Introduction to Systems Engineering Fundamentals

System Science View

How can we take the many connotations of the word “system” in everyday use and turn them into a theoretical framework capable of supporting the application of systems thinking in such a way that it can be usefully applied across all potential application domains and disciplines?

The basic ideas of a system whole can be traced back to the thinking of Aristotle and culminate in the works of the philosopher Hegel (M’Pherson 1974). Hegel’s view of holism states that an individual as part of an organic whole is fully realized only through his relationship to the whole. Humans have used this idea to help explain the relationship between abstract ideas by describing them as a system of related concepts, rules, or ideas. Some examples of systems are the natural number system and political systems. We also identify systems as a combination of elements with some relationship(s) which can be best understood by considering them as a whole.

General Systems Theory (GST) (von Bertalanffy 1968) considers the similarities between systems from different domains as a set of common system principles and concepts. The generally agreed upon systems science (glossary) definition of a system is “a set of related elements that form an integrated whole.” A system exists in an environment which contains related systems and conditions:

A closed system has no relationship(s) with its environment.
An open system shares input and output with its environment across the boundary.

System elements may be conceptual organizations of ideals in symbolic form or real objects, e.g., people, data, physical artifacts, etc.

Abstract systems contain only conceptual elements.
Concrete systems contain at least two elements which are objects.

This simple idea is then further elaborated through a set of principles and concepts. The following system principles, derived from GST, relate directly to the definition of a system:

Wholeness: All systems are formed from groups of related elements into a whole with an observable shared identity in an environment.
Behavior: All systems exhibit behaviors resulting from the interaction between elements.
Survival Behavior: All systems have one or more stable states and will act to sustain those states against environmental pressures or disturbances.
Goal Seeking Behavior: Some systems will exhibit more complex combinations of behavior to create the functions needed to complete specific goals or broader objectives.
Control: All systems have regulation and control mechanisms to guide their behaviors.
Effectiveness: Some systems are able to assess their effectiveness against a desired objective and adapt. These systems learn to sustain and improve that effectiveness.
Hierarchy: All systems form hierarchical structures and will exhibit additional behaviors that emerge within the hierarchy due to interactions between system elements.
Complexity: At some levels of a hierarchy, systems are sufficiently complex that they can only be understood, used, or changed through a systems approach.

Thus, a collection of elements which tend to group together will form themselves into coherent wholes. Once formed, they will tend to stay in those structures, combine, and evolve further into more complex stable states. Systems exploit this cohesion to sustain themselves in the face of threats or environmental pressures. Some systems are created by people for specific reasons, and will need to not only exist and survive, but also achieve necessary outcomes.

These system principles and associated concepts, related to all kinds of systems, are described in more detail in the system concepts (glossary) knowledge area.

The Scope of Systems

The modern world has numerous kinds of systems that influence daily life. Some examples of the way the word "system" is used in everyday society are transport systems, solar systems, telephone systems, the Dewey Decimal System, weapons systems, ecological systems, space systems, and so on; indeed it seems there is almost no end to the use of the word “system” in today’s society.

Using the basic system science definition of a system , we can relate this to the real world through three related system domains as follows:

System Boundaries of Engineered Systems, Social Systems, and Natural Systems (Figure Developed for BKCASE)

natural systems are real world phenomena to which we apply system thinking to help us better understand what they do and how they do it. A truly natural system would be a system we can observe and reason about, but over which we cannot exercise control, such as the solar system. As shown above, there are some managed natural systems which fall under the scope of one or both of the other domains. For engineered systems (ES) and social systems (SS), the best way to define the domain scope is to identify the types of systems for which we have authority to commit and manage resources for system creation and sustainment, as well as take responsibility for the results. Purely technical systems, such as bridges, electric autos, and power generation and distribution systems are exclusively in the ES domain, while purely human systems, such as legislatures, conservation foundations, and the United Nations (UN) Security Council are exclusively in the SS domain. These systems are purely human artifacts created to help us gain some kind of control over, or protection from, the real world. In System Science terms they are concrete, open Systems.

Systems common to both the SS and ES domains such as water and power management and safety governance systems, and water and power safety assurance systems, are often called sociotechnical systems . The systems common to the ES and NS domains such as dams and flood control systems might equally be termed as environ-technical systems, although the term sociotechnical is often extended to cover both. The behavior of such systems is determined both by the nature of the engineered elements, and by their ability to integrate with or deal with the variability of the natural and social systems in which they sit. The ultimate success of any engineered system is thus measured in its ability to contribute to the success of relevant socio (or enviro) technical systems.

System Definitions – a discussion

How is asystem defined in the systems engineering literature? Systems engineers generally refer to their system of interest (SoI) as “the system,” and their definitions of “system” tend to characterize engineered systems. Two examples are:

“A system is an array of components designed to accomplish a particular objective according to plan” (Johnson, Kast, and Rosenzweig 1963).
“A system is defined as a set of concepts and/or elements used to satisfy a need or requirement” (Miles 1973).

The INCOSE Handbook generalizes this idea of an engineered system as “An interacting combination of elements to accomplish a defined objective. These include hardware, software, firmware, people, information, techniques, facilities, services, and other support elements” (INCOSE 2011).

