Timepiece regulating mechanism with magnetically synchronized rotating arms

What is claimed is: 1. A timepiece regulating mechanism comprising a plate and, mounted to move at least in a pivoting motion with respect to said plate, an escape wheel set that pivots about an axis of escapement and is subjected to a drive torque, and at least a first resonator comprising a first rigid structure connected to said plate by first elastic return means, said first rigid structure carrying at least one inertia arm including a first inertia arm arranged to cooperate with said escape wheel set via magnetically and/or electrically charged tracks comprised in both said at least one first inertia arm and said escape wheel set, to form a synchronizing device between said escape wheel set and said at least one first resonator, wherein said synchronizing device is protected from loss of synchronization in the event of an accidental increase in torque by a mechanical anti-desynchronization mechanism comprising mechanical escapement stops carried by said escape wheel set, and at least one mechanical inertia arm stop, carried by said at least one first inertia arm, and together arranged to maintain stopped in abutment in the event of an accidental torque increase, wherein said at least one first inertia arm pivots about a first virtual pivot axis, and wherein said mechanical inertia arm stops comprised in said inertia arm each extend, in a direction substantially tangent to the pivoting oscillating travel of said inertia arm about said first virtual axis, and wherein said first virtual axis is located at the intersection in projection onto the plane of said plate of flexible strips comprised in said first elastic return means. 2. The regulating mechanism according to claim 1 , wherein said first virtual axis is located at the rest position of a single flexible strip which forms said first elastic return means. 3. The regulating mechanism according to claim 1 , wherein said magnetically and/or electrically charged track comprised in said at least one first inertia arm comprises at least a first inertia arm pole piece and a second inertia arm pole piece, which extend on either side of a radial line originating from said first virtual axis and on either side of a common perpendicular to said radial line. 4. The regulating mechanism according to claim 3 , wherein at least one said magnetically and/or electrically charged track comprised in said escape wheel set comprises alternate escapement pole pieces and mechanical escapement stops at the same pitch angle with respect to said axis of escapement. 5. The regulating mechanism according to claim 3 , wherein the total dimensions, on said radial line, of a group formed by a consecutive said first inertia arm pole piece and said second inertia arm pole piece, on said radial line, is substantially equal to a linear pitch which is the projection onto said radial line of said pitch angle, and wherein the distance, on said radial line, between said mechanical inertia arm stops corresponding to said group, is substantially equal to half said linear pitch. 6. The regulating mechanism according to claim 1 , wherein said first rigid structure also carries at least one second inertia arm comprised in a second resonator, said second inertia arm pivoting about a second virtual axis and, like said first inertia arm, arranged to cooperate with said escape wheel set via magnetically and/or electrically charged tracks comprised in both said at least one second inertia arm and said escape wheel set, to form a synchronizing device between said first resonator and said second resonator forming a tuning fork. 7. The regulating mechanism according to claim 6 , wherein said mechanical anti-desynchronization mechanism comprises at least one second mechanical inertia arm stop carried by said second inertia arm. 8. The regulating mechanism according to claim 6 , wherein said first inertia arm and said second inertia arm each include a fastening for at least one flexible strip, said flexible strips being attached at the other end thereof to said first rigid structure formed by the same connecting piece, comprising a bending area and secured to said plate in an end restraint. 9. The regulating mechanism according to claim 6 , wherein said first inertia arm and said second inertia arm are arranged to vibrate in phase opposition to each other. 10. The regulating mechanism according to claim 6 , wherein said first inertia arm and said second inertia arm are arranged on either side of said escape wheel set, and each include at least one pair formed of an inertia arm pole piece, and a said mechanical inertia arm stop, arranged to cooperate alternately with said track of said escape wheel set. 11. The regulating mechanism according to claim 10 , wherein at least one said magnetically and/or electrically charged track comprised in said escape wheel set comprises alternate escapement pole pieces and mechanical escapement stops at the same pitch angle, and, wherein, in each pair, the angular distance, in projection onto the same plane perpendicular to said axis of escapement, between said inertia arm pole piece and said mechanical inertia arm stop, is equal to half of said pitch angle. 12. The regulating mechanism according to claim 8 , wherein said first inertia arm and said second inertia arm and said flexible strips, extend in directions substantially parallel to each other, and orthogonal to that of said connecting piece. 13. The regulating mechanism according to claim 1 , wherein each said inertia arm is arranged to cooperate continuously with said escape wheel set, with no periodic stopping of said escape wheel set. 14. The regulating mechanism according to claim 1 , wherein said regulating mechanism forms a pin-wheel escapement mechanism of the Lepaute type, wherein said escape wheel set comprises a half-pin forming a said mechanical escapement stop in proximity to each escapement pole piece comprised in said escape wheel set, and wherein said at least one first inertia arm comprises a said mechanical inertia arm stop, which is the inner surface of a first arm of a compass, and another mechanical inertia arm stop corresponding to the next step which is the outer surface of a second arm of a compass, said inner surface of said first compass arm and said outer surface of said second compass arm being separated by a space of greater width than the radius of said half-pin. 15. The regulating mechanism according to claim 1 , wherein said mechanical stop system is coplanar and comprises at least one finger arranged to cooperate radially with a toothed wheel. 16. The regulating mechanism according to claim 1 , wherein the angular amplitude of each said inertia arm is less than 20°. 17. The regulating mechanism according to claim 8 , wherein at least one of said inertia arms of said tuning fork carries two magnetic pallet stones. 18. The regulating mechanism according to claim 8 , wherein said two inertia arms of said tuning fork each carry at least one magnetic pallet stone. 19. The regulating mechanism according to claim 8 , wherein at least one of said inertia arms of said tuning fork carries two mechanical anti-desynchronization pallet stones. 20. The regulating mechanism according to claim 8 , wherein said two inertia arms of said tuning fork each carry at least one mechanical anti-desynchronization pallet stone. 21. The regulating mechanism according to claim 6 , wherein said regulating mechanism comprises at least two said rotating inertia arms whose phase difference with respect to each other is controlle