Your search keyword '"Pfeifer, Rolf"' showing total 3 results

1. BOOTSTRAPPING PERCEPTION USING INFORMATION THEORY: CASE STUDIES IN A QUADRUPED ROBOT RUNNING ON DIFFERENT GROUNDS.

Author

SCHMIDT, NICO M., HOFFMANN, MATEJ, NAKAJIMA, KOHEI, and PFEIFER, ROLF

Subjects

STATISTICAL bootstrapping, INFORMATION theory, CASE studies, QUADRUPEDALISM, INFORMATION processing, QUANTITATIVE research, SIGNAL processing

Abstract

Animals and humans engage in an enormous variety of behaviors which are orchestrated through a complex interaction of physical and informational processes: The physical interaction of the bodies with the environment is intimately coupled with informational processes in the animal's brain. A crucial step toward the mastery of all these behaviors seems to be to understand the flows of information in the sensorimotor networks. In this study, we have performed a quantitative analysis in an artificial agent -- a running quadruped robot with multiple sensory modalities -- using tools from information theory (transfer entropy). Starting from very little prior knowledge, through systematic variation of control signals and environment, we show how the agent can discover the structure of its sensorimotor space, identify proprioceptive and exteroceptive sensory modalities, and acquire a primitive body schema. In summary, we show how the analysis of directed information flows in an agent's sensorimotor networks can be used to bootstrap its perception and development. [ABSTRACT FROM AUTHOR]

Published

2013

2. Self-Organization, Embodiment, and Biologically Inspired Robotics.

Author

Pfeifer, Rolf, Lungarella, Max, and Iida, Fumiya

Subjects

*ROBOTICS, *SELF-organizing systems, *INDUSTRIAL robots, *AUTOMATION, *BIOLOGY, *DESIGNERS, *ENGINEERS, *INFORMATION processing, *INFORMATION science

Abstract

Robotics researchers increasingly agree that ideas from biology and self-organization can strongly benefit the design of autonomous robots. Biological organisms have evolved to perform and survive in a world characterized by rapid changes, high uncertainty, indefinite richness, and limited availability of information. Industrial robots, in contrast, operate in highly controlled environments with no or very little uncertainty. Although many challenges remain, concepts from biologically inspired (bio-inspired) robotics will eventually enable researchers to engineer machines for the real world that possess at least some of the desirable properties of biological organisms, such as adaptivity, robustness, versatility, and agility. [ABSTRACT FROM AUTHOR]

Published

2007

3. Information processing via physical soft body.

Author

Nakajima, Kohei, Hauser, Helmut, Li, Tao, and Pfeifer, Rolf

Subjects

MACHINE dynamics, SILICONES, INFORMATION processing, FLEXIBILITY (Mechanics), COMPUTATIONAL mechanics

Abstract

Soft machines have recently gained prominence due to their inherent softness and the resulting safety and resilience in applications. However, these machines also have disadvantages, as they respond with complex body dynamics when stimulated. These dynamics exhibit a variety of properties, including nonlinearity, memory, and potentially infinitely many degrees of freedom, which are often difficult to control. Here, we demonstrate that these seemingly undesirable properties can in fact be assets that can be exploited for real-time computation. Using body dynamics generated from a soft silicone arm, we show that they can be employed to emulate desired nonlinear dynamical systems. First, by using benchmark tasks, we demonstrate that the nonlinearity and memory within the body dynamics can increase the computational performance. Second, we characterize our system's computational capability by comparing its task performance with a standard machine learning technique and identify its range of validity and limitation. Our results suggest that soft bodies are not only impressive in their deformability and flexibility but can also be potentially used as computational resources on top and for free. [ABSTRACT FROM AUTHOR]

Published

2015