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A Sourcebook for the Worldwide Discovery of a Creative Organic Universe
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II. Pedia Sapiens: A Planetary Progeny Comes to Her/His Own Actual Factual Knowledge

C. Earth Learns: Interactive Person/Planet, Self-Organizing, Daily Collaboratiions

Johnson, Norman, et al. Symbiotic Intelligence: Self-Organizing Knowledge on Distributed Networks Driven by Human Interaction. Christoph Adami, ed. Artificial Life VI. Cambridge: MIT Press, 1998. How a symbiosis of people and the Internet can enhance the societal ability for collective problem solving.

Furthermore, in the same manner as to how society self-organized to solve problems of survival, the same processes on the Net will result in the self-organization of knowledge. Because self-organizing knowledge arises from diverse contributions and can encompass knowledge greater than the contribution of any individual, there is the arguable potential of creating knowledge that will contribute to solutions that are not understandable within our current processes. (405)

Jolly, Alison. Lucy’s Legacy. Cambridge: Harvard University Press, 1999. An anthropologist finds in the evolution of sex and intelligence more evidence for cooperation than competition. A consistent, widespread pattern appears of diverse, recurrent, nested systems from the bacterial realm to cells, organisms, and human groupings.

We seem now to be in the midst of a fifth major transition: the joining of human societies into a global network. (28) We have traced the emergence of biological organization from primeval chemistry to bacterium to cell to body. At each stage a larger, coherent whole emerged from the linkage of independent parts. Each is a holon, simultaneously one and many, a single organism and yet a community of individuals. (408)

Jones, NIcola. The Learning Machines. Nature. 505/146, 2014. An excellent report about how the artificial intelligence endeavor, after many fitful years is lately aided by big data and cloud prowess so as to attain a mature capabilities. A pioneer for this phase has been the University of Toronto computer scientist Geoffrey Hinton, a recent Google hire, who with colleagues and students conjured “deep recurrent neural networks” based on the cortical algorithmic connections of human brains. Readers can access a wide web of info and players – Andrew Ng, Yann LeCun, Yoshua Bengio, Jitendra Malik – many papers on arXiv. The result is a promising new dimension or noosphere just opening for imaginative development and public service. Another good entry is “The Man Behind the Google Brain: Andrew Ng and the Quest for the New AI” in Wired, online May 7, 2013.

Three years ago, researchers at the secretive Google X lab in Mountain View, California, extracted some 10 million still images from YouTube videos and fed them into Google Brain — a network of 1,000 computers programmed to soak up the world much as a human toddler does. After three days looking for recurring patterns, Google Brain decided, all on its own, that there were certain repeating categories it could identify: human faces, human bodies and … cats. (146)

Deep Learning is a first step in this new direction. Basically, it involves building neural networks — networks that mimic the behavior of the human brain. Much like the brain, these multi-layered computer networks can gather information and react to it. They can build up an understanding of what objects look or sound like. With Deep Learning, Ng says, you just give the system a lot of data ‘so it can discover by itself what some of the concepts in the world are.’ (Wired)

Kaynak, Okyay, et al. Towards Symbiotic Autonomous Systems. Philosophical Transactions of the Royal Society A.. August, 2021. Bogazici University, Istanbul, Maladalen University, Sweden, and University of Science and Technology, Beijing engineers (surely a sapiensphere collaboration) introduce a special issue on present endeavors to achieve and enhance human - computer interface facilities and potentials. A common theme is that these Earthuman multiplex connectivities, by way of reciprocal interactions, will acquire an intelligent capability to learn and gain knowledge on their own. See the main paper by Yingxu Wang, et al herein for a copious explanation. And by a vista across centuries, this scientific journal founded by Isaac Newton can now report an historic spiral and ascent to a consummate worldwise phase, with a promise of a consummate discovery.

Starting in the last century, the widespread use of computers has changed the lifestyles of humankind. Since then, in Digital technology, the worldwide web, Internet of Things and artificial intelligence have led a growing interaction and empowerment among humans and technical devices. Looking ahead, this integration is tending to create symbiotic autonomous systems (SASs). What matters in the context of SASs is the degrees of autonomy they have, their capability to evolve (e.g. to learn and adapt), and their ability to interact with their environment, between themselves, and with ourselves. (Abstract excerpt)

Kelly, Kevin. Scan This Book. New York Times Magazine. May 14, 2006. A movement to digitally record the world’s non-fiction and fiction print materials, and to make them freely available to everyone, anywhere, is fast becoming a reality. In a few years a person will be able to access on a PC or even PDA the entirety of human knowledge. By so doing, the universal library of Alexandria is now realized on a global scale. With a total search capability, any work, whether classic, textbook, manual, or novella, will be instantly available. And it is our website premise that such a grand repository, due to an emergent worldwide humanity, might indeed be achieving its own integral discovery

Kelly, Kevin. The Planetary Computer. Wired. July, 2008. As the worldwide electronic web intensifies, the magazine’s cofounder and complexity sage advances one of the most complete comparisons of such a noosphere with the dynamic anatomy and physiology of a human brain. Similar trillions of neural synapses and terabytes of script and image processing serve to outline the advent of a true global cerebration. But the step to imagine that a novel planetary person could attain her/his own salutary discovery and knowledge still eludes.

