Steps Towards a (Media) Ecology: Difference between revisions
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Ashby writes, in Design for a Brain (1952) pages 100-103: | Ashby writes, in Design for a Brain (1952) pages 100-103: | ||
“The Homeostat [ | “The Homeostat [''Fig: Homeostat, four units''] consists of four units, each of which carries on top a pivoted magnet [''Fig: Homeostat–magnet, coil, pivot, vane, and water'']. The angular deviations of the four magnets from the central positions provide the four main variables. Its construction will be described in stages. Each unit emits a D.C. output proportional to the deviation of its magnet from the central position. The output is controlled in the following way. In front of each magnet is a trough of water electrode sat each end provide a potential gradient. The magnet carries a wire which dips into the water, picks up a potential depending on the position of the magnet, and sends it to the grid of the triode. J provides the anode-potential at 150 V., while H is at180 V. j so E carries a constant current. If the grid-potential allows just this current to pass through the valve, then no current will flow through the output. But if the valve passes more, or less, current than this, the output circuit will carry the difference in one direction or the other. So after E is adjusted, the output is approximately proportional to M's deviation from its central position.” <ref> W. Ross Ashby, Design for a Brain, John Wiley and Sons Publishing, 1952 p 100</ref> | ||
“Next, the units are joined together so that each sends its output to the other three; and thereby each receives an input from each of the other three. These inputs act on the unit's magnet through the coils A, B, and C, so that the torque on the magnet is approximately proportional to the algebraic sum of the currents in A, B, and C. (D also affects M as a self-feedback.) But before each input current reaches its coil, it passes through a commutator (X),which determines the polarity of entry to the coil, and through a potentiometer (P), which determines what fraction of the input shall reach the coil. As soon as the system is switched on, the magnets are moved by the currents from the other units, but these movements change the currents, which modify the movements, and so on. It may be shown […] that if there is sufficient viscosity in the troughs, the four-variable system of the magnet-positions is approximately state-determined. To this system the commutators and potentiometers act as parameters. When these parameters are given a definite set of values, the magnets show some definite pattern of behaviour; for the parameters determine the field, and thus the lines of behaviour. If the field is stable, the four magnets move to the central position, where they actively resist any attempt to displace them. If displaced, a co-ordinated activity brings them back to the centre. Other parameter-settings may, however, give instability; in which ease a 'runaway' occurs and the magnets diverge from the central positions with increasing velocity-till they hit the ends of the troughs. So far, the system of four variables has been shown to be dynamic, to have Figure 4/15/1 (A) as its diagram of immediate effects, and to be state-determined. Its field depends on the thirty-two parameters X and P. It is not yet ultrastable. But the inputs, instead of being controlled by parameters set by hand, can be sent by the switches S through similar components arranged on a uniselector (or 'stepping-switch') U. The values of the components in U were deliberately randomised by taking the actual numerical values from Fisher and Yates' Table of Random Numbers. Once built on to the uniselectors, the values of these parameters are determined at any moment by the positions of the uniselectors. Twenty-five positions on each of four uniselectors (one to each unit) provide 390,625 combinations of parameter-values. F represents the essential variable of the unit. Its contacts close when and only when the output current exceeds a certain value. When this happens, the coils G of the uniselector can be energised, moving the parameters to new values.”[…] <ref>W. Ross Ashby, Design for a Brain, John Wiley and Sons Publishing, 1952 pp 100-103 |Ashby’s notes on page 100-101 | It was given the name of' Homeostat ' for convenience of reference, and the noun seems to be acceptable. The derivatives homeostatic' and homeostatically', however, are unfortunate, for they suggest reference to the machine, whereas priority demands that they be used only as derivatives of Cannon's ‘homeostasis’. Following the original machine in principle, Mr. Earl .1. KIetsky, at the Technische Hogeschool, Delft, Holland, has designed and built a form that replaces the magnet, coils, vane and water by Kirchhoff adding circuits and capacitors </ref> | “Next, the units are joined together so that each sends its output to the other three; and thereby each receives an input from each of the