Network concepts in social theory: Foucault and cybernetics

What was cybernetics?

Cybernetics has recently been rediscovered in debates on big data and digitalization (e.g. Helbing et al., 2017). In these debates, as in the social sciences, the meaning of ‘cybernetics’ is still linked to the debate on technocracy that made cybernetics a buzz word in the 1950s and 1960s. This debate, however, did not deal with cybernetic research but with post-war politics. After World War II, the state attempted to organize social cohesion and modernization by rational techniques of planning and steering (Seefried, 2014). In search for better techniques, state agencies and private foundations also funded cybernetic research, as they saw potential for a general theory of ‘communication and control’ (Wiener, 1948). The political goal of rationalizing government by technical means spurred a public debate, in which ‘cybernetics’ became the signifier for a research programme believing in the optimization and rationalization of societies through data and machines.

Strangely, this understanding of cybernetics was shared by proponents and critics of rationalization in the technocracy debate. Proponents were strongly influenced by a rational choice approach to modelling the future as developed by the RAND Corporation (Seefried, 2014). They aimed for a so-called modern style of government that relies on rational decision-making by technical procedures (e.g. Helmer, 1966). Critical positions, on the other hand, argued that a rule of technicians and technique would result in a loss of democratic and human sovereignty. Critics, such as Jürgen Habermas (1987, p. 118), cautioned against the ‘cybernetic dream of the instinct-like self-stabilization of societies’. Yet, both sides agreed that ‘cybernetics’ stood for a rationalized stream of information and faster processing that – for better or for worse – would affect decision-making.

In contrast to its public label, cybernetics attempted something completely different according to many cyberneticians, as studies in the history of cybernetics have demonstrated (e.g. Dupuy, 2000; Hayles, 1999; Heims, 1993; Kline, 2015; Pickering, 2009). This leads to the methodological problem that, in the worst case, a text criticizes cybernetics while applying cybernetic concepts. It is therefore necessary to decentre the technocratic reading of cybernetics that continues to affect contemporary accounts of it.

For one, cybernetics discussed communication and control in a much broader range of areas, rather concentrating on mathematics, quantum theory, neurophysiology, psychology or linguistics than on political decision-making. This transdisciplinary approach was a precondition for cybernetics’ long-lasting impact (Kline, 2015). Of course, Norbert Wiener who coined the term ‘cybernetics’ was initially inspired by modernist ideas of feasibility and generalization, as he intended to create a universal framework for regulation in animals (including human beings), machines and, to a certain degree, societies. Moreover, its transdisciplinarity also opened cybernetics to aspirations of rational choice modelling or mechanical engineering. Cyberneticians, however, dissociated themselves early on from these perspectives. In their view, cybernetics aimed for the opposite: it attempted a general critique of mechanical steering and rationalization by replacing linear models with the complexity and circularity of interdependent feedback loops.

Already at the Macy conferences, a seminal series of 10 events that provided a forum for early cybernetics, two camps began to form (Dupuy, 2000, pp. 119–123). One camp consisted of scientists such as Leonard Savage who had a close relationship to positivism, utilitarian ideas of behaviour and linear models of communication. In the other camp were ‘core’ cyberneticians such as Warren McCulloch, Gregory Bateson and Heinz von Foerster, who initiated and organized the conferences. They criticized the hierarchical order of preferences behind rational choice reasoning, arguing that the main discovery of cybernetics lays in conceptualizing circular, heterarchical information processes and the emergent eigen-behaviour of complex systems (Bateson, 1987, p. 452; McCulloch, 1945; von Foerster, 1977). Linear and rationalist models would, thus, simply miss the central ideas of cybernetics.

This hunch of many cyberneticians had two main consequences. On the one hand, and as early as in the mid-1950s, significant parts of information theory and game theory rejected a connection to cybernetics, which denied to conceive of information problems in terms of effective transmission of a fixed message (Geoghegan & Peters, 2014; von Foerster & Pörksen, 2001, p. 97). On the other hand, a group of cyberneticians including Bateson and von Foerster concluded that early cybernetic concepts, although interested in non-linear dynamics beyond rationalism, still provided too many opportunities to build linear, rationalist models. To prevent this misunderstanding, they refined cybernetic concepts by performing a reflexive turn, creating ‘second-order cybernetics’ (Foerster, 1974; Hayles, 1999, pp. 73–75, 131; Scott, 2004).

