Have you considered growth systems as physical structures in the environment that develop through locally creative evolution of their unbalanced circular processes? The growth systems that produce changes of state could then be seen to do so by resolving their internal imbalances by in the same locally experimental way. If systems are their whole complex of parts, all contributing independently, wouldn't it make more sense to say that in this accumulative experimental way they're discovering their rules rather than following them?
-- Phil Henshaw ¸¸¸¸.·´ ¯ `·.¸¸¸¸ ~~~~~~~~~~~~~~~~~~~~~~~~ 680 Ft. Washington Ave NY NY 10040 tel: 212-795-4844 e-mail: [EMAIL PROTECTED] explorations: www.synapse9.com --------- Original Message -------- From: The Friday Morning Applied Complexity Coffee Group <[email protected]> To: [email protected] <[email protected]> Subject: [FRIAM] HBR: Breakthrough Ideas for 2007 Date: 01/30/07 13:51 > > > From the article by G. West. rl > > > 11. Innovation and Growth: Size Matters * > > Executives talk about their companies DNA and roles in business > ecosystems, but the analogy to living organisms is more than > metaphorical. Like the mathematical laws governing how organisms > metabolism, growth, evolution, and mortality depend on size, there > are rules that appear to govern the growth, performance, and even > decline of cities and other social organizations. Although we cant > yet predict how specific cities or companies will evolve, weve found > general mathematical relationships between population size, > innovation, and wealth creation that may have important implications > for growth strategy in organizations. > > In biology, different species are in many ways scaled versions of one > another. Bacteria, mice, elephants, sequoias, and blue whales may > look different, but most of their fundamental characteristics, > including energy and resource use, genome length, and life span, > follow simple mathematical rules. These take the form of so-called > power-law scaling relationships that determine how such > characteristics change with size. For example, metabolic rate > increases as the ¾ power of mass. Put simply, the scaling law says > that if an organisms mass increases by a factor of 10,000 (four > orders of magnitude), its metabolic rate will increase by a factor of > only 1,000 (three orders of magnitude). This represents an enormous > economy of scale: the bigger the creature, the less energy per pound > it requires to stay alive. This increase of efficiency with size > manifested by the scaling exponent ¾, which we say is sublinear > because its less than onepermeates biology. These ubiquitous > scaling laws have their origin in the universal properties of the > networks that sustain life, such as the cardiovascular and > respiratory systems. > > Social organizations, like biological organisms, consume energy and > resources, depend on networks for the flow of information and > materials, and produce artifacts and waste. So it would not be > surprising if they obeyed scaling laws governing their growth and > evolution. Such laws would suggest that New York, Santa Fe, New > Delhi, and ancient Rome are scaled versions of one another in > fundamental waysas, potentially, are Microsoft, Caterpillar, Tesco, > and Pan Am. To discover these scaling laws, Luís Bettencourt at Los > Alamos National Laboratory, José Lobo at Arizona State University, > Dirk Helbing at TU Dresden, and I gathered data across many urban > systems in different countries and at different times, addressing a > wide range of characteristics including energy consumption, economic > activity, demographics, infrastructure, intellectual innovation, > employment of supercreative people, and patterns of human behavior > such as crime rates and rates of disease spread. > > We did indeed find that cities manifest power-law scaling similar to > the economy-of-scale relationships observed in biology: a doubling of > population requires less than a doubling of certain resources. The > material infrastructure that is analogous to biological transport > networksgas stations, lengths of electrical cable, miles of road > surfaceconsistently exhibits sublinear scaling with population. > > However, to our surprise, a new scaling phenomenon appeared when we > examined quantities that are essentially social in nature and have no > simple analogue in biologythose associated with innovation and > wealth creation. They include patent activity, number of > supercreative people, wages, and GDP. For such quantities the > exponent (the analogue of ¾ in metabolic rate) exceeds 1, clustering > around a common value of 1.2. Thus, a doubling of population is > accompanied by more than a doubling of creative and economic output. > We call this phenomenon superlinear scaling: by almost any measure, > the larger a citys population, the greater the innovation and wealth > creation per person. > > By almost any measure, the larger a citys population, the greater > the innovation and wealth creation per person. > > Organismic growth, constrained by sublinear power-law scaling derived > from the dynamics of biological networks, ultimately ceases, with the > equations predicting what size organisms will reach. In contrast, our > equations predict that growth associated with superlinear scaling > processes observed in social organizations is theoretically > unbounded. This would seem to bode well for organizations. > Unfortunately, however, the equations also predict that in the > absence of continual major innovations, organizations will stop > growing and may even contract, leading to either stagnation or > ultimate collapse. Furthermore, to prevent this, the time between > innovations (the innovation cycle) must decrease as the system grows. > > Though our research has focused on cities, the social and structural > similarities between cities and firms suggest that our conclusions > extend to companies and industries. If so, the existence of > superlinear scaling that links size and creative output has two > important consequences: First, it challenges the conventional wisdom > that smaller innovation functions are more inventive, and perhaps > explains why few organizations have ever matched the creativity of a > giant like Bell Labs in its heyday. Second, it shows that because > organizations and industries must apparently innovate at a > continually accelerating rate to avoid stagnation, economizing by > reflexively cutting R&D budgets and creative staffs may be a > dangerous strategy over the long term. > > Geoffrey B. West ([EMAIL PROTECTED]) is the president of the Santa Fe > Institute in Santa Fe, New Mexico. > > > > > > > > > > > > > > ============================================================ > FRIAM Applied Complexity Group listserv > Meets Fridays 9a-11:30 at cafe at St. John's College > lectures, archives, unsubscribe, maps at http://www.friam.org > > ============================================================ FRIAM Applied Complexity Group listserv Meets Fridays 9a-11:30 at cafe at St. John's College lectures, archives, unsubscribe, maps at http://www.friam.org