other three. These inputs act on the unit's magnet through the coils A, B, and C, so that the torque on the magnet is approximately proportional to the algebraic sum of the currents in A, B, and C. (D also affects M as a self-feedback.) But before each input current reaches its coil, it passes through a commutator (X),which determines the polarity of entry to the coil, and through a potentiometer (P), which determines what fraction of the input shall reach the coil. As soon as the system is switched on, the magnets are moved by the currents from the other units, but these movements change the currents, which modify the movements, and so on. It may be shown […] that if there is sufficient viscosity in the troughs, the four-variable system of the magnet-positions is approximately state-determined. To this system the commutators and potentiometers act as parameters. When these parameters are given a definite set of values, the magnets show some definite pattern of behaviour; for the parameters determine the field, and thus the lines of behaviour. If the field is stable, the four magnets move to the central position, where they actively resist any attempt to displace them. If displaced, a co-ordinated activity brings them back to the centre. Other parameter-settings may, however, give instability; in which ease a 'runaway' occurs and the magnets diverge from the central positions with increasing velocity-till they hit the ends of the troughs. So far, the system of four variables has been shown to be dynamic, to have Figure 4/15/1 (A) as its diagram of immediate effects, and to be state-determined. Its field depends on the thirty-two parameters X and P. It is not yet ultrastable. But the inputs, instead of being controlled by parameters set by hand, can be sent by the switches S through similar components arranged on a uniselector (or 'stepping-switch') U. The values of the components in U were deliberately randomised by taking the actual numerical values from Fisher and Yates' Table of Random Numbers. Once built on to the uniselectors, the values of these parameters are determined at any moment by the positions of the uniselectors. Twenty-five positions on each of four uniselectors (one to each unit) provide 390,625 combinations of parameter-values. F represents the essential variable of the unit. Its contacts close when and only when the output current exceeds a certain value. When this happens, the coils G of the uniselector can be energised, moving the parameters to new values.”[…] <ref>W. Ross Ashby, Design for a Brain, John Wiley and Sons Publishing, 1952 pp 100-103 |Ashby’s notes on page 100-101 | It was given the name of' Homeostat ' for convenience of reference, and the noun seems to be acceptable. The derivatives homeostatic' and homeostatically', however, are unfortunate, for they suggest reference to the machine, whereas priority demands that they be used only as derivatives of Cannon's ‘homeostasis’. Following the original machine in principle, Mr. Earl .1. KIetsky, at the Technische Hogeschool, Delft, Holland, has designed and built a form that replaces the magnet, coils, vane and water by Kirchhoff adding circuits and capacitors </ref> | ||
Revision as of 12:23, 24 September 2020
==ROSS ASHBY ON THE HOMEOSTAT==[1]
I will quote Ross Ashby's Design for a Brain at length (1952). I also reproduce the images on those pages (although I have changed the captions to fit this wiki’s format). Here Ashby gives a technical description of the machine which – built by Ashby from parts of old WWII planes and spare components – models an organism. This cybernetic organism, by feeding back information from its environment and adapting to any changes made, maintains a “ultrastable” state (“homeostasis”). The most remarkable thing about this machine is that –because it is designed to correct any input which might threaten its stability – it works best when it does very little. At the time, as we will see, this was a difficult concept for even the cyberneticians at the Macy conferences to comprehend. Before moving on to Ashby’s description it is also worth pausing for a second to remember Lacan’s point about the cybernetic tortoise (which was built by Ashby’s colleague Grey Walter). Lacan noted that when the tortoise was at rest, as it “withdrew from life”, as it expressed “homeostatsis”, it displayed behaviour which, in psychoanalytical terms, could be described as the “death instinct” (see previous). We will see in the following chapter how, just as the tortoise invites discussions into the nature of self, the intersubjective and the nature of consciousness, the homeostat will invite questions about the dividing line between organism and environment and ecology and media. As in previous chapters this cybernetic creature will provide a model for Gregory Bateson to extend his ecology of mind to still further reaches, as Ashby’s notions of “requisite variation:” and “flexibility” are applied to the realms of biology, ecology and social cohesion.