Second-order cybernetics argued that first-order cybernetics observed systems without adequately considering that the observer is also part of a system. This would force cyberneticians to apply their concepts of circular self-regulation to their own observations (Clarke, 2009, p. 36). Observing systems are both conditioned by their position in the network of systems and self-regulatory as they create their behaviour through their own recursive processes. Therefore, they also produce their own perception of the world and any observing system could be observed from another observing system, starting an infinite recursive process of observing observers and their blind spots. In other words, second-order cybernetics radicalized ideas of circularity, reflexivity and complexity already encapsulated in first-order cybernetics.

Let us briefly explore main conceptual ideas of first- and second-order cybernetics. This introduction into cybernetic concepts further decentres the technocratic reading and generates a heuristic that I will use to analyse Foucault. It focuses on two main developments of cybernetics: (a) the invention of a new set of concepts that allowed to reject ontological perspectives for an operational approach and (b) the remodelling of ‘governance’ from linear and hierarchical models to circular and reflexive self-regulation that prefers difference over identity and continuity.

Networks and systems: ‘Doing’ rather than ‘being’

Cybernetics received much attention because it offended post-war humanism by rejecting the strict dichotomy of human beings and machines. In so doing, cybernetics imagined itself to be a fourth revolution following Copernicus, Darwin and Freud in dethroning the human subject (Hagner, 2008, pp. 38–39). Behind this rhetorical verve, however, stood an epistemological critique of modern societies. In particular, cybernetics targeted the ‘simplistic’ and ‘reductionist’ models of modern science that prevailed in Newtonian mechanics and ontological reasoning (Ashby, 1956, p. 5; another example is Ackoff, 1979). As both rely on essentialist distinctions of subjects and objects or life and machines, they generate an ‘under-complex’ understanding of the world. They simplify the ‘real’ diversity of possibilities by isolating variables and construing linear causalities, thus explaining the world with insufficient models of stimulus and response, cause and effect, or motivation and action (Ashby, 1956, pp. 5, 121–126; von Foerster, 1984).

Cyberneticians believed that this ‘old’ world view increasingly fails to grasp the growing complexity of the world. Therefore, they called for a new way of thinking, a ‘new world view’ (e.g. Ackoff, 1979, p. 96). The polemic call for a new mind-set that follows from the narrative of rising complexity survives in Foucault’s writings (e.g. Foucault, 1994, IV, p. 108) and in nowadays rhetoric of network theory and network governance (e.g. Eggers, 2008, p. 28; Raworth, 2017). To overcome the ‘old’, ‘insufficient’ models, early cybernetician W. Ross Ashby (1956, p. 1) already proclaimed a revolutionary shift towards an operational epistemology that disposes of the ontology inherent in humanism and mechanics by switching the attention from what to how and from essence to doing: ‘Cybernetics […] does not ask “what is this thing?” but “what does it do?”’ (original emphasis).

For developing this operational approach, cyberneticians invented a range of concepts that are abstract enough to deal with any assembly of elements and to model how these elements may connect to do something (Beer, 1959, 1967, pp. 9–10). Presenting ‘connectivity’ as the core idea of cybernetics, Stafford Beer once advanced five models of connectivity in a single paragraph – machines, systems, networks, diagram and electric circuits:

A machine is a system, a set of points joined together by certain specified relationships. Therefore we may set up as its model a simple network. […] The lines by which these dots are connected reveal the possible modes in which the system can operate. […] A schematic diagram […] can obviously be drawn […]. This diagram will bear a marked resemblance to any representation of an electric circuit. (Beer, 1967, p. 95, original emphasis)

