Cybernetics is a transdisciplinary approach for exploring regulatory systems—their structures, constraints, and possibilities. Norbert Wiener defined cybernetics in 1948 as "the scientific study of control and communication in the animal and the machine." In other words, it is the scientific study of how humans, animals and machines control and communicate with each other.
Cybernetics is applicable when a system being analyzed
incorporates a closed signaling loop—originally referred to as a
"circular causal" relationship—that is, where action by the system
generates some change in its environment and that change is reflected in
the system in some manner (feedback) that triggers a system change. Cybernetics is relevant to, for example, mechanical, physical, biological, cognitive, and social systems.
The essential goal of the broad field of cybernetics is to understand
and define the functions and processes of systems that have goals and
that participate in circular, causal chains
that move from action to sensing to comparison with desired goal, and
again to action. Its focus is how anything (digital, mechanical or
biological) processes information, reacts to information, and changes or
can be changed to better accomplish the first two tasks. Cybernetics includes the study of feedback, black boxes and derived concepts such as communication and control in living organisms, machines and organizations including self-organization.
Concepts studied by cyberneticists include, but are not limited to: learning, cognition, adaptation, social control, emergence, convergence, communication, efficiency, efficacy, and connectivity. In cybernetics these concepts (otherwise already objects of study in other disciplines such as biology and engineering) are abstracted from the context of the specific organism or device.
The word cybernetics comes from Greek κυβερνητική (kybernētikḗ), meaning "governance", i.e., all that are pertinent to κυβερνάω (kybernáō), the latter meaning "to steer, navigate or govern", hence κυβέρνησις (kybérnēsis), meaning "government", is the government while κυβερνήτης (kybernḗtēs)
is the governor or "helmperson" of the "ship". Contemporary cybernetics
began as an interdisciplinary study connecting the fields of control systems, electrical network theory, mechanical engineering, logic modeling, evolutionary biology, neuroscience, anthropology, and psychology in the 1940s, often attributed to the Macy Conferences.
During the second half of the 20th century cybernetics evolved in ways
that distinguish first-order cybernetics (about observed systems) from second-order cybernetics (about observing systems). More recently there is talk about a third-order cybernetics (doing in ways that embraces first and second-order).
Studies in cybernetics provide a means for examining the design
and function of any system, including social systems such as business
management and organizational learning, including for the purpose of
making them more efficient and effective. Fields of study which have influenced or been influenced by cybernetics include game theory, system theory (a mathematical counterpart to cybernetics), perceptual control theory, sociology, psychology (especially neuropsychology, behavioral psychology, cognitive psychology), philosophy, architecture, and organizational theory. System dynamics, originated with applications of electrical engineering control theory to other kinds of simulation models (especially business systems) by Jay Forrester at MIT in the 1950s, is a related field.
Definitions
Cybernetics has been defined in a variety of ways, by a variety of people, from a variety of disciplines.
Cybernetician Stuart Umpleby reports some notable definitions:
- "Science concerned with the study of systems of any nature which are capable of receiving, storing and processing information so as to use it for control."—A. N. Kolmogorov
- "'The art of steersmanship': deals with all forms of behavior in so far as they are regular, or determinate, or reproducible: stands to the real machine -- electronic, mechanical, neural, or economic -- much as geometry stands to real object in our terrestrial space; offers a method for the scientific treatment of the system in which complexity is outstanding and too important to be ignored."—W. Ross Ashby
- "A branch of mathematics dealing with problems of control, recursiveness, and information, focuses on forms and the patterns that connect."—Gregory Bateson
- "The art of securing efficient operation [lit.: the art of effective action]."—Louis Couffignal
- "The art of effective organization."—Stafford Beer
- "The art and science of manipulating defensible metaphors" (with relevance to constructivist epistemology. The author later extended the definition to include information flows "in all media", from stars to brains.)—Gordon Pask
- "The art of creating equilibrium in a world of constraints and possibilities."—Ernst von Glasersfeld
- "The science and art of understanding." – Humberto Maturana
- "The ability to cure all temporary truth of eternal triteness."—Herbert Brun
Other notable definitions include:
- "The science and art of the understanding of understanding."—Rodney E. Donaldson, the first president of the American Society for Cybernetics
- "A way of thinking about ways of thinking of which it is one."—Larry Richards
- "The art of interaction in dynamic networks."—Roy Ascott
- "The study of systems and processes that interact with themselves and produce themselves from themselves."—Louis Kauffman, President of the American Society for Cybernetics
Etymology
The term cybernetics stems from κυβερνήτης (cybernḗtēs)
"steersman, governor, pilot, or rudder". As with the ancient Greek
pilot, independence of thought is important in cybernetics. French physicist and mathematician André-Marie Ampère first coined the word "cybernetique" in his 1834 essay Essai sur la philosophie des sciences to describe the science of civil government. The term was borrowed by Norbert Wiener, in his book Cybernetics, to define the study of control and communication in the animal and the machine.
