This work is an attempt for a state-of-the-art survey of natural and life sciences with the goal to define the scope and address the central questions of an original research program. It is focused on the phenomena of emergence, adaptive dynamics and evolution of self-assembling, self-organizing, self-maintaining and self-replicating biosynthetic systems viewed from a newly-arranged perspective and understanding of computation and communication in the living nature. The author regards this research as an integral part of the emerging discipline of nature-inspired or natural computation, i.e. computation inspired by or occurring in nature. Within this context, he is interested in studies which represent a significant departure from traditional theories about complex systems and self-organization, emergent phenomena and artificial biology. In particular, these include non-conventional approaches exploring the aggregation, composition, growth and development of physical forms and structures, autopoiesis along with the associated abstract information structures and processes. This paper provides a critical review of the major assumptions which guide the development of modern computer science and engineering towards emulating biological systems. For this purpose, the author explores the potential and the virtues of biology to reshape contemporary science. The goal of this survey is to discuss the present state of natural and engineering sciences in the light of a necessary paradigm change in the structure and methodology of research and deliver some insights for developing a new kind of integral science based on the principles for dynamic interdependence of the constituting disciplines and on the evolving relationships among them.
Abstract. This paper discusses the rebirth of the old quest for the principles of biology along the discourse line of machine-organism disanalogy and within the context of biocomputation from a modern perspective. It reviews some new attempts to revise the existing body of research and enhance it with new developments in some promising fields of mathematics and computation. The major challenge is that the latter are expected to also answer the need for a new framework, a new language and a new methodology capable of closing the existing gap between the different levels of complex system organization.
This paper presents yet another personal reflection on one the most important concepts in both science and the humanities: time. This elusive notion has been not only bothering philosophers since Plato and Aristotle. It goes throughout human history embracing all analytical and creative (anthropocentric) disciplines. Time has been a central theme in physical and life sciences, philosophy, psychology, music, art and many more. This theme is known with a vast body of knowledge across different theories and categories. What has been explored concerns its nature (rational, irrational, arational), appearances/qualia, degrees, dimensions and scales of conceptualization (internal, external, fractal, discrete, continuous, mechanical, quantum, local, global, etc.). Of particular interest have been parameters of time such as duration ranges, resolutions, modes (present, now, past, future), varieties of tenses (e.g. present perfect, present progressive, etc.) and some intuitive, but also fancy phenomenological characteristics such as "arrow", "stream", "texture", "width", "depth", "density", even "scent". Perhaps the most distinct characteristic of this fundamental concept is the absolute time constituting the flow of consciousness according to Husserl, the reflection of pure (human) nature without having the distinction between exo and endo. This essay is a personal reflection upon time in modern physics and phenomenological philosophy.Keywords: space, time, consciousness, physics, mathematics, philosophy, phenomenology. ___________________________________________________________________ PrologueSpace and time are particularly modalities of human consciousness. Whereas space can be realized through our eyes and limbs, time remains elusive to our minds and still bothers philosophers since antiquity (Dyke & Bardon, 2013). In the beginning of the 20 th century science made a crucial switchover. Time was spatialized 1 . Until then the world was threedimensional. With the Special Relativity Theory (Einstein, 1905;Minkowski, 1909) the concept of time became the fourth dimension 2 and an integral element of the new physical worldview. It caused confusion among many of Einstein's contemporaries, and not only with its relativistic dilation in the well-known equation with the speed of light ť = t (1-(v/c) 2 ) ½ .1 It could be argued that time was spatialized earlier. Though time and space were separate for Newton (something that Einstein challenged), the clock time he assumed was laid out like space and was devoid of the dynamism of Bergsonian durée, (Bergson, 1912;Čapek, 1961). 2 It was Laplace who treated time as just another dimension equivalent to space, and thereby paved the way for the development of relativity theory as it came to be understood (but not as Čapek, following Bergson, understood it).This notion of relativistic time appeared wrong and unnatural, not without good reason, since:• Time is ineffable, eluding science and mathematics: it can only be grasped through intuition and shown indirectly and partia...
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