Now, and with Ross Ashby's help, we will take a look at his machine, the homeostat.
Ashby writes, in Design for a Brain (1952) pages 100-103:
“The Homeostat [Fig: Homeostat, four units] consists of four units, each of which carries on top a pivoted magnet [Fig: Homeostat–magnet, coil, pivot, vane, and water]. The angular deviations of the four magnets from the central positions provide the four main variables. Its construction will be described in stages. Each unit emits a D.C. output proportional to the deviation of its magnet from the central position. The output is controlled in the following way. In front of each magnet is a trough of water electrode sat each end provide a potential gradient. The magnet carries a wire which dips into the water, picks up a potential depending on the position of the magnet, and sends it to the grid of the triode. J provides the anode-potential at 150 V., while H is at180 V. j so E carries a constant current. If the grid-potential allows just this current to pass through the valve, then no current will flow through the output. But if the valve passes more, or less, current than this, the output circuit will carry the difference in one direction or the other. So after E is adjusted, the output is approximately proportional to M's deviation from its central position.” [2] “Next, the units are joined together so that each sends its output to the other three; and thereby each receives an input from each of the other three. These inputs act on the unit's magnet through the coils A, B, and C, so that the torque on the magnet is approximately proportional to the algebraic sum of the currents in A, B, and C. (D also affects M as a self-feedback.) But before each input current reaches its coil, it passes through a commutator (X),which determines the polarity of entry to the coil, and through a potentiometer (P), which determines what fraction of the input shall reach the coil. As soon as the system is switched on, the magnets are moved by the currents from the other units, but these movements change the currents, which modify the movements, and so on. It may be shown […] that if there is sufficient viscosity in the troughs, the four-variable system of the magnet-positions is approximately state-determined. To this system the commutators and potentiometers act as parameters. When these parameters are given a definite set of values, the magnets show some definite pattern of behaviour; for the parameters determine the field, and thus the lines of behaviour. If the field is stable, the four magnets move to the central position, where they actively resist any attempt to displace them. If displaced, a co-ordinated activity brings them back to the centre. Other parameter-settings may, however, give instability; in which ease a 'runaway' occurs and the magnets diverge from the central positions with increasing velocity-till they hit the ends of the troughs. So far, the system of four variables has been shown to be dynamic, to have Figure 4/15/1 (A) as its diagram of immediate effects, and to be state-determined. Its field depends on the thirty-two parameters X and P. It is not yet ultrastable. But the inputs, instead of being controlled by parameters set by hand, can be sent by the switches S through similar components arranged on a uniselector (or 'stepping-switch') U. The values of the components in U were deliberately randomised by taking the actual numerical values from Fisher and Yates' Table of Random Numbers. Once built on to the uniselectors, the values of these parameters are determined at any moment by the positions of the uniselectors. Twenty-five positions on each of four uniselectors (one to each unit) provide 390,625 combinations of parameter-values. F represents the essential variable of the unit. Its contacts close when and only when the output current exceeds a certain value. When this happens, the coils G of the uniselector can be energised, moving the parameters to new values.”[…] [3]
[… the text continues…]
ORGANISM–ENVIRONMENT
THE HOMEOSTAT AT MACY
HOMEOSTAT – (MEDIA) ECOLOGY
In Conscious Purpose versus Nature [4] Bateson outlines a dialectic that is now familiar to us. Bateson notes that the chain of being and the place of the mind within it – as it had been understood in pre-modern and in non-occidental cultures – has suffered a reversal in the modern Western scientific era. In the modern conception the supreme mind (God/ mind of Man) was at the top, enjoying mastery over the creatures below him, from the higher primates to the protozoa bubbling at the bottom. Bateson argues that this conception does not allow for a conception of mind as imminent within a series of co-extensive systems. The publication of Jean-Baptiste Lamarck's evolutionary theory at the beginning of the 19th century – “the first organised transforms theory of evolution”.[5] ushered in a Copernican revolution in the biological field. Philosophie Zoologique (1809) is revolutionary, Bateson contends, because it acknowledged that the order of nature runs in a converse direction, suggesting that mind is indeed emergent and imminent within an ecology 27.Up until Lamarck "mind was an explanation of the biological world. But, Hey presto, the question now arose: is the biological world the explanation of mind?" […] “Some years [after Lamarck], Russel Wallis, in his correspondence to Charles Darwin described the process of natural selection as akin to the regulation of a steam engine by a governor.”)