Lost in the Cosmos: The Last Self-Help Book (10 page)

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Authors: Walker Percy

Tags: #Humor, #Essays, #Semiotics

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DIAGRAM 1

Every element in the Cosmos is in interaction with every other element. The elements and systems of the Cosmos are still in interaction whether we are speaking of the radiation of energy in the electromagnetic spectrum or the attraction of gravity between bodies. In a sense, astrologers are right. The planet Saturn has an influence on me; it exerts a small gravitational attraction. I in turn exert a slight pull not only on the planet Saturn but upon the entire M31 galaxy in Andromeda. When I take a single step, I affect the rotation of the earth.

II

Some three and a half billion years ago, organic life began on this planet, perhaps earlier on other planets, perhaps not at all. A discharge of lightning might have caused the formation of organic molecules in the primordial soup, molecules which sooner or later happened to replicate themselves, though it is difficult to imagine how these events could have occurred accidentally. Perhaps there was another cause. Perhaps God was the cause. We do not know. At any rate, a new kind of system came into being, the organism. It had the extraordinary property of maintaining its internal milieu, its homeostasis, and of reproducing itself. Yet, different though it was from other systems, events within the organism and across the membrane of the organism as well as events in its environment could still be understood as the same kind of events—dyadic interactions which had occurred before:

The interactions of organisms with each other, whether sexual, combative, or predatory, could be similarly understood:

It is all very well to speak of the wonders of the Cosmos as testimony to the glory of God, and it may in fact be true, but it, the Cosmos, is hardly perceived as such in modern technological societies. For most scientists, it seems fair to say, these same wonders, including the behavior of organisms, can be explained as an interaction of elements. The wonder to the scientist is not that God made the world but that the works of God can be understood in terms of a mechanism without giving God a second thought. Is it not indeed more wonderful to understand the complex mechanisms (dyads) by which the DNA of a sperm joins with the DNA of an ovum to form a new organism than to have God snap his fingers and create an organism like a rabbit under a hat?

The real wonder is not that the Cosmos is now seen as wonderful but that it is not. Despite its inconceivable vastness, it is seen not as wonderful but as something that can be explained as a dyadic system.

III

It became useful to think of an organism as an open system which through the selective processes of evolution had developed a genetic code which enabled it to maintain an internal steady state (homeostasis) in a changing environment and to reproduce itself. Thus, all the elements and events in the Cosmos, including other organisms, could be thought of as the
environment
of the organism. The organism “responded” to those segments of its environment to which, through evolution, it had become genetically coded—hardwired—to respond: eating, fighting, avoiding some, approaching and mating with others. Those segments of the environment which were without biological significance were ignored:

There are many gaps in the environment of an organism. This is to say that though there may be an interaction between the mass of the organism and the mass of Jupiter, the organism does not respond to Jupiter in any observable way. Yet the organism, as in the case of a migrating bird, has been shown to respond to the magnetic field of the earth or the position of the sun.

IV

An organism may also, either by being genetically coded or by learning—that is, by modifying certain neurones in its central nervous system—respond to certain signals in its environment by a behavior oriented toward other segments of the environment. Thus, a Texas leaf-cutting ant which discovers a food source too big to move will deposit a trail of pheromones on the ground, which other ants will follow for several hundred meters from the nest:

The Texas leaf-cutting ant is genetically programmed so to respond. But Pavlov’s dog—or any other mammal exposed to certain changes in its environment—can
learn
to respond to a signal in an appropriate manner—by eating, fleeing, or fighting—through modification of cells in its central nervous system.

A gorilla
(A)
in its natural state can utter one of a dozen or so vocal signals which are responded to by other gorillas
(B, C,
... ) in an appropriate fashion—e.g., the bark
wraagh
is a signal of a sudden alarming situation, such as unexpected contact with buffalo, which signals flight in other gorillas.