As the adoption of game-theoretical metaphors illustrates, the different models have their own strengths and weaknesses. While the concept of a system is very abstract, allowing for an application to any arbitrary assembly of elements, networks and diagrams are much more intelligible in describing the idea of connectivity. Because of that, they also help to understand two general epistemological premises of cybernetic modelling. First, there is a multiplicity of interdependent relationships that condition each other. The opportunities of an element a to connect with another element b are influenced by the connections among the elements c, d and e, as well as the chosen ‘strategy’ of element a will influence the opportunities of the elements c, d and e. Secondly, the complexity is even higher as there is also a relationship between actualized and potential connections. The diagram, for instance, demonstrates that some connecting lines between the elements are active in each moment, whereas others are inactive but could have been chosen or might be chosen at a different point in time. What we can observe, therefore, is neither the essence of a thing nor the identity of a person, but only one possibility actualized at given moment.

Here lies a radical consequence of shifting the attention from essence to doing, which was finally explicated by second-order cybernetics: Systems or networks only exist in doing, in processing, in reproducing their elements and their relations in real-time (e.g. Maturana & Varela, 1980). Exploring these processes of ordering, cybernetics adopted the concepts of emergence and evolution. ‘Emergence’ means that some pattern appears as the elements in a network relate to each other. This emergent order and its possibilities are not intended; they are simply an effect of simultaneous coordination in the network. Yet, as the relations reproduce themselves in response to changes in the network and in its environment, the pattern of the network transforms – which is called ‘evolution’. In contrast to stable identities that develop coherently over time, emergence and evolution are erratic, unintentional and irreducible to former formations. Second-order cybernetics thus undermined modern theories of identity and linear history alike.

A new concept of ‘governance’: Circularity, self-regulation, diversity

In line with their categorical rejection of Newtonian mechanics and ontological philosophy, cybernetics also came to refuse linear-causal and mechanistic concepts of steering, in particular hierarchical forms of organization, command-and-control approaches and central planning. Cybernetics thought of those models of regulation as ‘primitive’ and ‘naïve’ (Beer, 1967, p. 21), because they are based on a reductionist idea of causality and imply that systems can be steered intentionally and hierarchically. While this critique targeted the models of modern science (not political decision-making), some cyberneticians argued that the ‘old’ rationality also yields insufficient concepts of government and power. According to Beer (1967, p. 21), for instance, those concepts still dominate post-war societies and simply identify control with coercion. In either case, cyberneticians believed that in refusing such simplistic models cybernetics would offer a new, more accurate understanding of control.

The cybernetic concept of control (or regulation) entertains two fundamental shifts. On the one hand, it maintains that regulation is a universal and ubiquitous phenomenon. While there are no systems (and no societies) without regulation, regulation rarely takes the form of coercion or linear causality. This is because complex systems are ‘highly differentiated’, which prevents them from being easily steered from a control centre. Rather, the interdependent elements in a network regulate themselves via mutual influence. Each element in a system is shaped by connecting processes and, at the same time, it shapes those processes by redirecting the flow of communication. In other words, cybernetics argued that regulation is but the name for the circular processes of communication and coordination (Beer, 1959).

To model circularity, early cyberneticians introduced the term ‘feedback’ (Rosenblueth et al., 1943). It described that a system uses its output as its input. Early cybernetics started from observing systems that minimize the difference of its actual output to a specified goal (negative feedback). This focus on quasi-teleological or purposive mechanisms of goal-attainment, however, soon was criticized. First, Ashby argued that complex ‘homeostatic’ systems would randomly seek their own viable patterns, rather than to orient towards a given goal (Kline, 2015, pp. 52–53). Then, second-order cybernetics developed this thought even further by arguing that input and output are not even objective terms. Instead, what counts as input is determined by the processes inside the system: ‘an organism does not receive “information” as something transmitted to it, rather, as a circularly organised system it interprets perturbations as being informative’ (Scott, 2004, p. 1369).