History
Roots of cybernetic theory
The word cybernetics was first used in the context of "the study of self-governance" by Plato in Alcibiades to signify the governance of people. The word 'cybernétique' was also used in 1834 by the physicist André-Marie Ampère (1775–1836) to denote the sciences of government in his classification system of human knowledge.
The first artificial automatic regulatory system was a water clock, invented by the mechanician Ktesibios;
based on a tank which poured water into a reservoir before using it to
run the mechanism, it used a cone-shaped float to monitor the level of
the water in its reservoir and adjust the rate of flow of the water
accordingly to maintain a constant level of water in the reservoir. This
was the first artificial truly automatic self-regulatory device that
required no outside intervention between the feedback and the controls
of the mechanism. Although they considered this part of engineering (the
use of the term cybernetics is much posterior), Ktesibios and others such as Heron and Su Song are considered to be some of the first to study cybernetic principles.
The study of teleological mechanisms (from the Greek τέλος or télos for end, goal, or purpose) in machines with corrective feedback dates from as far back as the late 18th century when James Watt's steam engine was equipped with a governor (1775–1800), a centrifugal feedback valve for controlling the speed of the engine. Alfred Russel Wallace identified this as the principle of evolution in his famous 1858 paper. In 1868 James Clerk Maxwell
published a theoretical article on governors, one of the first to
discuss and refine the principles of self-regulating devices. Jakob von Uexküll applied the feedback mechanism via his model of functional cycle (Funktionskreis) in order to explain animal behaviour and the origins of meaning in general.
Early 20th century
Contemporary cybernetics began as an interdisciplinary study connecting the fields of control systems, electrical network theory, mechanical engineering, logic modeling, evolutionary biology and neuroscience in the 1940s; the ideas are also related to the biological work of Ludwig von Bertalanffy in General Systems Theory. Electronic control systems originated with the 1927 work of Bell Telephone Laboratories engineer Harold S. Black on using negative feedback to control amplifiers.
Early applications of negative feedback in electronic circuits included the control of gun mounts and radar antenna during World War II. The founder of System Dynamics, Jay Forrester, worked with Gordon S. Brown
during WWII as a graduate student at the Servomechanisms Laboratory at
MIT to develop electronic control systems for the U.S. Navy. Forrester
later applied these ideas to social organizations, such as corporations
and cities and became an original organizer of the MIT School of
Industrial Management at the MIT Sloan School of Management.
W. Edwards Deming, the Total Quality Management guru for whom Japan named its top post-WWII industrial prize, was an intern at Bell Telephone Labs in 1927 and may have been influenced by network theory; Deming made "Understanding Systems" one of the four pillars of what he described as "Profound Knowledge" in his book The New Economics.
Numerous papers spearheaded the coalescing of the field. In 1935 Russian physiologist P. K. Anokhin
published a book in which the concept of feedback ("back
afferentation") was studied. The study and mathematical modelling of
regulatory processes became a continuing research effort and two key
articles were published in 1943: "Behavior, Purpose and Teleology" by Arturo Rosenblueth, Norbert Wiener, and Julian Bigelow; and the paper "A Logical Calculus of the Ideas Immanent in Nervous Activity" by Warren McCulloch and Walter Pitts.
In 1936, Ștefan Odobleja
published "Phonoscopy and the clinical semiotics". In 1937, he
participated in the IX International Congress of Military Medicine with
"Demonstration de phonoscopie"; in the paper he disseminated a
prospectus announcing his future work, "Psychologie consonantiste", the
most important of his writings, where he lays the theoretical
foundations of generalized cybernetics. The book, published in Paris by Librairie Maloine
(vol. I in 1938 and vol. II in 1939), contains almost 900 pages and
includes 300 figures in the text. The author wrote at the time that
"this book is ... a table of contents, an index or a dictionary of
psychology, [for] a ... great Treatise of Psychology that should contain
20–30 volumes". Due to the beginning of World War II, the publication
went unnoticed (the first Romanian edition of this work did not appear
until 1982).