[6] The full implications of Wallis' insight, that such ecological systems are regulated by negative feedback (an observation also made by Samuel Butler, you may remember), lay dormant until after WWII when the revolution in cybernetics and communication theory allowed for a clearer understanding of feedback as a general regulating principle within different scaled ecological systems (from a single cell to a complex environment, such as Spaceship Earth). It also allowed for an understanding of the formation of social relations and individuation of the human psyche as a process of circular causality driven by purpose. If pre-modern societies had an understanding that mind was coextensive within a series of systems this was rediscovered in the post-cybernetic era as "nowadays cybernetics deals with much more complex systems" of human behaviour, human organization, any biological systems which are all self-corrective. Such systems are always conservative of something, the change in the fuel supply effects the motion of the flywheel which is regulated by the governor [7]
This transaction, in relation to any system, might be understood as survival. This tendency of self-correcting systems toward conservatism is now directed to the subject of the human psych. Bateson notes that the difficulty people have in seeing the obvious, or with coping with disturbing information is an artefact of the system. The tendency to reinforce resistance to the obvious or the disturbing is systematic. "This is a system which conserves descriptive statements about the human being, body and soul. For the same is true of the psychology of the individual , where learning occurs, to conserve the opinions and components of the status quo." Society and the ecosystem are systems of the same general kind. In all such systems there is an "uneasy balance of dependency and competition". The components of a system are "segmented" so that change is localised [...] The biological system is driven to reproduce, even if, to state the obvious, overpopulation will result in a strain on the larger system: any "monkeying with the system is likely to disrupt the equilibrium."[8]. It is therefore, "quite a trick" to balance dependency and competition. The system is segmented so that no single part has access to the "total mind" . However, and here Bateson introduces a mysterious (almost mystical element), “there is a " "semipermiable" linkage between consciousness and the remainder of the total mind. A certain limited amount of information about what is happening in this larger part of the mind seems to be relayed to what we may call the screen of consciousness."[9] Because the screen of consciousness is a filtration system it necessarily provides partial information. The whole mind cannot be comprehended in part of that mind, to comprehend the circuitry of the system would require more circuitry which produces an infinitely recursive logic &c. The question now arises, how is this limited selection of information which plays on the screen of consciousness selected and filtered? "I am guided in my perception by purposes." , thought is responsive and immanent "I get a myth about this subject which might be quite correct. I am interested in getting that myth as I talk. It is relevant to my purposes that you hear me."[10]. In this anecdote thought is imminent to purpose. Purpose becomes that which builds subjects and relations to subjects within the system.36 Here subjects and objects are performativly produced within a circuit of communication where competition and dependency are central agents.
Here Bateson mounts a critique of instrumental reason and the instrumentalization of cybernetic principles: "What happens to the picture of a cybernetic system [...] when that picture is selectively drawn to answer only questions of purpose?"[11]If a system is organized only in terms of purpose it ends up with a “bag of tricks” and no wisdom about the system as a whole, it is organised to arrive at short cuts and quick fixes and to follow the shortest logical path, which may be "dinner; it may be a Beethoven sonata; it may be sex. Above all it may be money and power." [12]. The cause for concern, for Bateson, is the "addition of modern technology to the old system" The system orientated by purpose that consciousness has been using for more than a million years has produced more effective machinery "transportation systems, airplanes, weaponry, medicine, pesticides, and so forth" all produced through the agency of conscious purpose. [13]
Bateson gives an account of conscious purpose which begins in myth. God, in a retelling of the Judo-Christian creation myth, was cast out of the garden on the day that Adam and Eve worked out how to stack one box on top of another in order to get their hands on the apple. At the point at which they realised that A & B can result in C, and were defined by a local aim and purpose they were "cast out of the garden of the concept of their own systemic nature." our consciousness is conditioned to conscious purpose, which is projected onto the screen of our consciousness, such purpose defines the subjects and objects in our world, we produce technologies to meet those purposes, together these things constitute a system which we strive to preserve. We see as through a glass darkly – "Consciousness is blinded to the systematic nature of the individual man" .
