Many legged robots have boon built with a variety of different abilities, from running
to liopping to climbing stairs. Despite this however, there has been no consistency of
approach to the problem of getting them to walk. Approaches have included breaking
down the walking step into discrete parts and then controlling them separately, using
springs and linkages to achieve a passive walking cycle, and even working out the
necessary movements in simulation and then imposing them on the real robot. All of
these have limitations, although most were successful at the task for which they were
designed. However, all of them fall into one of two categories: either they alter the
dynamics of the robots physically so that the robot, whilst very good at walking, is
not as general purpose as it once was (as with the passive robots), or they control the
physical mechanism of the robot directly to achieve their goals, and this is a difficult
task.
In this thesis a design methodology is described for building controllers for 3D dynam¬
ically stable walking, inspired by the best walkers and runners around — ourselves —
so the controllers produced are based 011 the vertebrate Central Nervous System. This
means that there is a low-level controller which adapts itself to the robot so that, when
switched on, it can be considered to simulate the springs and linkages of the passive
robots to produce a walking robot, and this now active mechanism is then controlled
by a relatively simple higher level controller. This is the best of both worlds — we
have a robot which is inherently capable of walking, and thus is easy to control like
the passive walkers, but also retains the general purpose abilities which makes it so
potentially useful.
This design methodology uses an evolutionary algorithm to generate low-level control¬
lers for a selection of simulated legged robots. The thesis also looks in detail at previous
walking robots and their controllers and shows that some approaches, including staged
evolution and hand-coding designs, may be unnecessary, and indeed inappropriate, at
least for a general purpose controller. The specific algorithm used is evolutionary, using
a simple genetic algorithm to allow adaptation to different robot configurations, and
the controllers evolved are continuous time neural networks. These are chosen because
of their ability to entrain to the movement of the robot, allowing the whole robot and
network to be considered as a single dynamical system, which can then be controlled
by a higher level system.
An extensive program of experiments investigates the types of neural models and net¬
work structures which are best suited to this task, and it is shown that stateless and
simple dynamic neural models are significantly outperformed as controllers by more
complex, biologically plausible ones but that other ideas taken from biological systems,
including network connectivities, are not generally as useful and reasons for this are
examined.
The thesis then shows that this system, although only developed 011 a single robot,
is capable of automatically generating controllers for a wide selection of different test
designs. Finally it shows that high level controllers, at least to control steering and
speed, can be easily built 011 top of this now active walking mechanism.
