Legged robot locomotion is hindered by a mismatch between applications where
legs can outperform wheels or treads, most of which feature deformable
substrates, and existing tools for planning and control, most of which assume
flat, rigid substrates. In this study we focus on the ramifications of plastic
terrain deformation on the hop-to-hop energy dynamics of a spring-legged
monopedal hopping robot animated by a switched-compliance energy injection
controller. From this deliberately simple robot-terrain model, we derive a
hop-to-hop energy return map, and we use physical experiments and simulations
to validate the hop-to-hop energy map for a real robot hopping on a real
deformable substrate. The dynamical properties (fixed points, eigenvalues,
basins of attraction) of this map provide insights into efficient, responsive,
and robust locomotion on deformable terrain. Specifically, we identify
constant-fixed-point surfaces in a controller parameter space that suggest it
is possible to tune control parameters for efficiency or responsiveness while
targeting a desired gait energy level. We also identify conditions under which
fixed points of the energy map are globally stable, and we further characterize
the basins of attraction of fixed points when these conditions are not
satisfied. We conclude by discussing the implications of this hop-to-hop energy
map for planning, control, and estimation for efficient, agile, and robust
legged locomotion on deformable terrain.Comment: 17 pages, 13 figures, submitted to IEEE Transactions on Robotic