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This article summarizes the primary principles and concepts generally used to describe [[System (glossary)|Systems (glossary)]].
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'''''Lead Author:''''' ''Rick Adcock'', '''''Contributing Authors:''''' ''Gary Smith''
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This knowledge area (KA) provides a guide to some of the major developments in {{Term|Systems Science (glossary)|systems science}}, which is an interdisciplinary field of science that studies the nature of {{Term|Complex (glossary)|complex}} {{Term|System (glossary)|systems}} in nature, society, and {{Term|Engineering (glossary)|engineering}}.  
  
==Principles and Concepts==
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This is part of the wider systems knowledge which can help to provide a common language and intellectual foundation, and make practical systems {{Term|Concept (glossary)|concepts}}, {{Term|Principle (glossary)|principles}}, {{Term|Pattern (glossary)|patterns}} and tools accessible to {{Term|Systems Engineering (glossary)|systems engineering}} (SE) as discussed in the [[Foundations of Systems Engineering|Introduction to Part 2]]. 
  
[[General System Theory (glossary)]] (von Bertalanffy, 1968) considers the similarities between systems from different domain as a set of common systems principles and concepts.  GST allows us to make comparisons between system based on different technologies; judge the goodness or completeness of a system and develop domain independent systems approaches which can form the basis of disciplines such as Systems Engineering.
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==Topics==
 
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Each part of the SEBoK is divided into KAs, which are groupings of information with a related theme. The KAs, in turn, are divided into topics. This KA contains the following topics:
*A '''principle''' is a rule of conduct or behavior.  To take this further we can say that a principle is a “basic generalization that is accepted as true and that can be used as a basis for reasoning or conduct.” [WordWeb.com]  A principle can also be thought of as a “basic truth or law or assumption.” [ibid.] 
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* [[History of Systems Science]]
 
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* The origins of [[Systems Approaches]]
*A '''concept''' is an abstraction; a general idea inferred or derived from specific instances.  For example, we look at our pet dog and we can infer that there are other dogs of that “type.”  Hence, from this observation (or perhaps a set of observations) we develop a concept of a dog in our mind. Concepts are bearers of meaning, as opposed to agents of meaning and can only be thought about, or designated, by means of a name.
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* [[Complexity]]
 
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* [[Emergence]]
Principles depend on concepts in order to state this “truth.”  Hence, principles and concepts go hand in hand; principles cannot exist without concepts and concepts are not very useful without principles to help us understand the proper way to act (Lawson and Martin 2008).
 
 
 
GST tends to concentrate on the principles and philosophy behind this idea.  “''Despite the importance of system concepts … we do not yet have a unified or integrated set (i.e. a system) of such concepts''” (Ackoff, 1971).
 
 
 
While many researchers and practitioners have created GST concepts, these tend to be a stepping stone to theories and approaches.  This situation is made worse by the variety of domains and disciplines in which systems research is conducted and reported.  Ackoff proposes a '''system of "system concepts"''' to bring together the wide variety of concepts which have been proposed.  His 30 distinct concepts are grouped under four headings, or principles, “'''How Systems are formed'''”; “'''How Systems Change'''”; “'''How Systems Behave'''” and “'''How Systems Adapt and Learn'''”.
 
 
 
Lawson describes a system of "system concepts" (Lawson 2010) where systems are categorized according to Fundamental concepts, Types, Topologies, Focus, Complexity and Roles. Hitchins (Hitchins, 2009) defines a similar set of principles which also consider some of the issues of hierarchy and complexity of particular relevance to a system approach.
 
  
In this Knowledge area we will identify a set of '''System Principles''', against which the important System Concepts taken from a range of [[System Science (glossary)]] sources have been described.  These concepts form a set of axioms, assumptions, and premises which can be applied to both the understanding of [[Natural System (glossary)| Natural Systems (glossary)]] and [[Social System (glossary)|Social Systems (glossary)]]; and to the understanding and/or intervention in [[Engineered System (glossary) | Engineered Systems (glossary)]] or [[Sociotechnical System (glossary)|Sociotechnical Systems (glossary)]].  
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==Introduction==
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Systems science brings together research into all aspects of systems with the goal of identifying, exploring, and understanding patterns of {{Term|Complexity (glossary)|complexity}} and {{Term|Emergence (glossary)|emergence}} which cross disciplinary fields and areas of application. It seeks to develop interdisciplinary foundations which can form the basis of theories applicable to all types of systems, independent of {{Term|Element (glossary)|element}} type or application; additionally, it could form the foundations of a meta-discipline unifying traditional scientific specialisms. 
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The [[History of Systems Science]] article describes some of the important multidisciplinary fields of research of which systems science is composed.
  
The System Principles are summarized here, and used to organize the concepts in the [[Overview of System Concepts]]:
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A second article presents and contrasts the underlying theories and origins behind some of the classic {{Term|Systems Approach (glossary)|system approaches}} taken in applying systems science to real problems.
  
#'''Wholeness''': all systems are formed from groups of related elements into a whole with an observable shared identity in an environment.
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People who think and act in a systems way are essential to the success of both research and practice. Successful systems research will not only apply {{Term|Systems Thinking (glossary)|systems thinking}} to the topic being researched but should also consider a systems thinking approach to the way the research is planned and conducted. It would also be of benefit to have people involved in research who have, at a minimum, an awareness of system practice and ideally are involved in practical applications of the theories they develop.
#'''Behavior''': all systems exhibit behaviors resulting from the interaction between elements.
 