Cybernetics as a discipline was firmly established by Norbert Wiener, McCulloch, Arturo Rosenblueth and others, such as W. Ross Ashby, mathematician Alan Turing, and W. Grey Walter
(one of the first to build autonomous robots as an aid to the study of
animal behaviour). In the spring of 1947, Wiener was invited to a
congress on harmonic analysis, held in Nancy (France was an important geographical locus of early cybernetics together with the US and UK); the event was organized by the Bourbaki, a French scientific society, and mathematician Szolem Mandelbrojt (1899–1983), uncle of the world-famous mathematician Benoît Mandelbrot.
During this stay in France, Wiener received the offer to write a
manuscript on the unifying character of this part of applied
mathematics, which is found in the study of Brownian motion
and in telecommunication engineering. The following summer, back in the
United States, Wiener decided to introduce the neologism cybernetics, coined to denote the study of "teleological mechanisms", into his scientific theory: it was popularized through his book Cybernetics: Or Control and Communication in the Animal and the Machine (MIT Press/John Wiley and Sons, NY, 1948). In the UK this became the focus for the Ratio Club.
In the early 1940s John von Neumann contributed a unique and unusual addition to the world of cybernetics: von Neumann cellular automata, and their logical follow up, the von Neumann Universal Constructor. The result of these deceptively simple thought-experiments was the concept of self replication, which cybernetics adopted as a core concept. The concept that the same properties of genetic reproduction applied to social memes, living cells, and even computer viruses is further proof of the somewhat surprising universality of cybernetic study.
In 1950, Wiener popularized the social implications of
cybernetics, drawing analogies between automatic systems (such as a
regulated steam engine) and human institutions in his best-selling The Human Use of Human Beings: Cybernetics and Society (Houghton-Mifflin).
Cybernetics in the Soviet Union
was initially considered a "pseudoscience" and "ideological weapon" of
"imperialist reactionaries" (Soviet Philosophical Dictionary, 1954) and
later criticised as a narrow form of cybernetics. In the mid to late 1950s Viktor Glushkov
and others salvaged the reputation of the field. Soviet cybernetics
incorporated much of what became known as computer science in the West.
While not the only instance of a research organization focused on cybernetics, the Biological Computer Lab at the University of Illinois at Urbana–Champaign, under the direction of Heinz von Foerster, was a major center of cybernetic research for almost 20 years, beginning in 1958.
Split from artificial intelligence
Artificial intelligence (AI) was founded as a distinct discipline at the Dartmouth workshop. After some uneasy coexistence, AI gained funding and prominence. Consequently, cybernetic sciences such as the study of artificial neural networks were downplayed; the discipline shifted into the world of social sciences and therapy.
Prominent cyberneticians during this period include Gregory Bateson and Aksel Berg.
New cybernetics
In the 1970s, new cyberneticians emerged in multiple fields, but especially in biology. The ideas of Maturana, Varela and Atlan,
according to Jean-Pierre Dupuy (1986) "realized that the cybernetic
metaphors of the program upon which molecular biology had been based
rendered a conception of the autonomy of the living being impossible.
Consequently, these thinkers were led to invent a new cybernetics, one
more suited to the organizations which mankind discovers in nature -
organizations he has not himself invented".
However, during the 1980s the question of whether the features of this
new cybernetics could be applied to social forms of organization
remained open to debate.
In political science, Project Cybersyn attempted to introduce a cybernetically controlled economy during the early 1970s.
In the 1980s, according to Harries-Jones (1988) "unlike its
predecessor, the new cybernetics concerns itself with the interaction of
autonomous political actors
and subgroups, and the practical and reflexive consciousness of the
subjects who produce and reproduce the structure of a political
community. A dominant consideration is that of recursiveness, or
self-reference of political action both with regards to the expression
of political consciousness and with the ways in which systems build upon
themselves".
One characteristic of the emerging new cybernetics considered in that time by Felix Geyer and Hans van der Zouwen, according to Bailey (1994),
was "that it views information as constructed and reconstructed by an
individual interacting with the environment. This provides an epistemological
foundation of science, by viewing it as observer-dependent. Another
characteristic of the new cybernetics is its contribution towards
bridging the micro-macro gap. That is, it links the individual with the society".
