Jon Fox

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Four thousand years BCE in the ancient Near East, a region we have come to describe as the cradle of civilisation, Sumerian scribes made replicas of their minds in mud and created the clay tablet - the world's first silicate chip.

Five thousand years later, silicon semiconductors, ferromagnetic films and floating gate transistors have amplified the recording power of clay a quintillion times. Trends in processing and storage technology suggest to futurists that before too long, human thought, as the Babylonian mythology Enma Eli described so presciently, "shall be bound" and "to a unity brought together".

The technological singularity - that moment when humanity is surpassed by intelligent machines and absorbed by them - was first described by the mathematician Stanislaw Ulam, as a defining moment when "the ever accelerating progress of technology" leads to a point "beyond which human affairs, as we know them, could not continue". For the engineer Ray Kurzweil, this event marks overcoming the limitations of biological brains.

There is a tendency to view one's own time as uniquely sophisticated, to conceive of the past as primitive. Yet with clay tablets, humans overcame the limitations of their brains 5,000 years ago. The first singularity took place in the Stone Age. It is only recently that we have grasped what it means for individual brains to extend into the world of culture, fuse with the thoughts of society through the properties of physical artefacts and technologies, and then reabsorb the experience of the collective by accessing these technologies.

And what we have learnt is that the evolution of human intelligence is a continuous process of alternating outsourcing and reintegration, an endless series of fusions and fissions among individuals and collectives. To make this organic-inorganic narrative clear, let's consider numbers.

In the western world, we have grown complacent about our Indian-Arabic number system. These numbers possess both a zero and a place-based value. One might assume that previous number systems were less able and that our decimal numerals are a late and highly evolved means of representing magnitude and relation. This is far from the case. The two earliest number systems were Egyptian and Sumerian. The ancient Egyptian numbers were also base ten, and each power of ten was represented by a different hieroglyph - from strokes (one), to cattle (ten), ropes (100), and lotus flowers (1,000). The Sumerians used base 60, written in cuneiform characters, one for units and one for powers of ten. A legacy of the sexagesimal base persists in our units of time - 60 seconds to the minute and 60 minutes to the hour. Cultures are swimming in unfamiliar number systems: base 27 among the Oksapmin people of New Guinea; base 20 among the Yoruba of West Africa; and base 12 among the Nimbi of Nigeria.

In all of these culturally evolved instances, numbers were inscribed upon suitable physical materials to encode matters of great value and where the constraints of time and space would necessitate outsourcing of arithmetical and mathematical ideas. Numbers have evolved as a means of achieving long-lasting consensus. By being placed in the "public domain" these numbers have achieved incredible exponential returns through the collective deliberation of generations. Whereas thoughts restricted to individual brains depend entirely upon the knowledge and ability of one brain, ideas in the world can be manipulated across time and space by countless minds, and achieve through collective consideration a significant non-linear increase in stored knowledge.

It is, therefore, the combined memory (stored solutions that span generations) and computational (worked on by many individuals) representational powers of the silicate chip, and its many subsequent Stone-Age cousins, that make their realisation in history as candidate singularities.

It is true there is something about our contemporary solid-state artefacts that suggests a form of independence or autonomy from humans which merits special consideration. Whereas silicate chips need to be modified by hand, silicon chips can be modified by current. And although silicate chips can be transmitted across vast distances, they do so slowly, unlike calculations in silicon that travel at near light speed. On the other hand, silicate chips have successfully stored information for more than 5,000 years, whereas digital media is considered resilient if it can store information for more than a decade.

The evolution of human intelligence has always been about overcoming the constraints of soft organic matter. The adaptability of cells and tissues, their ability to perpetuate through replication, comes at a cost of fragility, limited scale and the needs of the generalist. Specialist tasks can be better served by more restrictive materials. And collective performance can be facilitated by platforms that support the combined activity of populations.

Our earliest cognitive platform was the silicate chip of the Sumerians - clay tablets upon which humanity achieved its primal, introductory singularity.

Excerpt from:

The roots of technological singularity can be traced backed to the Stone Age - Wired.co.uk