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A Sourcebook for the Worldwide Discovery of a Creative Organic Universe
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VII. Our Earthuman Ascent: A Major Evolutionary Transition in Twndividuality

2. Complex Local to Global Network Biosocieties

Gavrilets, Sergey and Peter Richerson. Collective Action and the Evolution of Social Norm Internalization. Proceedings of the National Academy of Sciences. 114/6068, 2017. A University of Tennessee ecologist and an UC Davis environmentalist trace a constant propensity for human groupings to evolve toward more beneficial behaviors via a formation of tacit, agreed standards.

People often ignore material costs they incur when following existing social norms. Some individuals and groups are often willing to pay extremely high costs to enact, defend, or promulgate specific values and norms that they consider important. Such behaviors, often decreasing biological fitness, represent an evolutionary puzzle. We study theoretically the evolutionary origins of human capacity to internalize and follow social norms. We focus on two general types of collective actions our ancestors were regularly involved in: cooperation to overcome nature’s challenges and conflicts with neighboring groups. We show that norm internalization evolves under a wide range of conditions, making cooperation “instinctive.” We make testable predictions about individual and group behavior. (Significance)

Gintis, Herbert. Strong Reciprocity and Human Sociality. Journal of Theoretical Biology. 206/2, 2000. Empirical studies can quantify a pervasive tendency for mutual aid among social assemblies.

Gligor, Mircea and Margareta Ignat. Some Demographic Crashes Seen as Phase Transitions. Physica A. 301/535, 2001. Population dynamics exhibit an underlying mathematical basis when modeled by nonlinear statistical theories.

The interest in searching for power laws in the description of complex, collective phenomena is caused by the fact that these power laws are universal, that is to a large degree independent of the microscopic details of the phenomenon. As such, they are typical features of a collective mechanism like the phase transitions: many observables behave as universal power laws in the vicinity of the transition point. Also, the interest for power laws is related to an important property of power laws, namely scale invariance: the characteristic length scale of a physical system at its crritical point is infinite, leading to self-similar, scale-free flucations. (536)

Goldstone, Robert and Marco Janssen. Computational Models of Collective Behavior. Trends in Cognitive Sciences. 9/9, 2005. A survey of how complex systems theory is bringing a new explanatory basis to the human sciences – sociology, economics, psychology, anthropology. By computational is meant the use of “agent-based models” whereby tacit rules inform interactions between autonomous entities as they self-organize into emergent group behaviors.

Goldstone, Robert, et al. Emergent Processes in Group Behavior. Current Directions in Psychological Science. 17/1, 2008. Researchers at Indiana University use agent-based computational models to quantify how human communities of many kinds might take on a life and cognitive capacity of their own.

Just as neurons interconnect in networks that create structured thoughts beyond the ken of any individual neuron, so people spontaneously organize themselves into groups to create emergent organizations that no individual may intend, comprehend, or even perceive. (10) Social phenomena such as the spread of gossip, the World-Wide Web, the popularity of cultural icons, legal systems, and scientific establishments all take on a life of their owe, complete with their own self-organized divisions of labor and specialization, feedback loops, growth, and adaptations. (10)

Gontier, Nathalie and Anton Sukhoverkhov.. Reticulate evolution underlies synergistic trait formation in human communities. Evolutionary Anthropology. 32/1,. Evolutionary Anthropology. 32/1, 2021. University of Lisbon and Kuban State Agrarian University scholars (search Gontier) continue to development and application of this generic network quality as it serves to link living beingness across all development scales and groupings.