Another characteristic noted was the "transition from classical
cybernetics to the new cybernetics [that] involves a transition from
classical problems to new problems. These shifts in thinking involve,
among others, (a) a change from emphasis on the system being steered to
the system doing the steering, and the factor which guides the steering
decisions; and (b) new emphasis on communication between several systems
which are trying to steer each other".
Recent endeavors into the true focus of cybernetics, systems of control and emergent behavior, by such related fields as game theory (the analysis of group interaction), systems of feedback in evolution, and metamaterials
(the study of materials with properties beyond the Newtonian properties
of their constituent atoms), have led to a revived interest in this
increasingly relevant field.
Cybernetics and economic systems
The design of self-regulating control systems for a real-time planned economy was explored by economist Oskar Lange, cyberneticist Viktor Glushkov, and others Soviet cyberneticists during the 1960s. By the time information technology was developed enough to enable feasible economic planning based on computers, the Soviet Union and eastern bloc countries began moving away from planning and eventually collapsed.
More recent proposals for socialism involve "New Socialism", outlined by the computer scientists Paul Cockshott and Allin Cottrell, where computers determine and manage the flows and allocation of resources among socially owned enterprises.
On the other hand, Friedrich Hayek
also mentions cybernetics as a discipline that could help economists
understand the "self-organizing or self-generating systems" called markets. Being a "complex phenomena",
the best way to examine the market functioning is by using the feedback
mechanism, explained by cybernetic theorists. That way, economists
could make "pattern predictions".
Therefore, the market for Hayek is a "communication system", an "efficient mechanism for digesting dispersed information". The economist and a cyberneticist are like garderners who are "providing the appropriate environment".
Hayek's definition of information is idiosyncratic and precedes the
information theory used in cybernetics and the natural sciences.
Finally, Hayek also considers Adam Smith's idea of the invisible hand as an anticipation of the operation of the feedback mechanism in cybernetics. In the same book, Law, Legislation and Liberty, Hayek mentions, along with cybernetics, that economists should rely on the scientific findings of Ludwig von Bertalanffy general systems theory, along with information and communication theory and semiotics.
Subdivisions of the field
Cybernetics is sometimes used as a generic term, which serves as an umbrella for many systems-related scientific fields.
Basic cybernetics
Cybernetics studies systems of control as a concept, attempting to discover the basic principles underlying such things as
- Artificial intelligence
- Computer vision
- Control systems
- Conversation theory
- Emergence
- Interactions of actors theory
- Learning organization
- Robotics
- Second-order cybernetics
- Self-organization in cybernetics
In biology
Cybernetics
in biology is the study of cybernetic systems present in biological
organisms, primarily focusing on how animals adapt to their environment,
and how information in the form of genes is passed from generation to generation. There is also a secondary focus on combining artificial systems with biological systems. A notable application to the biology world would be that, in 1955, the physicist George Gamow published a prescient article in Scientific American called "Information transfer in the living cell", and cybernetics gave biologists Jacques Monod and François Jacob a language for formulating their early theory of gene regulatory networks in the 1960s.
- Autopoiesis
- Biocybernetics
- Bioengineering
- Bionics
- Ecology
- Heterostasis
- Homeostasis
- Medical cybernetics
- Neuroscience
- Synthetic biology
- Systems biology
- Practopoiesis
In computer science
Computer science directly applies the concepts of cybernetics to the control of devices and the analysis of information.
- Cellular automaton
- Decision support systems
- Design patterns
- Robotics
- Simulation
- Formal languages
- Modal logic
In engineering
Cybernetics in engineering is used to analyze cascading failures and system accidents, in which the small errors and imperfections in a system can generate disasters. Other topics studied include:
In management
- Autonomous agency theory
- Entrepreneurial cybernetics
- Management cybernetics
- Operations research
- Organizational cybernetics
- Systems engineering
- Viable system theory
In mathematics
Mathematical Cybernetics focuses on the factors of information, interaction of parts in systems, and the structure of systems.