Bateson continues to wax biblical: “Lack of systematic wisdom is always punished”.[14] when presenting the cybernetic paradox of consciousness. Bateson continues to call for a revision of "the occidental errors of epistemology"[15], and calls for a humility in the face of nature and in relation to what is known by human beings. Bateson finds useful models in Zen Buddhism, which challenges the sovereignty of the self in relation to natural systems; artistic or aesthetic pursuits which operate under the order of self-reflexive, deutero-learning which alters the register of hierarchical perception; the 'best of religion' serves as a corrective to 'overrun' (positive feedback producing inflexibility and instability within a system).
In this respect the lines of engagement are ostensibly the same as the 1950s, but the stakes at the end of the 1960s, when an ecological disaster seems imminent, are more desperate. Bateson wrote in Radical Software: “... all of the many current threats to man”s survival are traceable to three root causes: a) technological progress b) population increase c) certain errors in the thinking and attitudes of occidental culture. (Our “values” are wrong!)” [16]
The question for Bateson in Restructuring the Ecology of a Great City – written for the office of New York City Mayor John Lindsy and published in the fourth issue of Radical Software –[17] is how to conserve and protect flexibility, which is a measure of the degree of adaptability within the parameters of a given system. Bateson begins the essay by establishing that the exploitation of resources over thousands of years by humans has resulted in a reduction of such flexibility. Human society has been progressively unstable since the introduction of the wheel, metal and script. Indeed the 'pathologies of our time' are an accumulation of a loss of flexibility over a very long period. The ideal city is considered as "a single system or environment with 'high' civilization" in which the flexibility of the civilization and of the environment are equal. The designation 'High' corresponds to the degree of self-knowledge or 'wisdom' of a given society, this is passed down by individuals through institutions (schools, family, church for instance).
Bateson shifts between actual and hypothetical societies; and also actual-hypothetical past and present societies, positing an ideal, ecological society which primarily uses that energy which is available to Spaceship Earth, principally solar, wind, photosynthesis and tidal energy.
To illustrate the ecological city, and the more general issue of flexibility within a system, Bateson again returns to W. Ross Ashby's Homeostat. In Ashby's model, and Bateson's city, flexibility operates within set parameters, the upper and lower limits of which are strained when tested, resulting in a loss of flexibility throughout that system. Bateson uses the practical (whilst somehow generally hypothetical) example of over-population, which exacts strains on housing, transportation systems and education if tested to the limit, resulting in the city becoming less self-sustainable, less flexible, less ecologically responsive. Bateson advocates the control of ecological resources and seeks to establish authority to preserve the flexibility that does exist (and to allow for instances for it to exist where it currently does not). This, Bateson argues, may justify 'tyrannical' measures.
Bateson advocates a radical humility on the part of humankind, warning that in seeking to have control of a given system one destroys it. The aim is to find one's place within an ecology, which requires a large philosophical AND spiritual leap in the first instance. Bateson has little faith in the current economic and political system – the Viet-Nam war is a folly, the pollution of the environment by corporations is reprehensible, overpopulation and the pollution of ecological systems by DDT indicate that it may be 'too late'. The interventions he makes – speaking on behalf of the Ecology Bill in Hawaii, and the debate on the future city in New York, for example – call for long term changes of individual and collective philosophy, reform where possible (Hawaii) and anti-democratic legislation if necessary (New York). The stakes are high, the very survival of Spaceship Earth.
