Developing Scalable Abilities for Self-Reconfigurable Robots

Slee, Sam

January 2010

<p>The power of modern computer systems is due in no small part to their fantastic ability to adapt to whatever tasks they are charged with. Self-reconfigurable robots seek to provide that flexibility in hardware by building a system out of many individual modules, each with limited functionality, but with the ability to rearrange themselves to modify the shape and structure of the overall robotic system and meet whatever challenges are faced. Various hardware systems have been constructed for reconfigurable robots, and algorithms for them produce a wide variety of modes of locomotion. However, the task of efficiently controlling these complex systems -- possibly with thousands or millions of modules comprising a single robot -- is still not fully solved even after years of prior work on the topic.</p><p> </p><p> In this thesis, we investigate the topic of theoretical control algorithms for lattice-style self-reconfigurable robots. These robots are composed of modules attached to each other in discrete lattice locations and only move by transitioning from one lattice location to another adjacent location. In our work, given the physical limitations of modules in a robot, we show a lower bound for the time to reconfiguration that robot. That is, transition the robot from one connected arrangement of modules to a different connected arrangement. Furthermore, we develop an algorithm with a running time that matches this lower bound both for a specific example reconfiguration problem and for general reconfiguration between any pair of 2D arrangements of modules. Since these algorithms match the demonstrated lower bound, they are optimal given the assumed abilities of the modules in the robot.</p><p> </p><p> In addition to our theoretically optimal reconfiguration algorithms, we also make contributions to the more practical side of of this robotics field with a novel, physically stable control algorithm. The majority of prior theoretical work on control algorithms for self-reconfigurable robots did not consider the effects of gravity upon the robot. The result is that these algorithms often transform a robot into configurations -- arrangements of modules -- which are unstable and would likely break hardware on a real robot with thousands or millions of modules. In this thesis we present an algorithm for locomotion of a self-reconfigurable robot which is always physically stable in the presence of gravity even though we assume limited abilities for the robot's modules to withstand tension or sheer forces. This algorithm is highly scalable, able to be efficiently run on a robot with millions of modules, demonstrates significant speed advantages over prior scalable locomotion algorithms, and is resilient to errors in module actions or message passing. Overall, the contributions of this thesis extend both the theoretical and practical limits of what is possible with control algorithms for self-reconfigurable robots.</p> / Dissertation

Computer Science

Robotics

algorithms

computer science

robotics

self-reconfigurable robots

Dynamic Stability Analysis Of Modular, Self-reconfigurable Robotic Systems

Boke, Tevfik Ali

01 May 2005

In this study, an efficient algorithm has been developed for the dynamic stability analysis of self-reconfigurable, modular robots. Such an algorithm is essential for the motion planning of self-reconfigurable robotic systems. The building block of the algorithm is the determination of the stability of a rigid body in contact with the ground when there exists Coulomb friction between the two bodies. This problem is linearized by approximating the friction cone with a pyramid and then solved, efficiently, using linear programming. The effects of changing the number of faces of the pyramid and the number of contact points are investigated. A novel definition of stability, called percentage stability, is introduced to counteract the adverse effects of the static indeterminacy problem between two contacting bodies. The algorithm developed for the dynamic stability analysis, is illustrated via various case studies using the recently introduced self-reconfigurable robotic system, called I-Cubes.

Aplikace technologie MOLECUBES v robotice / MOLECUBES technology application in robotics

Vacek, Václav

January 2016

The aim of the thesis is to propose and make a robot, which is made of identical modules. These modules are able to connect or disconnect themselves and thanks to this feature new structures of robot can be achieved. This problem is solved by the design proposal of a module, which is capable to rotate in two axis and has connection connectors for other modules. Communication is carried out by Wi-fi connection to the computer and angles required for reconfiguration are calculated by inverse kinematics in Matlab program. On these modules the reconfiguration test was succesfully demonstrated.