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[1]Ivars MathLand

space February 22, 1997 Rule

From Counting to Writing

Tokens

We learn to count at such an early age that we tend to take the notion
of abstract numbers for granted. We know the word "two" and the symbol
"2" express a quantity that we can attach to apples, oranges, or any
other object. We readily forget the mental leap required to go from
counting specific things to the abstract concept of number as an
expression of quantity.

Abstract numbers are the product of a long cultural evolution. They
also apparently played a crucial role in the development of writing in
the Middle East. Indeed, numbers came before letters, contends
archaeologist Denise Schmandt-Besserat of the University of Texas in
Austin. In her fascinating, newly published book How Writing Came
About, she describes the evidence and reasoning that led her to such a
startling conclusion.

When Schmandt-Besserat began her studies nearly 3 decades ago, she was
looking for the earliest examples of the human use of clay. She went
from museum to museum, reviewing clay collections from Middle Eastern
cultures that thrived between 8000 and 6000 B.C. She expected to see
bricks, beads, and figurines. To her surprise, she also discovered
hoards of little clay objects that could easily pass for children's
playthings.

The clay objects came in a variety of geometric shapes, including
cones, spheres, disks, cylinders, and tetrahedrons. Some appeared to
be miniature models, an inch or less in size, of animals and tools.
Perforations and various markings adorned other objects.

Tokens

Examples of clay tokens.

The first appearance of such tokens in the archaeological record of
the Middle East coincides with the development of agriculture in the
period from 8000 to 7500 B.C. The Sumerians, formerly hunters and
gatherers, began settling in villages in the fertile valley of the
Tigris and Euphrates rivers.

Archaeological studies of the period show evidence of grain
cultivation in fields surrounding villages, the construction of
communal silos for storing grain, and a rapid increase in population.
In such a setting, individual farmers needed a reliable way to keep
track of their goods, especially the amount of grain stored in shared
facilities.

It seems they did it by maintaining stocks of baked-clay tokens -- one
token for each item, different shapes for different types of items. A
marble-sized clay sphere stood for a bushel of grain, a cylinder for
an animal, an egg-shaped token for a jar of oil. There were as many
tokens, or counters, of a certain shape as there were of that item in
the farmer's store.

Thus, tokens could be lined up in front of accountants, who doubtless
organized them according to types of goods and transactions. They
could even be arranged in visual patterns to make estimation and
counting easier.

This simple system of data storage persisted practically unchanged for
almost 4,000 years, spreading over a large geographic area.
Eventually, the growth of villages into cities and the increasing
complexity of human activities, especially in southern Mesopotamia,
forced a shift to a more versatile means of record keeping. That shift
was marked by the appearance of elaborate tokens alongside the
well-established system of simple counters. Though similar in size,
material, and color and fabricated in much the same way as their
plainer cousins, the new tokens bore surface markings and showed a
greater variety of shapes.

The elaborate tokens were apparently used for manufactured products --
the output of Sumerian workshops. Incised cones and rhomboids probably
represented loaves of bread and vessels of beer. Disks and parabolic
tokens marked with lines signified different types of fibers, cloths,
and finished garments. Incised cylinders and rectangles stood for
ropes and mats. Other tokens seem to have represented luxury goods,
including perfumes and various kinds of metalwork.

The advent of complex tokens coincided with the emergence of powerful
central governments and the construction of monuments and great
temples, beginning around 3350 B.C. Art from that period shows the
rise of a governing elite and the pooling of community resources for
celebrating large festivals. The token system, extended to cover goods
and services, played a key role in managing massive building projects
and orchestrating large public events.

Temple excavations reveal that the Sumerians often kept sets of tokens
in clay globes, or envelopes. Temple clerks marked the envelopes by
pressing tokens into the soft clay before sealing and baking them,
making visible the number and shape of tokens enclosed. Excavated
specimens show circular imprints left by spheres and wedge-shaped
imprints left by cones.

Once sealed in their clay cocoons, the tokens were hidden from view.
It didn't take long for busy bureaucrats to realize that once the clay
envelopes were marked, it was no longer necessary to keep the tokens.
In fact, the marks by themselves, impressed on a clay tablet, were
sufficient.