In psychology
- Attachment theory
- Behavioral cybernetics
- Cognitive psychology
- Consciousness
- Embodied cognition
- Human-robot interaction
- Mind-body problem
- Perceptual control theory
- Psychovector analysis
- Systems psychology
In sociology
By examining group behavior through the lens of cybernetics, sociologists can seek the reasons for such spontaneous events as smart mobs and riots, as well as how communities develop rules such as etiquette by consensus without formal discussion. Affect Control Theory explains role behavior, emotions, and labeling theory
in terms of homeostatic maintenance of sentiments associated with
cultural categories. The most comprehensive attempt ever made in the
social sciences to increase cybernetics in a generalized theory of
society was made by Talcott Parsons. In this way, cybernetics establishes the basic hierarchy in Parsons' AGIL paradigm, which is the ordering system-dimension of his action theory. These and other cybernetic models in sociology are reviewed in a book edited by McClelland and Fararo.
In art
Nicolas Schöffer's CYSP I
(1956) was perhaps the first artwork to explicitly employ cybernetic
principles (CYSP is an acronym that joins the first two letters of the
words "CYbernetic" and "SPatiodynamic").
The prominent and influential Cybernetic Serendipity exhibition was held at the Institute of Contemporary Arts in 1968 curated by Jasia Reichardt, including Schöffer's CYSP I and Gordon Pask's Colloquy of Mobiles installation. Pask's reflections on Colloquy connected it to his earlier Musicolour
installation and to what he termed "aesthetically potent environments",
a concept that connected this artistic work to his concerns with
teaching and learning.
The artist Roy Ascott elaborated an extensive theory of cybernetic art in "Behaviourist Art and the Cybernetic Vision" (Cybernetica,
Journal of the International Association for Cybernetics (Namur),
Volume IX, No.4, 1966; Volume X No.1, 1967) and in "The Cybernetic
Stance: My Process and Purpose" (Leonardo Vol 1, No 2, 1968). Art historian Edward A. Shanken
has written about the history of art and cybernetics in essays
including "Cybernetics and Art: Cultural Convergence in the 1960s" and From Cybernetics to Telematics: The Art, Pedagogy, and Theory of Roy Ascott (2003), which traces the trajectory of Ascott's work from cybernetic art to telematic art (art using computer networking as its medium, a precursor to net.art.)
- Telematic art
- Interactive art
- Systems art
In architecture and design
Cybernetics
was an influence on thinking in architecture and design in the decades
after the Second World War. Ashby and Pask were drawn on by design
theorists such as Horst Rittel, Christopher Alexander and Bruce Archer. Pask was a consultant to Nicholas Negroponte's Architecture Machine Group, forerunner of the MIT Media Lab, and collaborated with architect Cedric Price and theatre director Joan Littlewood on the influential Fun Palace project during the 1960s. Pask's 1950s Musicolour installation was the inspiration for John and Julia Frazer's work on Price's Generator project. There has been a resurgence of interest in cybernetics and systems thinking amongst designers in recent decades, in relation to developments in technology and increasingly complex design challenges. Figures such as Klaus Krippendorff, Paul Pangaro and Ranulph Glanville
have made significant contributions to both cybernetics and design
research. The connections between the two fields have come to be
understood less in terms of application and more as reflections of each
other.
In Earth system science
Geocybernetics aims to study and control the complex co-evolution of ecosphere and anthroposphere, for example, for dealing with planetary problems such as anthropogenic global warming. Geocybernetics applies a dynamical systems perspective to Earth system analysis. It provides a theoretical framework for studying the implications of following different sustainability paradigms on co-evolutionary trajectories of the planetary socio-ecological system to reveal attractors in this system, their stability, resilience and reachability. Concepts such as tipping points in the climate system, planetary boundaries, the safe operating space for humanity and proposals for manipulating Earth system dynamics on a global scale such as geoengineering have been framed in the language of geocybernetic Earth system analysis.
In sport
A model of cybernetics in Sport was introduced by Yuri Verkhoshansky and Mel C. Siff in 1999 in their book Supertraining.
In law
As a form of regulation, cybernetics has been always close to law, specially in regulation and legal sciences, through the next topics:
- Organizations and superorganisms
- Ontology, logic and artificial intelligence
- Complex adaptive systems
- Smart contracts
- Control systems
- Self-organization in cybernetics
- Cyberethics
- Regulation
- Consensus systems
- Metagovernment
Related fields
Complexity science
Complexity science attempts to understand the nature of complex systems.
Aspects of complexity science include:
Biomechatronics
Biomechatronics relates to linking mechatronics
to biological organisms, leading to systems that conform to A. N.
Kolmogorov's definition of Cybernetics: "Science concerned with the
study of systems of any nature which are capable of receiving, storing
and processing information so as to use it for control". From this perspective mechatronics are considered technical cybernetics or engineering cybernetics.