This paper investigates how reticulate evolution contributes better understandings of sociocultural evolution, along with community formation. Reticulate evolution occurs more by means of symbiosis, symbiogenesis, lateral gene transfer, infective heredity, and hybridization. We zoom in on symbiosis and show how it distinguishes (1) human, plant, animal, and machine interactions; (2) diet-microbiome relationships; and (3) host-virome and other pathogens affect human health and disease. Reticulate evolution requires an understanding of behavioral and cultural evolution at a community level, where causal processes lead to synergistic organizational traits. (Abstract)

Reticulate evolution differs from the vertical version studied by the Neodarwinists. In the latter paradigm, the focus lies on how descent lines ramify and diversify into lineages by natural selection or drift. The branching out of lineages brings forth tree of life typologies that are classically understood to depict the gradual modification of species over time. Reticulate evolution instead requires network typologies and web of life metaphors that depict how organisms belonging to different species interact in space. (1)

Guimera, R., et al. Self-Similar Community Structure in a Network of Human interactions. Physical Review E. 065103, 2003. In theory complex networks form a hierarchical structure of nested “communities.” This is borne out by a study of a large university email system. The authors go on to state that such “spontaneous self-organization” is an example of a universally present natural principle.

By using the same argument, one can expect that the scaling behavior we obtain should be observable in any human social network. At the same time, the similarity with river networks suggests that a common principle of optimization – of flow of information in organizations or of flow of water in rivers – could be the underlying driving force in the formation and evolution of social networks. (065103-4)

Hackenberg, Robert and Beverly Hackenberg. Notes Toward a New Future: Applied Anthropology in Century XXI. Human Organization. 63/4, 2004. Still another field, in this case to also be “postmodern,” finds that “nonlinear dynamic systems” theories are especially suitable to advance the study of multifaceted human societies. The main paper is An Anthropological Problem, A Complex Solution by Michael Agar whence “a narrative of connections and contingencies” and agent-based modeling can apply, e.g., to urban epidemics of illicit drug use.

Hall, Gavin and William Bialek. The Statistical Mechanics of Twitter. arXiv:1812.07029. As a global science proceeds on its electronic own, cross-informative networks are forming between widely separate fields. Here is an exemplary paper by Princeton University theorists which reports a connection in kind between webwide social chatter and physical dynamics. It is noted that this public verbose media tends to critical attractor modes. Once more across a broad stretch from uniVerse to usVerse, a common, recurrent, biterate conservation and discourse goes on. See also Searching for Collective Behavior in a Small Brain by W. Bialek and colleagues (1810.07623).

We build models for the distribution of social states in Twitter communities which can be defined by the participation vs. silence of individuals in conversations that surround key words. We approximate the joint distribution of these binary variables using the maximum entropy principle, finding the least structured models that match the mean probability of individuals tweeting and their pairwise correlations. These models provide accurate, quantitative descriptions of higher order structure in these social networks. The parameters of these models seem poised close to critical surfaces in the space of possible models, and we observe scaling behavior of the data under coarse-graining. These results suggest that simple models, grounded in statistical physics, may provide a useful point of view on the larger data sets now emerging from complex social systems. (Abstract)

Hamilton, Marcus, et al. Nonlinear Scaling of Space Use in Human Hunter-Gatherers. Proceedings of the National Academy of Sciences. 104/4765, 2007. This report grew from research programs of James Brown’s group at the University of New Mexico, which studies biocomplexity, scaling and macroecology. It merits special notice because this work is one of the first quantifications of how human groupings take on the same patterns and processes as an organism. What can then be broadly implied is a nested biological continuity throughout emergent evolution, of which, as long proposed, human social community can be appreciated with isomorphic kinship to a somatic and cerebral organic entity.

Even though buried within the 200+ pages of a weekly scientific journal, the paper exemplifies a welling discovery by humankind of a profoundly different comprehensible nature and cosmos suffused by such universally recurrent mathematical form and function, a quickening genesis in our midst if we would attend to it, as this website is trying to document.