Kelly, Kevin. We Are The Web. Wired. August, 2005. Writer, editor and web pioneer Kelly surveys the logarithmic worldwide interconnection of personal computers since the 1980’s and 1990’s and looks ahead to its completion circa 2015. By this scope, its developing structure of fractal, neural-like networks appears as a planetary encephalization similar to a human brain. Metaphors do mix and it is also called a global Machine. But I add such an emergent noosphere is not yet appreciated for a potential to achieve common understanding and knowledge, accessible to everyone.

Over time, a Wikipedia article becomes totally underlined in blue as ideas are cross-referenced. That massive cross-referencing is how brains think and remember. It is how neural nets answer questions. It is how our global skin of neurons will adapt autonomously and acquire a higher level of knowledge. (133)

Kodama, Tatsuki, et al.. Generalized early dark energy and its cosmological consequences. arXiv:2309.11272. We use this entry by Saga University, Japan physicists to gather three current whole universe studies from Japan, China and Italy. We place the record in our Earth Learn section to convey how much all these scientific frontiers are truly a common global endeavor. They also evince that such awesome abilities seem to spontaneously arise whereever they can. Thirdly, we record how fantastic it is that collective human beings are capable of such infinite vistas, as if carrying out some descriptive project. Here is their citation and brief abstract.

We investigate cosmological consequences of a generalized early dark energy (EDE) model where a scalar field exists at various cosmological epochs for a broad range of parameters. We consider power-law and axion-type potentials for such an EDE field and study how it affects the cosmological evolution. We show that gravitational wave background can be enhanced to be detected in future observations. (2309.11272)

Liu, Liang, et al. Constraining the spatial curvature of the local Universe with deep learning. arXiv:2309.11334. A similar contribution by Mianyang Teachers’ College, China astro-researchers.

We use the distance sum rule (DSR) method to constrain the spatial curvature of the Universe with a large sample of strong gravitational lensing (SGL) systems, whose distances are calibrated from the Pantheon compilation of type Ia supernovae (SNe Ia) using deep learning. We investigate the possible influence of the lens galaxy on constraining the curvature parameter by three different models. (2309.11334)

Bottaro, Salvatore, et al. Unveiling dark forces with the Large Scale Structure of the Universe. arXiv: 2309.11496. This is an entry by five physicists posted in Italy and Israel.

Cosmology offers opportunities to test Dark Matter independently of its interactions with the Standard Model. We study the imprints of long-range forces acting solely in the dark sector on the distribution of galaxies, the so-called Large Scale Structure. Along the way we develop, for the first time, the Effective Field Theory of LSS in the presence of new dynamics in the dark sector. (2309.11496)

Kozlowski, Wojciech and Stephanie Wehner. Towards Large-Scale Quantum Networks. arXiv:1909.08396. QuTech, Delft University of Technology physicists continue to scope out the growing possibility by way of rapid advances in quantum computation of a local and global webworks with meta-capabilities.

The vision of a quantum internet is to fundamentally enhance Internet technology by enabling quantum communication between any two points on Earth. While the first realisations of small scale quantum networks are expected in the near future, scaling such networks presents immense challenges to physics, computer science and engineering. Here, we provide a gentle introduction to quantum networking targeted at computer scientists, and survey the state of the art. We proceed to discuss key challenges for computer science in order to make such networks a reality. (Abstract)

Kraut, Robert, et al. Scientific Foundations: A Case for Technology-Mediated Social- Participation Theory. Computer. November, 2010. At this late hour, at a mid-point of the first decades of a new millennium, one might report that across a broad range of fields and endeavors, a breakthrough maturity and credence seems to be just now attained. In this case, a team which includes MIT’s Tom Malone states a strong claim that our way forward must involve increasing efforts to foster and access socially “collective and collaborative intelligences.” This approach can then be advanced by tailoring worldwide knowledge gaining and sharing websites such as Wikipedia, the online encyclopedia, TopCoder for communally written software, eBird for multiuser tracking of migrations, and myriad others that pool thousands of participants to achieve a common goal. A novel aspect (see Malone below) is to see such efforts in genetic terms, another is to realize (Woolley, et al, herein) that these vast “collaboratories” can acheive a group cognizance on their own.