This conceptual clarification radicalized cybernetics’ idea of control as self-organization. First-order approaches already argued that the elements of the networks regulate themselves by their own ‘language’ (Beer, 1959, p. 5) or ‘codes’ (Ashby, 1956, p. 140). To generate resonance inside a system, you must connect to those codes rather than to exercise command. But second-order cybernetics was even more rigid. According to them, the environment of a system is only ‘noise’ until the systems selects on which turbulences in the stream of noise it is going to act (Clarke, 2009; von Foerster, 1984). Because there are so many connections and co-dependencies in a network (and in a network of networks), systems are completely self-organized. Complexity and self-organization go hand in hand.

It is obvious by now that these ‘governance’ concepts are descriptive and normative. The descriptive aspect is that (according to cybernetics) complex systems have internal processes that are highly differentiated and flexible, which allows them to deal with massive amounts of complexity and contingency in their environment. This observation is famously stated by Ashby’s ‘law of requisite variety’ (1956, pp. 202–213). It is, however, easily turned into a normative statement: If you do not want to undermine highly complex systems, command-and-control approaches are the wrong way to go. Complex systems depend on diversity, flexibility and self-regulation, because they allow them to innovate, experiment and ‘design’ new answers in response to a highly volatile environment. Here, cybernetics has an inherent link to aesthetics and style (Ackoff, 1979, p. 101), as those answers are not ‘the one best way’ (as searched for by rational choice approaches) but only one ‘viable’ way found through the creativity that is unlocked by diversity and self-regulation. Cybernetics, thus, offered a theory of difference that undermined concepts of ontological identity, economic rationality and political integration.

Two examples: Advocating communication and information theory

It is well known that Foucault was not in the habit of disclosing his sources by giving frequent references, which has always been a challenge for historicizing and locating his work. Moreover, Foucault’s approach obviously differs in many ways from socio-cybernetic attempts like Niklas Luhmann’s that openly and systematically embraced cybernetics to build a theory of society. In other words, it is not to be expected that Foucault would simply acknowledge the impact of cybernetic concepts, such as information, noise or system. One exception, however, is the extraordinary piece Message or Noise?.

In this 1966 paper, Foucault (1994, I, p. 557) set out to criticize the ‘benedictory humanisms’ of medicine. ³ According to him, modern medicine believes that a disease sends messages, which doctors must only hear and interpret. To dismantle this assumption, Foucault drew on the concepts of noise and code from cybernetics and information theory. He argued that initially there is only noise. For noise to have a message, it would need to provide ‘diverse discontinuous elements’ that are connected among each other according to certain regularities. Those connected elements, then, must have a connection to another set of elements that holds the meaning. According to Foucault (1994, I, p. 558), these conditions are not fulfilled in medicine:

But the illness does not send a “message,” because a message depends upon a “code” that is established by the described rules. There is no code in nature […]. The illness might “make noise,” and that is already plenty. All of the rest is made up by medicine.

In Linguistics and Social Science, my second example published 3 years later when Foucault (1994, I, pp. 821–828) reflected upon the methodology of his inquiries, he further explored this approach of language and information analysis. He argued that structural linguistics abolished the old idea that language is a true representation. In consequence, it became possible to analyse language just like ‘all the phenomena of information’ – by using formal methods of mathematics and communication theory to decipher language in terms of ‘senders’ and ‘receivers’, ‘messages’ and ‘codes or regulations [règles]’ (Foucault, 1994, I, p. 825). In doing so, linguistics joins with other sciences in discovering the ‘if not universal, at least extraordinarily broad character of the phenomena of communication that reach from microbiology to sociology’ (Foucault, 1994, I, p. 828).

Foucault, here, explicitly affiliated himself with the (cybernetic) idea of a universal methodology that interprets the world through information, communication and regulation. However, two aspects in this article also indicate Foucault’s critique of the structuralist programme. On the one hand, he argued that the structuralist analysis is not necessarily an ahistorical endeavour even though structural linguists often focused on synchronous models. On the other hand, he insinuated that the methodology goes beyond analysing language. ‘[T]he social’, Foucault argued (1994, I, p. 826), can altogether be described as ‘an assembly of codes and information’. Structural linguistics, thus, only laid the groundwork to develop a new approach that builds on cybernetic concepts to analyse epistemic structures and historicize them by following the ‘discontinuity and transformation’ of ‘discourses’ (Foucault, 1994, I, pp. 827–828).

