Morphological Sensitivity and Falling Behavior of Paper V-Shapes

Abstract Behavioral diversity seen in biological systems is, at the most basic level, driven by interactions between physical materials and their environment. In this context we are interested in falling paper systems, specifically the V-shaped falling paper (VSFP) system that exhibits a set of discrete falling behaviors across the morphological parameter space. Our previous work has investigated how morphology influences dominant falling behaviors in the VSFP system. In this article we build on this analysis to investigate the nature of behavioral transitions in the same system. First, we investigate stochastic behavior transitions. We demonstrate how morphology influences the likelihood of different transitions, with certain morphologies leading to a wide range of possible paths through the behavior-space. Second, we investigate deterministic transitions. To investigate behaviors over longer time periods than available in falling experiments we introduce a new experimental platform. We demonstrate how we can induce behavior transitions by modulating the energy input to the system. Certain behavior transitions are found to be irreversible, exhibiting a form of hysteresis, while others are fully reversible. Certain morphologies are shown to behave like simplistic sequential logic circuits, indicating that the system has a form of memory encoded into the morphology–environment interactions. Investigating the limits of how morphology–environment interactions induce non-trivial behaviors is a key step for the design of embodied artificial life-forms.

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Evolving Physically Simulated Flying Creatures for Efficient Cruising

Artificial Life ◽

10.1162/artl.2006.12.4.561 ◽

2006 ◽

Vol 12 (4) ◽

pp. 561-591 ◽

Cited By ~ 11

Author(s):

Yoon-Sik Shim ◽

Chang-Hun Kim

Keyword(s):

Energy Efficient ◽

Artificial Life ◽

Morphological Characteristics ◽

Life Forms ◽

The Body ◽

Fitness Evaluation ◽

Terrestrial Locomotion ◽

Wide Range ◽

Wing Structure ◽

Lift And Drag

The body-brain coevolution of aerial life forms has not been developed as far as aquatic or terrestrial locomotion in the field of artificial life. We are studying physically simulated 3D flying creatures by evolving both wing shapes and their controllers. A creature's wing is modeled as a number of articulated cylinders, connected by triangular films (patagia). The wing structure and its motor controllers for cruising flight are generated by an evolutionary algorithm within a simulated aerodynamic environment. The most energy-efficient cruising speed and the lift and drag coefficients of each flier are calculated from its morphological characteristics and used in the fitness evaluation. To observe a wide range of creature size, the evolution is run separately for creatures categorized into three species by body weight. The resulting creatures vary in size from pigeons to pterosaurs, with various wing configurations. We discuss the characteristics of shape and motion of the evolved creatures, including flight stability and Strouhal number.

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Fault effects in asynchronous sequential logic circuits

IEE Proceedings E (Computers and Digital Techniques) ◽

10.1049/ip-e.1993.0046 ◽

1993 ◽

Vol 140 (6) ◽

pp. 327-332

Author(s):

M.-D. Shieh ◽

C.-L. Wey ◽

P.D. Fisher

Keyword(s):

Logic Circuits ◽

Sequential Logic

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Artificial life and ‘nature’s purposes’: The question of behavioral autonomy

Human Affairs ◽

10.1515/humaff-2020-0052 ◽

2020 ◽

Vol 30 (4) ◽

pp. 587-596

Author(s):

Elena Popa

Keyword(s):

Artificial Life ◽

Life Forms ◽

Behavioral Traits ◽

Ethical Implications ◽

Autonomous Behavior ◽

Significant Difference ◽

Behavioral Autonomy ◽

Synthetic Life ◽

Biological Organisms

AbstractThis paper investigates the concept of behavioral autonomy in Artificial Life by drawing a parallel to the use of teleological notions in the study of biological life. Contrary to one of the leading assumptions in Artificial Life research, I argue that there is a significant difference in how autonomous behavior is understood in artificial and biological life forms: the former is underlain by human goals in a way that the latter is not. While behavioral traits can be explained in relation to evolutionary history in biological organisms, in synthetic life forms behavior depends on a design driven by a research agenda, further shaped by broader human goals. This point will be illustrated with a case study on a synthetic life form. Consequently, the putative epistemic benefit of reaching a better understanding of behavioral autonomy in biological organisms by synthesizing artificial life forms is subject to doubt: the autonomy observed in such artificial organisms may be a mere projection of human agency. Further questions arise in relation to the need to spell out the relevant human aims when addressing potential social or ethical implications of synthesizing artificial life forms.

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Mestizo Robotics

Leonardo ◽

10.1162/leon_a_01150 ◽

2017 ◽

Vol 50 (2) ◽

pp. 132-137

Author(s):

Gustavo Crembil ◽

Paula Gaetano Adi

Keyword(s):

Artificial Life ◽

Life Forms ◽

Peruvian Amazon ◽

Hybrid Nature ◽

Alternative Approach

With a cultural and material “cannibalistic” approach, the authors aim to revise certain technological discourses by introducing TZ’IJK, a “mestizo” robotic artwork developed in the Peruvian Amazon. Far from the utopian visions of Hollywood sci-fi movies populated by highly intelligent, anthropomorphic and responsive machines, TZ’IJK employs a combination of high and low technologies that embody Latin America’s anthropophagic, postcolonial and hybrid nature. Mestizo Robotics proposes an alternative approach to the development of embodied artificial life forms, from both theoretical and technological viewpoints.

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A COMPARATIVE ANATOMICAL CHARACTERISTICS OF THE STEMS OF CLIMBING PLANTS IN ARALAM WILD LIFE SANCTUARY, KANNUR

Kongunadu Research Journal ◽

10.26524/krj124 ◽

2016 ◽

Vol 3 (1) ◽

pp. 37-44

Author(s):

Prasanth K.P ◽

Sekaran S

Keyword(s):

Secondary Growth ◽

Life Forms ◽

Tinospora Cordifolia ◽

Piper Nigrum ◽

Supporting Cells ◽

Anatomical Structures ◽

Climbing Plants ◽

Plant Life Forms ◽

Wide Range ◽

Storage Parenchyma

Climbing plants differ from self-supporting plants, such as shrubs and trees, in a range of characteristics. The most notable is the mechanical properties of the stem Comparison of the differentiated anatomical structures recorded in ten species of the climbing plants. The plants selected for the present study are Ampelocissus latifolia, (Vitaceae), Lygodium flexuosum (Lygodiaceae), Centrosema virginianum (Fabaceae), Tinospora cordifolia, (Menispermaceae), Wattakakka volubilis (Asclepiadaceae) Cyclea peltata (Menispermaceae), Calycopteris floribunda (Combretaceae) Pothos scandens (Araceae) Ipomoea separia (Convolvulaceae) and Piper nigrum (Piperaceae). The stems of climbing plants are characterized by the scarcity of supporting cells (fibers) and an increase in the diameter of the xylem vessels. The study con firms that they show a greater diversity of organization than other plant life forms. This anatomical radiation couldprobably not exist without the achievement of a wide range of secondary growth processes. Many dicotyledons, notably those with a climbing habit, show interesting secondary structure which differs from the more usual type described, therefore, sometimes termed anomalous. The variant secondary growth isparticularly widespread in tropical climbers. It is speculated that variant growth can increase stem flexibility, protect the phloem, increase storage parenchyma, aid in clinging to supports, limit physical disruption of vascular tissues during twisting and bending, and promote wound healing after girdling.

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