The chimpanzee Lana has been taught by the Rumbaughs, through a learning program of rewards, to punch differently marked keys of a computer and “ask” for food, liquids, music, etc.

Next the Rumbaughs taught two chimpanzees to communicate with each other, e.g., one chimp punching a marked key to ask another chimp for a certain food to which the importuned chimp had access. The Rumbaughs called the marks on the computer keys “symbols” and the transaction between the two chimps “the first successful demonstration of symbolic communication between two nonhuman primates.”

Whereupon B. F. Skinner showed that two domestic pigeons
(Columba livia domestica)
could learn spontaneously to use such “symbols” to communicate with each other. The two pigeons, named Jack and Jill, could conduct a “conversation.” Jack was the observer and Jill the informer. Jack and Jill first learned to associate marked keys with three colors. Jill was taught to “name” three colors to respond to the keyboard-question “What color?” Jack was taught to select the color corresponding to the name. When the pigeons were correct, they were rewarded with grain. Then Jack learned to ask Jill for a color name by depressing the
WHAT COLOR?
key. Then Jill looked behind a curtain at a color hidden from Jack. Then, while Jack watched, Jill selected a “symbolic name” for the color. When Jill was right, Jack rewarded her by pushing the
THANK YOU
key. Then, while Jill moved to her reward, Jack selected the right color. Then Jack was rewarded.

Whether Skinner was out to discomfit the Rumbaughs and prove that pigeons are as smart as chimps, or whether both were out to prove that pigeons and chimps are as smart as people, or at least that their intelligences are not qualitatively different, we must admire the skill of both teams of investigators in teaching communication skills. But what has been called into question in these and like experiments is the use of words such as
language, symbols, sentences
to describe this kind of communication. Investigators such as Terrace and Sebeok have shown that such communication does not bear the test of language in the human sense, e.g., having a rule-governed syntax. One of the weaknesses of semiotics is the all-too-frequent use of words like
language
and
sentence
in a loose analogical sense.

This argument aside, what matters here is that these communications in Skinner’s pigeons and the Rumbaughs’ chimps can be understood perfectly well by Peirce’s familiar dyadic model, as a sequence of interactions or dyads:

This sequence can of course be broken down into smaller dyads, e.g., interactions between Jack’s conditioned neurones, electrical discharges along the efferent nerves leading to Jack’s pecking muscles, and so on.

An African gray parrot named Alex at Purdue University has been taught to call forty objects by name, identify five colors, and distinguish between a square, a triangle, and a pentagon. When he wants to return to his cage, he says, “Wanna go back.”

Many people, including some scientists, like to speak of the “language” of the Rumbaughs’ chimps, Skinner’s pigeons, and the Purdue parrot, to say nothing of the song of the humpback whale. These communications, however, bear little if any resemblance to human language. The former can be understood as dyadic events not qualitatively different, albeit much more complex, from other dyadic events in the Cosmos. The latter cannot be so understood.

V

Extremely recently in the history of the Cosmos, at least on the earth—perhaps less than 100,000 years ago, perhaps more—there occurred an event different in kind from all preceding events in the Cosmos. It cannot be understood as a dyadic interaction or a complexus of dyadic interactions.

It has been called variously triadic behavior, thirdness, the Delta factor, man’s discovery of the sign (including symbols, language, art).

This phenomenon occurred in the evolution of man. It may have occurred elsewhere in the Cosmos, or it may have occurred in other creatures on earth. We do not know. But it is not known to have occurred elsewhere in the Cosmos and it has not been proved—despite heroic attempts with chimps, gorillas, and dolphins—to have occurred in other earth species.

The present argument does not require that triadic behavior be unique in man. Perhaps it is not. Semiotics proposes only that where triadic behavior occurs, certain new properties and relationships also come into existence,

Triadic behavior is that event in which sign
A
is understood by organism
B,
not as a signal to flee or approach, but as “meaning” or referring to another perceived segment of the environment:

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