This is, of course, what Foucault (1994, I, p. 846) proposed in his application to the Collège de France: to analyse ‘systems’ of thought and ‘how – via what channels and codes – knowledge registers […] phenomena that have hitherto remained outside’. Here, as in the examples above, Foucault decidedly employed cybernetic vocabulary to antagonize against the humanistic ideas of meaning, development and sovereignty. He declared that he had discovered a new ‘passion […] for what I call the “system”’, that is ‘an assembly of relations that maintain themselves, transform themselves’ (Foucault, 1994, I, p. 514). ⁴ In the influential essay Of Other Spaces, Foucault (1994, IV, p. 752) pinpointed the massive epistemological shift he himself intended, again using a cybernetic metaphor: ‘We are at a moment when the world experiences itself, I think, less like a great life that would develop over time, but like a network [!] that connects points and intersects with its own threads’.

Two mediators: Structuralism and Canguilhem

The examples illustrate three aspects. Firstly, Foucault argued for introducing cybernetic concepts of networks and systems, information, codes and communication into the analysis of language and discourse. Secondly, they indicate some reasons for doing so. While it is a methodological invention that offers a completely new formal and analytical approach (which is useful for a young philosopher), the shift to the cybernetic language of systems and complexity, noise and information also helped to make a political point. It provided Foucault with concepts for criticizing philosophical and clinical humanisms and their core idea, the sovereign subject. Finally, both examples also hint towards the sources of Foucault’s affinities for cybernetic ideas of communication and control, that is, structuralism and the history of knowledge as performed by his teacher Georges Canguilhem.

The close connections of structuralism and cybernetics are well known. On the one hand, contemporaries, especially neo-Marxists such as Henri Lefebvre, stressed the cybernetic background of structuralism (which included Foucault). But their perspective was more political than analytical as they aimed to expose structuralism as technocratic ideology that undermined critical human agency and thereby supported a rationalist rule (Dosse, 1997, I, pp. 163, 357; Lafontaine, 2004, pp. 109–114). ⁵ Recent research, on the other hand, offers an analytical account that is often rooted in a reading of cybernetic research (Dupuy, 2000, pp. 17–20, 107–108; Geoghegan, 2011; Johnson, 2015; Lafontaine, 2007).

According to this research, main figures of structuralism had both personal ties to and theoretical enthusiasm for cybernetics. In 1955, for instance, Jacques Lacan gave an influential seminar that intended to bring cybernetics into psychoanalysis, thereby redefining the unconscious in terms of a formalistic model of language (Lafontaine, 2007, pp. 33–36). Claude Lévi-Strauss, on the other hand, probably had even closer ties to cybernetics. He was in contact with Roman Jakobson who advanced formal linguistics by implementing the cybernetic theory of communication and information, which he encountered as a participant of the Macy conferences (Geoghegan, 2011, pp. 104–121; Gerovitch, 2008). Moreover, Lévi-Strauss conferred with Warren Weaver who sent him copies of the Mathematical Theory of Communication published by him and Claude Shannon (Geoghegan, 2011, p. 117). Finally, Lévi-Strauss frequently quoted Norbert Wiener, arguing that cybernetics provides the instruments to give anthropology a new, formalistic direction (Le Roux, 2009; Lévi-Strauss, 1954).

Although Foucault would strive beyond the structuralist projects, he was strongly inspired by structuralism, from where he took the concept of the system, which the structuralists, in turn, took from cybernetics (Foucault, 1994, I, p. 514; Lafontaine, 2004, p. 109). Perhaps, he even knew about this connection to cybernetics, since he linked structuralism with communication theory, as we saw above. Foucault (1994, I, p. 447) also paralleled Lacan’s and Lévi-Strauss’ proposals with cybernetics and information theory, as they would try to enable the humanities and sciences to develop a self-reflexive relationship, opening a new ‘non-dialectical’ perspective on knowledge (Foucault, 1994, I, pp. 541–543). In this regard, however, structuralism was not the only, perhaps not even the most important, mediator for cybernetic ideas.