However, engineered systems often find that their environment includes natural systems that don’t follow the definitions of a “system” above in that they have not been defined to satisfy a requirement or come into being to satisfy a defined objective. These include such systems as the solar system if one’s engineered system is an interplanetary spacecraft. This has led to more general definitions of a system following the system science approach, such as the following (Aslaksen 2004): A system consists of three related sets:

A set of elements.
A set of internal interactions between the elements.
A set of external interactions between one or more elements and the external world, i.e., interactions that can be observed from outside the system.

This definition of a system enables people to reason about numerous classes of dynamical systems that involve engineered, social, and natural systems.

Fundamental properties of a system described in the systems engineering literature include togetherness, structure, behavior, and emergence. These properties provide one perspective on what a system is: “We believe that the essence of a system is togetherness, the drawing together of various parts and the relationships they form in order to produce a new whole…” (Boardman and Sauser 2008). Hitchins refers to this systems property as cohesion (Hitchins 2009, 59-63).

The joining together of various parts (elements) can be related to either the structure of a system or to the behavior of a system. The structure of a system is the static existence of the system, namely its elements and their relationships, whereas system behavior refers to the effect produced when an instance of the system is in operation. The actual behavior produced in operation leads to the fundamental property of emergence: “Whole entities exhibit properties which are meaningful only when attributed to the whole, not to its parts…” (Checkland 1999).

Natural systems and social systems often form part of the environment in which engineered systems need to exist. For a natural or social system, simply continuing to exist, and when appropriate, to adapt and grow, is sufficient. Man-made, engineered, and sociotechnical systems are created with a defined purpose (Hitchins, 2009). Thus, they must not only be able to exist within their environment, but also to do what is necessary to achieve that purpose.

System Context

As can be seen from the discussion above, most attempts to define the term “system” either include assumptions about the system domain being considered, or are attempts to take a system science view. We need to make a clear distinction between defining "the system" to which we wish to apply a systems approach and defining "systems" as an abstract idea which we can use to help understand complex situations.

The reason we use the concept of a system is to help make sense of the complexity of the real world. This is done either by creating an abstract system to help explain complex situations, such as the real number system; by creating a standardized approach to common problems, such as the Dewey Decimal System; or by agreeing on a model of a new situation to allow further exploration, such as a scientific theory or conceptual system design. People use systems to make sense of complexity in an individual way and when they work together to solve problems.

In the systems approach we may consider a number of relevant systems to fully explore problems and solutions, and a given element may be included in several system views. Thus, it is less important that we can define “the system” than it is that we can use combinations of systems to help achieve engineering or management tasks.

We use the idea of a system context to define an engineered system of interest (soi) , and to capture and agree the important relationships between it, the systems it works directly with, and the systems which influence it in some way. This engineered system context relates to the system science ideas of an open, concrete system, although such a system may include abstract system elements. There are a number of more detailed system concepts (glossary) which the systems approach must also consider, such as static or dynamic, deterministic or non-deterministic, chaotic or homeostatic, complexity and adaptation, feedback and control, and more.

All applications of a systems approach (and hence of systems engineering) are applied to an engineered system context, and not to an individual system.

References

Citations

Alaksen,E. 2004. "A Critical Examination of the Foundations of Systems Engineering Tutorial". Paper presented at 14th Annual International Council on Systems Engineering (INCOSE) International Symposium, 20-24 June 2004, Toulouse, France.

Boardman, J. and Sauser, B. 2008. Systems Thinking: Coping with 21st Century Problems. Boca Raton, FL, USA: Taylor & Francis Inc.

Checkland, P. 1999. Systems Thinking, Systems Practice. New York, NY, USA: John Wiley & Sons.

Hitchins, Derek. 2009. "What are the General Principles Applicable to Systems?", Insight, VOL & ISSUE 59-63.

INCOSE. 2011. INCOSE Systems Engineering Handbook. Version 3.2.1. International Council on Systems Engineering. INCOSE-TP-2003-002-03.2.1

Johnson, R.A. 1963. F.W. Kast, and J.E. Rosenzweig, The Theory and Management of Systems, McGraw-Hill. NEED TO COMPLETE

Miles, R.F. (ed.)1973. System Concepts, Wiley. NEED TO COMPLETE

M’Pherson, P, K. 1974. "A perspective on systems science and systems philosophy". Futures 6(3), June 1974, p. 219-239.

von Bertalanffy, L. 1968. General system theory: Foundations, Development, Applications. Revised ed. New York, NY, USA: Braziller.

Primary References

INCOSE 2011, INCOSE Systems Engineering Handbook Issue 3.2.1 INCOSE-TP-2003-002-03.2.1

von Bertalanffy, L. 1968. General System Theory: Foundations, Development, Applications. Revised ed. New York, NY: Braziller.

Additional References

No additional references have been identified for version 0.5. Please provide any recommendations on additional references in your review.

Article Discussion

[Go to discussion page]

<- Previous Article | Parent Article | Next Article ->

Signatures

--Radcock 15:55, 15 August 2011 (UTC)

--Lee 11:59, 21 August 2011 (UTC)