Gutenberg’s invention of metallic movable type elevated writing into a central position in the culture. By the means of cheap and perfect copies, text became the engine of change and the foundation of stability. From printing came journalism, science and the mathematics of libraries and law. The distribution-and-display device that we call printing instilled in society a reverence for precision (of black ink on white paper), an appreciation for linear logic (in a sentence), a passion for objectivity (of printed fact) and an allegiance to authority (via authors), whose truth was as fixed and final as a book. In the West, we became people of the book. Now invention is again

In fact, the habits of the mashup are borrowed from textual literacy. You cut and paste words on a page. You quote verbatim from an expert. You paraphrase a lovely expression. You add a layer of detail found elsewhere. You borrow the structure from one work to use as your own. You move frames around as if they were phrases.

It is a formidable task, but in the past decade computers have gotten much better at recognizing objects in a picture than most people realize. Researchers have started training computers to recognize a human face. Specialized software can rapidly inspect a photograph’s pixels searching for the signature of a face: circular eyeballs within a larger oval, shadows that verify it is spherical. Once an algorithm has identified a face, the computer could do many things with this knowledge: search for the same face elsewhere, find similar-looking faces or substitute a happier version.

This is more clearly seen at the extreme. The difference between four bottles of amino acids on a laboratory self and the four amino acids arrayed in your chromosomes lies in the additional structure, or ordering, those atoms get from participating in the spirals of your replicating DNA. Same atoms, more order. Those atoms of amino acids acquire yet another level of structure and order when their cellular host undergoes evolution. As organisms evolve, the informational code their atoms carry is manipulated, processed, and reordered. In addition to genetic information, the atoms now convey adaptive information. Over time, the same atoms can be promoted to new levels of order. Perhaps their one cell home joins another cell to become multicellular — that demands the informational architecture for a larger organism as well as a cell. Further transitions in evolution — the aggregation into tissues and organs, the acquisition of sex, the creation of social groups — continue to elevate the order and increase the structure of the information flowing through those same atoms.

The technium can be understood as a way of structuring information beyond biology. Foremost among all inventions is language, and its kin writing, which introduced a parallel set of symbol strings to those found in DNA. But the grammar and syntax of language far outstrips the flexibility of the genetic code. Literary inventions like the book index, punctuation, cross-references, and alphabetic order permitted incredibly complex structures within words; printing broadcast them. Calendars and other scripts captured abstractions such as time, or music. The invention of the scientific method in the 17th century was a series of deepening organizational techniques. Data was first measured, then recorded, analyzed, forecasted and disseminated. The wide but systematic exchange of information via wires, radio waves and society meetings upped the complexity of information flowing through the technium. Innovations in communications (phonograph, telegraph, television) sped up the rate of coordination, and also added new levels of systemization. The invention of paper was a more permanent memory device than the brain; photographic film even better. Cheap digital chips lowered the barrier for storing ephemeral information, further intensifying the density of information. Highly designed artifacts and materials are atoms stuffed with layers of complex information. The most mechanical superstructures we've ever built - say skyscrapers, or the Space Shuttle, or the Hadron Supercollider — are giant physical manifestations of incredibly structured information. There are many more hours of design poured into them than hours in manufacturing. Finally, the two greatest inventions in the last 25 years, the link and the tag, have woven new levels of complexity into the web of information. The technium of today reflects 8,000 years of almost da

To explain the how our minds work, or how evolution advances, we apply the pattern of a very large software program processing bits of information. None of these historical metaphorical pictures are wrong; just incomplete. Ditto for computation. But extropy must be more than information alone. We have thousands of years of science ahead of us. Information and computation can't be the most complex immaterial entity there is, just the most complex we've discovered so far. We might eventually discover that extropy involves quantum dynamics, or gravity, or even quantum gravity. But for now, information (in the sense of structure) is a better analogy than anything else we know of for understanding the nature of extropy. Following information will reveal a larger pattern.