382 J.E. MARSDEN, MECHANICS, DYNAMICS, AND SYMMETRYadapted from the animal world where similar things happen, but in fact are more
subtle than what we are discussing here due, in part to the fact that in those
examples there are periodic changes in the phase space as the legs of the animal
come into periodic contact with the ground.
Different gaits correspond to different cyclic input patterns. For example, the
snakeboard possesses at least three primary gait patterns, shown in Figures 3.7-3.9.
The first is the drive gait, shown in Figure 3.7. This figure shows the position
of the snakeboard's center of mass versus time for the case in which the rotor and
wheel axles oscillate with the same frequency (which is called the "drive gait").
This gait closely resembles the motion followed by riders of the snakeboard when
they begin moving from a resting position.
0 .3 ~-~--~-~--~-~--~-~0.20.18 o
;;::
-0.1-0.2-0.30.2s intervals-0.4 '-----'----'----'----'-------'----'------'
0 0.5 1.5 2 2.5 3 3 .5
x(m)Figure 3. 7. Center of mass position for the drive gait.Fig. 3.8 shows a second possible gait, the rotate gait, which has not yet been
discovered by snakeboard riders, but which is easily demonstrated by a robotic
version that has been built. In this case, the rotor oscillates at twice the frequency
of the axles (the "rotate gait," as the robot essentially rotates in place).
Finally, in Figure 3.9 we show the path followed when generating the third
direction of motion (having already generated forward translation and rotation).
This gait, the parallel parking gait, is the most complicated to perform, requiring
that the rotor oscillate three times for every two oscillations of the axles.
We do not yet have a complete geometric understanding of the notion of gaits.
In general, the net displacement of the mechanism that arises from periodic inputs
has, as an important ingredient, the geometric phase, or holonomy. The geometric
phase is that part of the motion described by the local form of the mechanical
connection, A. In the case of the snakeboard, the net displacement is a non-trivial
combination of the geometric phase and the dynamic phase. Understanding the
increased complexity of the relationship between geometric and dynamic phases for
this class of systems is the subject of current research. However, it has been found
by direct calculation that different gaits can b e associated with the derivatives of the
connection. When the momentum terms are not present, i. e., when p = 0 (the case
of kinematic constraints), all motions are generated through this mechanism. In the