Stability of inverted pendulum reveals transition between predictive control and impedance control in grip force modulation.

During object manipulation, our sensorimotor sys-tem needs to represent the objects dynamics in order to better control it. This is especially important in the case of grip force control where small forces can cause the object to slip from our fingers, and excessive forces can cause fatigue or even damage the object. While the tradeoff between these two constraints is clear for stable objects, such as lifting a soda can, it is less clear how the sensorimotor system adjusts the grip force for unstable objects. For this purpose, we measured the change in the grip force of individual human participants while they stabilize five different lengths of an inverted pendulum. These lengths set different dynamics of the pendulum, ranging in their degree of controllability. We observed two main states during such manipulation, a marginally stable state of the pendulum and a stabilization state in which participants acted to stabilize the system. While during the stabilization state participants increased their applied grip force, for the stable state we observed a mixed behaviour. For small and less controllable pendulums, grip force increased while for larger pendulums, participants could modulate the the grip force according to the anticipated load forces. Based on these results, we suggest that the pendulum dynamics change the control strategy between predictive control and impedance control.