in figure 1 above this would apply to any life cycle context in which elements within the SoI have independent life cycle relationships. This concept could apply to any of the life cycle contexts above, although it is of particular relevance to the service and enterprise contexts.
It is important to understand that the term SoS is an addition to the general concept of system hierarchy that applies to all system. Maier examined the meaning of System of Systems in detail and used a characterization approach which emphasizes the independent nature of the system element, rather than “the commonly cited characteristics of systems-of-systems (complexity of the component systems and geographic distribution) which are not the appropriate taxonomic classifiers” (Maier 1998, 268). Maier describes both independence in how a system element operates (e.g. an element in the SoI also has its own separate mission or is part of another SoI) and in how an element is developed or sustained (e.g. an element is made available, modified or configured by a different organization to the one responsible for the rest of SoI).
There are advantages to being able to have elements shared across a number of engineered systems and to being able to created to quickly create solutions to problems by combining existing engineered systems. As the technology to enable integration of independent systems becomes more common this SoS approach is becoming a common aspect of many SE life cycle.
Wherever system elements in an engineered system context have any degree of independence from the SoI life cycle this adds a further complexity; specifically, by constraining how the resulting engineered system can be changed or controlled. This dimension of complexity affects the management and control aspects of the systems approach.
A more detailed discussion of the different system grouping taxonomies developed by systems science can be found in Part 4 Applications of Systems Engineering) and an expansion of the ways we deal with SoS complexity can be found n the System of Systems KA in part 4.
Applying Engineered System Contexts
From the discussions of product and service contexts above it should be clear that they require similar systems understanding to be successful and that the difference between them is more about the scope of life cycle choices and the authority to make changes. They are also presented here as generalizations of the system engineering approach. All real projects will have both product and service system dimensions to them. In this general view of engineered systems there is always an enterprise system directly interested in the service system context and either directly owning and operating any product systems or gaining access to product systems as needed. This enterprise system may be explicitly involved in initiating and managing an engineering system life cycle, or may be implicit in the shared ownership of a problem situation. Any engineered system context may have aspects of the SoS independence discussed above. This may be part of the context in the wider system or environment or it may be related to the choice of elements within the SoI.
A real SE life cycle typically combines different aspects of these general contexts into a unique problem and solution context and associated acquirer and supplier commercial relationships. These must be identified by that life cycle as part of its SE activities. More details of these different life cycle contexts are given in part 2 and how these apply to SE practice is expanded in Part 4.
A good example of a general description of the above is given by Ring (ref), who defines the overall context as the Problem Suppression System, and describes a cycle by which an enterprise will explore its current needs, use these to identify one or more life cycle interventions, relevant organisations then conduct and deliver those life cycles, integrate their outputs into the PSS, the enterprise can then review the results in the environment and begin the cycle again.
This general systems approach is described in part 2 and used as a focus to identify areas of foundational knowledge. The current practices of SE described in the rest of the SEBoK make reference to these foundations as appropriate.
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