Not for everyone but here is a snip from a remarkable site on General
Systems Theory. The idea of this snip is to highlite feedback as an essential
element of information transfer.
The reason to post this is to point out the importance of forums
such as this to put feedback into our information sturcture. Without such
feedback the flows of information become closed or cease to exist. This
isn't a great way to justify alot of the information posted here and elsewhere
but some of the posters over the Y2K alarmist era have produced effects
that may continue well into the 21st. century.
To me the important part is not the content of the feedback but the
efficency of the information transfer itself.
I hope the forum evolves into something greater than it is. To do that
we must continue on the path of making what we do part of a greater whole.
Y2K is passing, to where do we go now? The future?
If anyone is interested in General Systems Theory I highly recommend the site below. It is impressive.
Enjoy
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lesson1
This lesson is designed to be an introduction
to General Systems Theory. The texts presented here are concerned with
those characteristics typical of all systems, whether mechanical, biological,
or social.
The idea of a general theory of all systems
was introduced by Ludwig von Bertalanffy, whose now classic essay �The
Meaning of General Systems Theory� is reproduced below.
Big Snip
Information and Entropy
Another development which is closely connected with system theory is
that of the modern theory of communication. It has often been said that
energy is the currency of physics, just as economic values can be expressed
in dollars or pounds. There are, however, certain fields of physics and
technology where this currency is not readily acceptable. This is the case
in the field of communication which, due to the development of telephones,
radio, radar, calculating machines, servomechanisms and other devices,
has led to the rise of a new branch of physics.
The general notion in communication theory is that of information. In
many cases, the flow of information corresponds to a flow of energy, e.g.,
if light waves emitted by some objects reach the eye or a photoelectric
cell, elicit some reaction of the organism or some machinery, and thus
convey information. However, examples can easily be given where the flow
of information is opposite to the flow of energy, or where information
is transmitted without a flow of energy or matter. The first is the case
in a telegraph cable, where a direct current is flowing in one direction,
but information, a message, can be sent in either direction by interrupting
the current at one point and recording the interruption at another. For
the second case, think of the photoelectric door openers as they are installed
in many supermarkets: the shadow, the cutting off of light energy, informs
the photocell that somebody is entering, and the door opens. So information,
in general, cannot be expressed in terms of energy.
There is, however, another way to measure information, namely, in terms
of decisions. Take the game of Twenty Questions, where we are supposed
to find out an object by receiving simple "yes" or "no" answers to our
questions. The amount of information conveyed in one answer is a decision
between two alternatives, such as animal or nonanimal. With two questions,
it is possible to decide for one out of four possibilities, e.g., mammal�nonmammal,
or flowering plant�nonflowering plant. With three answers, it is a decision
out of eight, etc. Thus, the logarithm at the base 2 of the possible decisions
can be used as a measure of information, the unit being the so-called binary
unit or bit. The information contained in two answers is log2 4 = 2 bits,
of three answers, log2 8 = 3 bits, etc. This measure of information happens
to be similar to that of entropy or rather negative entropy, since entropy
also is defined as a logarithm of probability. But entropy, as we have
already heard, is a measure of disorder; hence negative entropy or information
is a measure of order or of organization since the latter, compared to
distribution at random, is an improbable state.
A second central concept of the theory of communication and control
is that of feedback. A simple scheme for feedback is the following (Fig.
2.1).
FIGURE 2.1
The system comprises, first, a receptor or "sense organ," be it a photoelectric
cell, a radar screen, a thermometer, or a sense organ in the biological
meaning. The message may be, in technological devices, a weak current,
or, in a living organism, represented by nerve conduction, etc. Then there
is a center recombining the incoming messages and transmitting them to
an eflfector, consisting of a machine like an electromotor, a heating coil
or solenoid, or of a muscle which responds to the incoming message in such
a way that there is power output of high energy. Finally, the functioning
of the effector is monitored back to the receptor, and this makes the system
self-regulating, i.e., guarantees stabilization or direction of action.
Feedback arrangements are widely used in modern technology for the stabilization
of a certain action, as in thermostats or in radio receivers; or for the
direction of actions towards a goal where the aberration from that goal
is fed back, as information, till the goal or target is reached. This is
the case in self-propelled missiles which seek their target, anti-aircraft
fire control systems, ship-steering systems, and other so-called servomechanisms.
There is indeed a large number of biological phenomena which correspond
to the feedback model. First, there is the phenomenon of so-called homeostasis,
or maintenance of balance in the living organism, the prototype of which
is thermoregulation in warmblooded animals. Cooling of the blood stimulates
certain centers in the brain which "turn on" heat-producing mechanisms
of the body, and the body temperature is monitored back to the center so
that temperature is maintained at a constant level. Similar homeostatic
mechanisms exist in the body for maintaining the constancy of a great number
of physicochemical variables. Furthermore, feedback systems comparable
to the servomechanisms of technology exist in the animal and human body
for the regulation of actions. If we want to pick up a pencil, a report
is made to the central nervous system of the distance by which we have
failed to grasp the pencil in the first instance; this information is then
fed back to the central nervous system so that the motion is controlled
till the aim is reached.
So a great variety of systems in technology and in living nature follow
the feedback scheme, and it is well-known that a new discipline, called
Cybernetics, was introduced by Norbert Wiener to deal with these phenomena.
The theory tries to show that mechanisms of a feedback nature are the base
of teleological or purposeful behavior in man-made machines as well as
in living organisms, and in social systems.
It should be borne in mind, however, that the feedback scheme is of
a rather special nature. It presupposes structural arrangements of the
type mentioned. There are, however, many regulations in the living organism
which are of essentially diflerent nature, namely, those where the order
is effectuated by a dynamic interplay of processes. Recall, e.g., embryonic
regulations where the whole is reestablished from the parts in equifinal
processes. It can be shown that the primary regulations in organic systems,
i.e., those which are most fundamental and primitive in embryonic development
as well as in evolution, are of the nature of dynamic interaction. They
are based upon the fact that the living organism is an open system, maintaining
itself in, or approaching a steady state. Superposed are those regulations
which we may call secondary, and which are controlled by fixed arrangements,
especially of the feedback type. This state of aflairs is a consequence
of a general principle of organization which may be called progressive
mechanization. At first, systems�biological, neurological, psychological
or social�are governed by dynamic interaction of their components; later
on, fixed arrangements and conditions of constraint are established which
render the system and its parts more efficient, but also gradually diminish
and eventually abolish its equipotentiality. Thus, dynamics is the broader
aspect, since we can always arrive from general system laws to machinelike
function by introducing suitable conditions of constraint, but the opposite
is not possible.