Letting the mass depend on the spin-field coupling as $M^2=m^2-(eg/2c^2)F_{\\alpha\\beta}S^{\\alpha\\beta}$, we propose a new set of relativistic planar equations of motion for spinning anyons. Our model can accommodate any gyromagnetic ratio $g$ and provides us with a novel version of the Bargmann-Michel-Telegdi equations in 2+1 dimensions. The system becomes singular when the field takes a critical value, and, for $g\\neq2$, the only allowed motions are those which satisfy the Hall law. For each $g\\neq2,0$ a secondary Hall effect arises also for another critical value of the field. The non-relativistic limit of our equations yields new models which generalize our previous ``exotic\'\' model, associated with the two-fold central extension of the planar Galilei group.