71 research outputs found
SMA-Based Muscle-Like Actuation in Biologically Inspired Robots: A State of the Art Review
New actuation technology in functional or "smart" materials has opened new horizons in robotics actuation systems. Materials such as piezo-electric fiber composites, electro-active polymers and shape memory alloys (SMA) are being investigated as promising alternatives to standard servomotor technology [52]. This paper focuses on the use of SMAs for building muscle-like actuators. SMAs are extremely cheap, easily available commercially and have the advantage of working at low voltages.
The use of SMA provides a very interesting alternative to the mechanisms used by conventional actuators. SMAs allow to drastically reduce the size, weight and complexity of robotic systems. In fact, their large force-weight ratio, large life cycles, negligible volume, sensing capability and noise-free operation make possible the use of this technology for building a new class of actuation devices. Nonetheless, high power consumption and low bandwidth limit this technology for certain kind of applications. This presents a challenge that must be addressed from both materials and control perspectives in order to overcome these drawbacks. Here, the latter is tackled. It has been demonstrated that suitable control strategies and proper mechanical arrangements can dramatically improve on SMA performance, mostly in terms of actuation speed and limit cycles
Locomoção bípede adaptativa a partir de uma única demonstração usando primitivas de movimento
Doutoramento em Engenharia EletrotécnicaEste trabalho aborda o problema de capacidade de imitação da locomoção
humana através da utilização de trajetórias de baixo nível codificadas com
primitivas de movimento e utilizá-las para depois generalizar para novas
situações, partindo apenas de uma demonstração única. Assim, nesta linha de
pensamento, os principais objetivos deste trabalho são dois: o primeiro é
analisar, extrair e codificar demonstrações efetuadas por um humano, obtidas
por um sistema de captura de movimento de forma a modelar tarefas de
locomoção bípede. Contudo, esta transferência não está limitada à simples
reprodução desses movimentos, requerendo uma evolução das capacidades
para adaptação a novas situações, assim como lidar com perturbações
inesperadas. Assim, o segundo objetivo é o desenvolvimento e avaliação de
uma estrutura de controlo com capacidade de modelação das ações, de tal
forma que a demonstração única apreendida possa ser modificada para o robô
se adaptar a diversas situações, tendo em conta a sua dinâmica e o ambiente
onde está inserido.
A ideia por detrás desta abordagem é resolver o problema da generalização a
partir de uma demonstração única, combinando para isso duas estruturas
básicas. A primeira consiste num sistema gerador de padrões baseado em
primitivas de movimento utilizando sistemas dinâmicos (DS). Esta abordagem
de codificação de movimentos possui propriedades desejáveis que a torna ideal
para geração de trajetórias, tais como a possibilidade de modificar determinados
parâmetros em tempo real, tais como a amplitude ou a frequência do ciclo do
movimento e robustez a pequenas perturbações. A segunda estrutura, que está
embebida na anterior, é composta por um conjunto de osciladores acoplados
em fase que organizam as ações de unidades funcionais de forma coordenada.
Mudanças em determinadas condições, como o instante de contacto ou
impactos com o solo, levam a modelos com múltiplas fases. Assim, em vez de
forçar o movimento do robô a situações pré-determinadas de forma temporal, o
gerador de padrões de movimento proposto explora a transição entre diferentes
fases que surgem da interação do robô com o ambiente, despoletadas por
eventos sensoriais. A abordagem proposta é testada numa estrutura de
simulação dinâmica, sendo que várias experiências são efetuadas para avaliar
os métodos e o desempenho dos mesmos.This work addresses the problem of learning to imitate human locomotion actions
through low-level trajectories encoded with motion primitives and generalizing
them to new situations from a single demonstration. In this line of thought, the
main objectives of this work are twofold: The first is to analyze, extract and
encode human demonstrations taken from motion capture data in order to model
biped locomotion tasks. However, transferring motion skills from humans to
robots is not limited to the simple reproduction, but requires the evaluation of
their ability to adapt to new situations, as well as to deal with unexpected
disturbances. Therefore, the second objective is to develop and evaluate a
control framework for action shaping such that the single-demonstration can be
modulated to varying situations, taking into account the dynamics of the robot
and its environment.
The idea behind the approach is to address the problem of generalization from
a single-demonstration by combining two basic structures. The first structure is
a pattern generator system consisting of movement primitives learned and
modelled by dynamical systems (DS). This encoding approach possesses
desirable properties that make them well-suited for trajectory generation, namely
the possibility to change parameters online such as the amplitude and the
frequency of the limit cycle and the intrinsic robustness against small
perturbations. The second structure, which is embedded in the previous one,
consists of coupled phase oscillators that organize actions into functional
coordinated units. The changing contact conditions plus the associated impacts
with the ground lead to models with multiple phases. Instead of forcing the robot’s
motion into a predefined fixed timing, the proposed pattern generator explores
transition between phases that emerge from the interaction of the robot system
with the environment, triggered by sensor-driven events. The proposed approach
is tested in a dynamics simulation framework and several experiments are
conducted to validate the methods and to assess the performance of a humanoid
robot
Digital control networks for virtual creatures
Robot control systems evolved with genetic algorithms traditionally take the form
of floating-point neural network models. This thesis proposes that digital control systems,
such as quantised neural networks and logical networks, may also be used for
the task of robot control. The inspiration for this is the observation that the dynamics
of discrete networks may contain cyclic attractors which generate rhythmic behaviour,
and that rhythmic behaviour underlies the central pattern generators which drive lowlevel
motor activity in the biological world.
To investigate this a series of experiments were carried out in a simulated physically
realistic 3D world. The performance of evolved controllers was evaluated on two well
known control tasks—pole balancing, and locomotion of evolved morphologies. The
performance of evolved digital controllers was compared to evolved floating-point neural
networks. The results show that the digital implementations are competitive with
floating-point designs on both of the benchmark problems. In addition, the first reported
evolution from scratch of a biped walker is presented, demonstrating that when
all parameters are left open to evolutionary optimisation complex behaviour can result
from simple components
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