Complex tokens couldn't be stored in clay envelopes as conveniently as
simple counters because they often left indecipherable impressions.
Instead, perforations allowed such tokens to be strung together, with
special clay tags apparently identifying the accounts. In this case,
the shortcut the bureaucrats discovered was to inscribe the incised
pattern found on the surface of a complex token directly onto a clay
tablet. For example, they could replace an incised ovoid token with a
neatly drawn oval with a slash across it.

The result was a practical, convenient data storage system. A small
set of clay tablets with neatly aligned signs was much easier to
handle than an equivalent collection of loose tokens, and using a
stylus for marking clay tablets was a lot faster than making an
impression of every token.

Around 3100 B.C., someone had the bright idea that, instead of
representing, say, 33 jars of oil by repeating the symbol for one jar
33 times, it would be simpler to precede the symbol for a jar of oil
by numerals -- special signs expressing numbers. Moreover, the same
signs could be used to represent the same quantity of any item.

The signs chosen for this new role were the symbols for the two basic
measures of grain. The impressed wedge (cone) came to stand for 1 and
the impressed circle (sphere) for 10.

In this way, the token system evolved into a kind of shorthand in
which signs representing standard measures of grain, impressed on a
clay tablet, came to represent not grain or any other specific
commodity, but the concept of pure quantity. It was a revolution in
both accounting and human communication. For the first time, there was
a reckoning system applicable to any and every item under the sun.

Thus, "writing resulted not only from new bureaucratic demands but
from the invention of abstract counting," Schmandt-Besserat argues in
How Writing Came About. "The most important evidence uncovered is that
counting was not, as formerly assumed, subservient to writing; on the
contrary, writing emerged from counting."

Clay tokens became obsolete by 3000 B.C., replaced by pictographic
tablets that could represent not only "how many" but also "what,
where, when, and how." With the introduction of a new type of stylus,
pictographic writing developed into cuneiform notation. The resulting
record-keeping system proved so efficient and convenient that it was
used in the Middle East for the next 3,000 years.

"The tokens were mundane counters dealing with foods and other basic
commodities of everyday life, but they played a major role in the
societies that adopted them," Schmandt-Besserat concludes. "They were
used to manage goods, and they affected the economy; they were an
instrument of power, and they created new social patterns; they were
employed for data manipulation, and they changed a mode of thought.

"Above all," she continues, "the tokens were a counting and
record-keeping device and were the watershed of mathematics and
communication."

Copyright © 1996 by Ivars Peterson.

RedTriRule

References:

Peterson, I. 1990. Islands of Truth: A Mathematical Mystery Cruise.
New York: W.H. Freeman.

______. 1988. Tokens of plenty. Science News 134(Dec. 24&31):408.

Schmandt-Besserat, D. 1996. How Writing Came About. Austin, Texas:
University of Texas Press.

______. 1992. Before Writing: From Counting to Cuneiform. Austin,
Texas: University of Texas Press.

______. 1987. Oneness, twoness, threeness. The Sciences 27(No. 4):44.

______. 1986. An ancient token system: The precursor to numerals and
writing. Archaeology 39(November-December):32.

______. 1981. Decipherment of the earliest tablets. Science 211(Jan.
16):283.

______. 1980. The envelopes that bear the first writing. Technology
and Culture 21(July):357.

You can learn about the cuneiform writing system at
[2]http://www.sron.ruu.nl/~jheise/akkadian/cuneiform.html.

Illustration courtesy of the University of Texas Press.

Comments are welcome. Please send messages to Ivars Peterson at
[3]ip at scisvc.org.

Ivars Peterson is the mathematics and physics writer at Science News.
He is the author of The Mathematical Tourist, Islands of Truth,
Newton's Clock, and *Fatal Defect (now available in paperback). His
current work in progress is The Jungles of Randomness (to be published
in 1997 by Wiley).

*NOW AVAILABLE in paperback: Fatal Defect: Chasing Killer Computer
Bugs by Ivars Peterson. Vintage Books, 1996. ISBN 0-679-74027-9. U.S.
$13.00.

RedTriRule

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