Mechanism for regulating the rate of a timepiece oscillator

What is claimed is: 1. A microsystem for setting the rate of a timepiece oscillator, comprising at least one wheel/inertia block arranged to pivot with respect to a base plate comprised in said microsystem, said wheel/inertia block comprising an off-centre unbalance and comprising a toothing, said microsystem comprising at least one actuator arranged to drive at least a first active click formed by a click arranged to drive a control wheel, a lever, or a click wheel, said active click being arranged to drive said toothing, and said microsystem comprising at least one means for stopping said toothing in position, wherein at least one said actuator is an optically controlled thermomechanical actuator arranged to convert a flow of light energy into a displacement of a control member comprised in said thermomechanical actuator, which control member carries a said first active click or directly controls a movement of a first said active click. 2. The microsystem according to claim 1 , wherein said at least one means for stopping said toothing in position is a second click arranged to be returned towards said toothing by an elastic return means comprised therein. 3. The microsystem according to claim 1 , wherein said at least one first active click is a click mounted tangentially to said toothing and comprises at least one tooth returned towards said toothing by an elastic return means comprised therein. 4. The microsystem according to claim 1 , wherein said thermomechanical actuator comprises, substantially in a first longitudinal direction a longitudinal line composed of alternating stiff weights and flexible neck portions maintained between anchor elements on said base plate, and in that a central area of said thermomechanical actuator comprising at least said neck portions is arranged to be superposed on a heating area where said central area can receive an application of light energy capable of compressing said longitudinal line between said anchor elements and of causing at least one of said neck portions to bend. 5. The microsystem according to claim 4 , wherein at least one of said flexible neck portions is offset, in a transverse direction orthogonal to said longitudinal direction, by a transverse offset with respect to said other neck portions, converting the bending motion of at least one of said neck portions into a plane rotational motion, parallel to said base plate, of at least one intermediate weight not directly connected to one of said anchor elements. 6. The microsystem according to claim 5 , wherein said intermediate weight that is drivable in rotation, carries a stick extending substantially in said transverse direction and comprising a distal end forming said control member. 7. The microsystem according to claim 6 , wherein the rotational travel of said stick is limited by stick stops which surround said lever. 8. The microsystem according to claim 6 , wherein said thermomechanical actuator carries, substantially in the extension of said stick and on the opposite side with respect to a line defined by said anchor elements, at least one counterweight intended to prevent motion of said stick in the event of shocks. 9. The microsystem according to claim 8 , wherein said central area comprises the inner end of said counterweight which is separated from the distal end thereof by a cavity arranged to insulate said distal end from a hot area when said central area is subjected to a flow of light energy. 10. The microsystem according to claim 6 , wherein said central area comprises the inner end of said stick which is separated from said distal end by a cavity arranged to insulate said distal end from a hot area when said central area is subjected to a flow of light energy. 11. The microsystem according to claim 4 , wherein said central area comprises the inner ends of two arms directly attached via the outer ends thereof to said anchor elements wherein said inner ends are separated by recesses arranged to insulate said anchor elements from a hot area when said central area is subjected to a flow of light energy. 12. The microsystem according to claim 4 , wherein said base plate comprises at least one cavity arranged to insulate a hot area from said base plate and from said at least one wheel/inertia block when said central area is subjected to a flow of light energy. 13. The microsystem according to claim 1 , wherein said base plate and said thermomechanical actuator are made of the same material to avoid being thrown out of adjustment when said base plate and said thermomechanical actuator are subjected, inside a watch, to the same temperature variations. 14. The microsystem according to claim 1 , wherein at least one said wheel/inertia block is mounted to pivot about a fixed axis affixed to said base plate or incorporated in said base plate. 15. The microsystem according to claim 1 , wherein at least one said wheel/inertia block is incorporated in said base plate with respect to which said wheel/inertia block pivots carried by monolithic articulated structures or flexible bearings. 16. The microsystem according to claim 1 , wherein said microsystem comprises a first level formed by said base plate and a second level comprising at least one said wheel/inertia block, at least one said actuator, at least one said first active click, and at least one said means for stopping said toothing in position. 17. The microsystem according to claim 16 , wherein said first level is a handle layer and in that said second level is a device layer. 18. The microsystem according to claim 1 , wherein said microsystem is made in one-piece and comprises cavities underneath the movable members comprised therein. 19. The microsystem according to claim 18 , wherein said microsystem is made entirely of silicon and/or silicon oxide. 20. A timepiece oscillator comprising at least one microsystem according to claim 1 , wherein said base plate of said at least one microsystem is attached to a component of said oscillator to adjust the inertia thereof in order to correct the rate of said oscillator. 21. The oscillator according to claim 20 , wherein said oscillator comprises an equipped balance formed by a bare balance connected to an elastic return means or subjected to at least one field of repulsion and/or of attraction, said bare balance carrying at least one said microsystem or being in one-piece with at least one said microsystem. 22. A timepiece movement comprising at least one oscillator according to claim 20 , wherein said movement comprises at least one crystal transparent to predetermined wavelength ranges, and allowing the passage of a light ray for setting a said microsystem. 23. A watch comprising at least one microsystem according to claim 1 , wherein said watch comprises at least one crystal transparent to predetermined wavelength ranges, and allowing the passage of a light ray for setting at least one said microsystem. 24. The watch according to claim 23 , wherein said watch comprises at least one said microsystem wherein said control member is arranged to control a mechanical component for setting a time-related function of said watch when said microsystem is subjected to suitable light radiation. 25. The watch according to claim 23 , wherein the only means for setting time-related functions comprised in the watch are formed by at least one said microsystem whose control member is arranged to control a mechanical component for setting a timere