For Bateson "cybernetics is [...] not simply a change in attitude, but even a change in the understanding of what an attitude is."[18] This introduces the political subject as transcendent: In later writings Bateson would consider that liberal reason requires a self-reflexivity which would allow a profound change in subjectivity. As with Bateson’s consideration of then human psyche or the social unit, there is always a paradox at the centre. For the subject to see themselves beyond the screen of consciousness is not possible, because the the screen of consciousness is the interface between the map of the self and the territory of the self. To know one’s place within system requires a transcendent self-reflexivity. The double bind would be that this transcendent self-reflexivity would be simultaneously a revelation of the self and a negation of the self. To think on the register of the total mind would allow one to see beyond the screen of consciousness and to recognize one’s place in the system. The ecological subject would transcend subjectivity, coming into being at the moment of its dissolution.
Bateson’s cybernetic epistemology necessitates a self-reflective understanding of the individual’s place within a larger system. The (second order) cybernetic approach to negentropy holds that human + environment are part of a single system. Humans are in the position to operate on a “deteuro-level” and order their environment (given that this is to a limited degree given that the universe is, in the long run, entropic). Humans, through making choices, order their environment – an aesthetic position. Humans’ failour to understand their place in the overall system can lead to disastrous environmental consequences, as a sub-system seeks to preserve aspects within itself which run contrary to the order of the greater system – an ecological position.
We also considered that the tendency to self-reflexivity is an artifice of the method described above. In the preceding chapters I have described a number of machines which solicit this self-reflexivity. The last of these machines, the Porta Pak, becomes a technology of self and a technology of collectivity. [19]
Functionally, the behaviour is the brain.
- ↑ Outtakes from previous draft of intro to this chapter. Bateson: "Ross Ashby long ago pointed out that no system (neither computer nor organism) can produce anything new unless the system contains some source of the random. In the computer, this will be a random-number generator which will ensure that the "seeking," trial-and-error moves of the machine will ultimately cover all the possibilities of the set to be explored."| Bateson "I am going to build a church some day. It will have a holy of holies and a holy of holies of holies, and in that ultimate box will be a random numbertable." Stewart Brand recounting an exchange with Bateson's secretary Judy Van Slooten WEC Review p490
- ↑ W. Ross Ashby, Design for a Brain, John Wiley and Sons Publishing, 1952 p 100
- ↑ W. Ross Ashby, Design for a Brain, John Wiley and Sons Publishing, 1952 pp 100-103 |Ashby’s notes on page 100-101 | It was given the name of' Homeostat ' for convenience of reference, and the noun seems to be acceptable. The derivatives homeostatic' and homeostatically', however, are unfortunate, for they suggest reference to the machine, whereas priority demands that they be used only as derivatives of Cannon's ‘homeostasis’. Following the original machine in principle, Mr. Earl .1. KIetsky, at the Technische Hogeschool, Delft, Holland, has designed and built a form that replaces the magnet, coils, vane and water by Kirchhoff adding circuits and capacitors
- ↑ Bateson STEM 433, 1968
- ↑ Bateson, STEM 455
- ↑ STEM 435 Bateson also gives an account of this in Stewart Brand's For God Sake Margaret!, Co-Evolutionary Quarterly 197*
- ↑ StEM 435
- ↑ Bateson, StEM 437
- ↑ Bateson StEM, 438
- ↑ Bateson STEM, 438
- ↑ Bateson STEM,439
- ↑ Bateson STEM,440
- ↑ Bateson StEM,441
- ↑ STEM 441
- ↑ STEM 495
- ↑ Gregory Bateson, Awake, Radical Software No 5 Volume 1, p.33
- ↑ Bateson Restructuring the Ecology of a Great City, Radical Software no 4 1970
- ↑ Bateson STEM, page?
- ↑ It was in the period of Radical Software that art became about self-reflexivity In the first instance it was not intended to be art in any conventional sense (no declarable art products were produced), it was rather an extension and expression of lives lived, an augmentation of potential. In this sense it was a negation of art which has been at the heart of the discourse of art since the birth of modernism, but it nevertheless provided a new condition that art recognised its own self-reflexivity – self-reflexivity was thereafter a condition of artistic production.