Bringing the TMSP research community together to work toward making theoretical advances and developing the underlying technologies present several challenges. These include meeting the general need for theoretical integration across levels of analysis (for example, from individual psychology and behavioral economics through social processes and organizational dynamics), within levels (such as communication, relationship formation, and trust building), and across theoretical frameworks and representations (for example, dynamic systems, random graph theory, and computational cognition). (23)

Krumov, Lachezar, et al. Motifs in Co-Authorship Networks and Their Relation to the Impact of Scientific Publications. European Physical Journal B. Online First, March, 2011. We highlight this report by Technical University Darmstadt, Martin Luther University, and Jacobs University computer scientists for its perception that similar viable topologies and dynamics reoccur across widely separate realms of genomes, brains, and earth’s self-organizing education sphere, and are akin to modes of information processing.

Co-authorship networks, where the nodes are authors and a link indicates joint publications, are very helpful representations for studying the processes that shape the scientific community. At the same time, they are social networks with a large amount of data available and can thus serve as vehicles for analyzing social phenomena in general. Here we show that the success of individual authors or publications depends unexpectedly strongly on an intermediate scale in co-authorship networks. We find that the average citation frequency of a group of authors depends on the motifs these authors form. In particular, a box motif (four authors forming a closed chain) has the highest average citation frequency per link. We also relate this topological observation to the underlying social and socio-scientific processes that have been shaping the networks. (Abstract)

An interesting alternative to these simulation-driven studies is to explore the relationship between network architecture and dynamics from a data-analysis perspective, i.e. to extract this relationship from large-scale data sets, which can be expected to be produced, at least partly, by the dynamics of the network at hand. Evidences for network architecture being a clearly discernible, quantifiable component, contributing to the patterns observed in data, exist from a diverse range of fields: gene expression patterns, both on the level of whole transcriptional regulatory networks and on the scale of small regulatory devices… (1-2)

We showed that some aspects of citation data are a consequence of the pattern of collaboration, rather that of the individual collaborators themselves. The outstanding role of the box motif, given by the highest average edge weight, the fact that the two authors in a box motif with the highest weight are typically adjacent, the high betweenness and long construction time, all give a first insight into the self-organization processes underlying the production of knowledge. (5)

Last, Cadell. Global Brain: Foundations of a Distributed Singularity. Korotayev, Andrey and David LePoire, eds. The 21st Century Singularity and Global Futures. International: Springer, 2019. A Bertalanffy Center for the Study of Systems Science, Vienna scholar achieves a well researched, thoughtful essay upon the emergent formation of an informational worldwise phase of collective, informed intelligence. It is proposed that this evident presence appears to have a capability to gain actual knowledge by its own analogous cognizance. In regard, if this spherical sapience can be rightly identified, enhanced and availed, it could provide a vital resource to advise, edify and solve dire problems which are otherwise intractable. See also the author’s 2020 book Global Brain Singularity (Springer) which is his doctoral thesis at the Free University of Brussels with Francis Heylighen.

Global Brain is a concept used to describe and understand the distributed, self-organizing intelligence currently emerging from all people and information-communication technologies (ICT) connected via the Internet. In its future network form it could become more intelligent and coherent with the capability to coordinate the functional operations of human civilization. Such a system would represent a new level of organized complexity which would allow people to deal with planetary problems that cannot be solved by contemporary methods. Thus, in a Global Brain metasystem, the human possibility space would open up levels of freedom and opportunity which have never before existed in evolutionary history. (Abstract)

“Global Brain” is a helpful metaphor to understand how our modern human society has become mediated by Internet functions like a biological brain. Here we posit that as brains produce intelligence, goal-directedness, and consciousness, so our species as a whole civilization produces higher order intelligence, goal-directedness, and consciousness. In positive regard, a Global Brain would help the human superorganism solve problems too complex for any lower level of intelligent organization. In another way, neurons within neural networks process information in a parallel and distributed fashion transmitting information; this is the same basic structural pattern used by humans to transmit information via the Internet. (3, edits)

Therefore, the Global Brain may be a useful metaphor for describing a distributed and self-organizing planetary superintelligence emerging from humans and ICT interacting and learning via the Internet. (4) But importantly for our inquiry, the idea of the Earth itself as a superorganism asks us to reflect on the possibility that the Global Brain would function as the structure of a nervous system. Thus, just as animals grew increasingly sophisticated brains so that they could make better models of the world and eventually their own models (self-consciousness), the Earth could be forming a brain so that it can accurately model its surrounding environment (i.e., the universe). (5)

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