#'''Survival Behavior''': all systems have one or more stable state, and will act to sustain those states against environmental pressures of 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 mechanism to guide their behaviors.
 
#'''Effectiveness''': some systems are able to assess their effectiveness against a desired objective and to adaption and learn to sustain and improve that effectiveness
 
#'''Hierarchy''': all systems form hierarchical structures, additional behaviors will 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.
 
 
 
One of the purposes of this part of the SEBoK is to identify those aspects of systems science which apply to Systems Engineering, through the application a [[Systems Approach (glossary)]] within a defined [[System Context (glossary)]].  The topics of Hierarchy, Complexity and Emergence help us to identify which system need a Systems Approach, and how to tailor that approach to suit the kinds of problem and appropriate solutions.
 
 
 
==Topics==
 
The topics contained within this knowledge area include:
 
*[[Overview of System Concepts]]
 
*[[System Context]]
 
*[[Complexity]]
 
*[[Emergence]]
 
  
 
==References==
 
==References==
  
===Citations===
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===Works Cited===
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None.
  
von Bertalanffy, L. 1968. General system theory: Foundations, development, applications. Revised ed. New York, NY: Braziller.
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===Primary References===
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Checkland, P. 1999. ''[[Systems Thinking, Systems Practice]].'' New York, NY, USA: John Wiley & Sons.
  
Ackoff, R.L. 1971. Towards a System of Systems Concepts, Management Science, Vol.17 No. 11, USA.
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Bertalanffy, L. von. 1968. ''[[General System Theory: Foundations, Development, Applications]],'' Revised ed. New York, NY, USA: Braziller.
  
Hitchins, Derek. 2009. What are the General Principles Applicable to Systems? Insight, 59-63.
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Flood, R.L. 1999. ''[[Rethinking the Fifth Discipline]]: Learning within the Unknowable.'' London, UK: Routledge.
 
 
Lawson, H., and Martin, J. N. 2008. On the Use of Concepts and Principles
 
for Improving Systems Engineering Practice, INCOSE, Proceedings of the INCOSE International Conference, Utrecht.
 
 
 
Lawson, H. 2010. A Journey Through the Systems Landscape. London: College Publications, Kings College.
 
 
 
===Primary References===
 
Checkland, P. 1999. [[Systems Thinking, Systems Practice]], New York, John Wiley & Sons.
 
  
Hitchins, D. 2007. [[Systems Engineering: A 21st Century Systems Methodology]]. Hoboken, NJ, USA: John Wiley & Sons.
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===Additional References===
  
Hitchins, Derek. 2009. [[What are the General Principles Applicable to Systems?]] Insight, 59-63.
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None.
  
Page, S. E. 2009. [[Understanding Complexity]]. The Great Courses. Chantilly, VA, USA: The Teaching Company.
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Sheard, S. A. & Mostashari, A. 2008. [[Principles of Complex Systems for Systems Engineering]]. Systems Engineering, 12, 295-311.
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==Article Discussion==
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[[{{TALKPAGENAME}}|[Go to discussion page]]]
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[[Category:Part 2]][[Category:Knowledge Area]][[Category:Systems Science]]
<center>[[Systems Thinking|<- Previous Article]] | [[Systems|Parent Article]] | [[Overview of System Concepts|Next Article ->]]</center>
 
==Signatures==
 
--[[User:Radcock|Radcock]] 19:19, 15 August 2011 (UTC)
 
[[Category:Part 2]][[Category:Knowledge Area]]
 

Latest revision as of 23:19, 2 May 2024


Lead Author: Rick Adcock, Contributing Authors: Gary Smith


This knowledge area (KA) provides a guide to some of the major developments in systems sciencesystems science, which is an interdisciplinary field of science that studies the nature of complexcomplex systemssystems in nature, society, and engineeringengineering.

This is part of the wider systems knowledge which can help to provide a common language and intellectual foundation, and make practical systems conceptsconcepts, principlesprinciples, patternspatterns and tools accessible to systems engineeringsystems engineering (SE) as discussed in the Introduction to Part 2.

Topics

Each part of the SEBoK is divided into KAs, which are groupings of information with a related theme. The KAs, in turn, are divided into topics. This KA contains the following topics:

Introduction

Systems science brings together research into all aspects of systems with the goal of identifying, exploring, and understanding patterns of complexitycomplexity and emergenceemergence which cross disciplinary fields and areas of application. It seeks to develop interdisciplinary foundations which can form the basis of theories applicable to all types of systems, independent of elementelement type or application; additionally, it could form the foundations of a meta-discipline unifying traditional scientific specialisms.

The History of Systems Science article describes some of the important multidisciplinary fields of research of which systems science is composed.

A second article presents and contrasts the underlying theories and origins behind some of the classic system approachessystem approaches taken in applying systems science to real problems.

People who think and act in a systems way are essential to the success of both research and practice. Successful systems research will not only apply systems thinkingsystems thinking to the topic being researched but should also consider a systems thinking approach to the way the research is planned and conducted. It would also be of benefit to have people involved in research who have, at a minimum, an awareness of system practice and ideally are involved in practical applications of the theories they develop.

References

Works Cited

None.

Primary References

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

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

Flood, R.L. 1999. Rethinking the Fifth Discipline: Learning within the Unknowable. London, UK: Routledge.

Additional References

None.


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