Another source was Georges Canguilhem’s epistemological project. Canguilhem’s areas of interest, biology and medicine, were up front in redefining life by using cybernetic concepts of information and regulation. Renowned scientists, such as the Nobel laureate François Jacob, casted genetics and molecular biology in a cybernetically inspired vocabulary, redirecting the research agenda and transforming our view on the ‘genetic code’ (Fox Keller, 2002; Kay, 2000). Canguilhem located this epistemological transformation in a history of biological concepts of regulation; but he also used these concepts to develop his own philosophy of life (Muhle, 2008). As early as 1947, Canguilhem (1992) even followed the cybernetic analogy of machines and life, arguing that technology is a universal biological phenomenon. ⁶

When Foucault wrote the introduction to the English translation of Canguilhem’s On the Normal and the Pathological, he remembered the special interest Canguilhem took in ‘the theory of information: code, message, message carrier, etc.’ (Foucault, 1994, III, p. 440). According to Foucault, the importance of Canguilhem’s work for a new generation of French researchers derived from him introducing this cybernetic vocabulary and, with it, a new perspective on the humanities and their history. Instead of viewing history as linear progress, and instead of attributing this knowledge to a sovereign subject, information theory helped to understand evolution and the history of knowledge as a contingent ‘game of codes and of decoding’ (Foucault, 1994, III, p. 441). The history of knowledge would thus not be that of increasing knowledge but of redistributing what counts as true and false. This interpretation of Canguilhem’s influence in mind, it takes no wonder that Foucault remained interested in the crossroads of biology, history and information theory. For instance, he wrote a glowing review for François Jacobs La logique du vivant, in which Jacob explained how cybernetics and information theory can be applied to biology and its history. During the 1970s, Foucault would refer to this book multiple times and compare it with his own efforts (Foucault, 1994, II, pp. 99–104, 160–162).

Moreover, it is obvious that Foucault’s introduction described what inspired him in Canguilhem’s work. While Sprenger (2019, pp. 61–81) and Muhle (2008) argued that Canguilhem’s philosophy of life influenced Foucault’s later depiction of biopolitics, his critique of structuralism already imported some of the above arguments. On the one hand, Foucault criticized that the linguists thought there was a unifying structure (langue) behind the single utterings (parole). In contrast to ‘the uniform simplicity of causal assignations’ still inherent in structuralism, he aimed at reintroducing the ‘concepts of discontinuity and transformation’, which he knew from Canguilhem’s adaption of the cybernetic vocabulary (Foucault, 1994, I, pp. 680, 827). On the other hand, Foucault argued that focusing on language, as structuralists did, narrowed their perspective. Language is not a representation of thinking, he plead, but only one ‘form of communication’. The theory of language, thus, refers to a more general theory of communication that works with concepts, such as ‘senders’, ‘receivers’, ‘messages’, ‘codes and regularities’, that can now be used to describe ‘the social’ altogether (Foucault, 1994, I, pp. 825–826).

Remarkably, Foucault’s critique of structuralism has much in common with the critique second-order cybernetics voiced regarding first-order cybernetics. They criticized that the initial attempts tended to downplay complexities, discontinuities and contingency. To overcome these shortcomings, they initiated a reflexive turn. What was coined ‘cybernetics of cybernetics’ on the one side (von Foerster, 1974), Foucault (1994, I, p. 583) described as an attempt to analyse structuralism in structuralist terms. Moreover, in the following years, Foucault would often refer to two authors and friends who explicitly drew on second-order cybernetics, the philosopher Gilles Deleuze and the mathematician and ‘neocybernetician’ Michel Serres (Clarke, 2014; Clarke & Hansen, 2009; Lafontaine, 2004, pp. 150–155). Therefore, one might argue that post-structuralism relates to structuralism as second-order cybernetics to first-order cybernetics.