Simulation and investigation of embodied autonomous robots driven by homeokinetic control

Pies, Robert

26 October 2017

The thesis is concerned with modeling and simulation of autonomous robots in order to investigate emergent behavior of situated agents interacting with their environment. First, models are proposed to capture the essentials of real-world physics for simple objects and their interaction within the world. These models are then embedded into a coherent framework (DEVS) to allow their discrete-event driven execution on a computer. In the remaining part, the notion of homeokinesis is discussed in detail and proves to provide a sound framework for emergence of behavior. Experiments are conducted at this stage, which utilize the simulator developed in the first part. Resulting emergent behavior is presented and investigated in detail. Finally an encountered limitation in the orginal formulation of homeokinetic control is remedied by application of recurrent neural networks.

info:eu-repo/classification/ddc/000

ddc:000

Self-organisation of internal models in autonomous robots

Smith Bize, Simon Cristobal

January 2016

Internal Models (IMs) play a significant role in autonomous robotics. They are mechanisms able to represent the input-output characteristics of the sensorimotor loop. In developmental robotics, open-ended learning of skills and knowledge serves the purpose of reaction to unexpected inputs, to explore the environment and to acquire new behaviours. The development of the robot includes self-exploration of the state-action space and learning of the environmental dynamics. In this dissertation, we explore the properties and benefits of the self-organisation of robot behaviour based on the homeokinetic learning paradigm. A homeokinetic robot explores the environment in a coherent way without prior knowledge of its configuration or the environment itself. First, we propose a novel approach to self-organisation of behaviour by artificial curiosity in the sensorimotor loop. Second, we study how different forward models settings alter the behaviour of both exploratory and goal-oriented robots. Diverse complexity, size and learning rules are compared to assess the importance in the robot’s exploratory behaviour. We define the self-organised behaviour performance in terms of simultaneous environment coverage and best prediction of future sensori inputs. Among the findings, we have encountered that models with a fast response and a minimisation of the prediction error by local gradients achieve the best performance. Third, we study how self-organisation of behaviour can be exploited to learn IMs for goal-oriented tasks. An IM acquires coherent self-organised behaviours that are then used to achieve high-level goals by reinforcement learning (RL). Our results demonstrate that learning of an inverse model in this context yields faster reward maximisation and a higher final reward. We show that an initial exploration of the environment in a goal-less yet coherent way improves learning. In the same context, we analyse the self-organisation of central pattern generators (CPG) by reward maximisation. Our results show that CPGs can learn favourable reward behaviour on high-dimensional robots using the self-organised interaction between degrees of freedom. Finally, we examine an on-line dual control architecture where we combine an Actor-Critic RL and the homeokinetic controller. With this configuration, the probing signal is generated by the exertion of the embodied robot experience with the environment. This set-up solves the problem of designing task-dependant probing signals by the emergence of intrinsically motivated comprehensible behaviour. Faster improvement of the reward signal compared to classic RL is achievable with this configuration.

629.8

Goal-Oriented Control of Self-Organizing Behavior in Autonomous Robots / Zielgerichtete Steuerung von selbstorganisiertem Verhalten in autonomen Robotern

Martius, Georg

07 September 2009

No description available.

530 Physik

Mathematics and Computer Science

machinelles Lernen

selbstlernende Roboter

Selbstorganisation

Homöokinesis

autonome Roboter

machine learning

developmental robotics

guided self-organization

homeokinesis

autonomous robots

30.20

Self-Organizing Control for Autonomous Robots / A Dynamical Systems Approach Based on the Principle of Homeokinesis / Selbstorganisierende Steuerung für Autonomer Roboter / Ein Dynamischer Systeme-Ansatz basierend auf dem Prinzip der Homeokinese

Hesse, Frank

19 January 2009

No description available.

530 Physik

Mathematics and Computer Science

Dynamische Systeme

Autonome Roboter

Homeokinese

Selbstorganisation

Motorisches Lernen

Adaptive Steuerung

Verhaltensbasierte Robotik

Prothesensteuerung

Dynamical Systems

Autonomous Robots

Homeokinesis

Self-Organization

Motor Learning

Adaptive Control

Behaviour-Based Robotics

Prostheses Control

30.20