The result is a complex social structure in which resources flow through social networks, which exhibit self-similar or fractal-like hierarchical scaling and are strikingly similar, quantitatively, to the hierarchically branched vascular networks that distribute metabolic resources within the bodies of plants and mammals and water from river drainage basins. (4765) Our results demonstrate that individual space use in hunter-gatherer societies scales nonlinearly or allometrically with population size. Furthermore, this power-law scaling relation is robust to differences in trophic foraging niche, ecosystem temperature, energy availability, geographic location, and cultural phylogeny. (4768)

Hamilton, Marcus, et al. The Complex Structure of Hunter-Gather Social Networks. Proceedings of the Royal Society B. 274/2195, 2007. Researchers from the Universities of New Mexico and Chicago, and Santa Fe Institute, report that after many years of nonlinear studies, living systems from cells to cities can be known to spring from and be distinguished by the self-organizing dynamics of interactive entities. These propensities then proceed to create a nested, iterative societal scale. As the authors cite, this same phenomena occurs everywhere from physical and chemical phases to continental civilizations.

Science itself, via its male practitioners, is much about hunting and gathering. If to add some reflection (feminine right brain?), a greater reality just being revealed to human inquiry is not an alien morbidity but rather, as tradition teaches, graced by a stratified correspondence of microcosm and macrocosm, now found to be arrayed in a temporal genesis. A universality of animate form and dynamics, a 21st century theory of everywhere, would then imply an implicate, independent source. Our collaborative, bicameral work going forward is to brace and evoke such a life, person, and earth-affirming cosmology in the brief window we have to do so.

In nature, many different types of complex system form hierarchical, self-similar or fractal-like structures that have evolved to maximize internal efficiency. In this paper, we ask whether hunter-gatherer societies show similar structural properties. We use fractal network theory to analyze the statistical structure of 1189 social groups in 339 hunter-gatherer societies from a published compilation of ethnographies. We show that population structure is indeed self-similar or fractal-like… this remarkable self-similarity holds both within and across cultures and continents. We show that the branching ratio is related to density-dependent reproduction in complex environments and hypothesize that the general pattern of hierarchical organization reflects the self-similar properties of the networks and the underlying cohesive and disruptive forces that govern the flow of material resources, genes and non-genetic information within and between social groups. Our results offer insight into the energetics of human sociality and suggest that human social networks self-organize in response to similar optimization principles found behind the formation of many complex systems in nature. (2195)

Complex systems composed of multiple interacting parts tend to self-organize or evolve structures that maximize whole-system performance by optimizing the interactions among components. (2195) Our analyses show that not only are these societies internally self-similar, but also that this self-similarity is found across societies that differ widely in ecological, historical and genetic backgrounds. (2198)

Hamilton, Marcus, et al. The Ecological and Evolutionary Energetics of Hunter-Gather Residential Mobility. Evolutionary Anthropology. 25/3, 2016. . In an issue on Evolution of Human Mobility, a southwest, Santa Fe Institute, team of MH, Jose Lobo, Eric Ripley, Hyejin Youn, and Geoffrey West proceed to reconstruct this early phase by way of these qualitative aspects. See also by this group Nonlinear Scaling of Space Use in Human Hunter-Gatherers (PNAS 104/4765, 2007) and The Complex Structure of Hunter-Gatherer Social Networks (Proceedings of the Royal Society B 274/2195, 2007). And we wonder Whom is worldwise Anthropo/Cosmo Sapiens to retrospectively do this, what does it mean to realize that our daily, communal lives are moved and constrained by a mathematical independence?

Residential mobility is a key aspect of hunter-gatherer foraging economies and therefore is an issue of central importance in hunter-gatherer studies. Hunter-gatherers vary widely in annual rates of residential mobility. Understanding the sources of this variation has long been of interest to anthropologists and archeologists. The vast majority of hunter-gatherers who are dependent on terrestrial plants and animals move camp multiple times a year because local foraging patches become depleted and food, material, and social resources are heterogeneously distributed through time and space. In some environments, particularly along coasts, where resources are abundant and predictable, hunter-gatherers often become effectively sedentary. But even in these special cases, a central question is how these societies have maintained viable foraging economies while reducing residential mobility to near zero. (Abstract)

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