Timepiece oscillator with flexure bearings having a long angular stroke

What is claimed is: 1. A mechanical timepiece oscillator comprising: a first rigid support element; a solid inertial element; and at least two first flexible strips between said first rigid support element and said solid inertial element, the at least two first flexible strips support said solid inertial element and are arranged to return the solid inertial element to a rest position, wherein said solid inertial element is arranged to oscillate anallarly in an oscillation plane about said rest position, wherein said two first flexible strips do not touch each other and their projections onto said oscillation plane intersect, in the rest position, at a crossing point, through which passes the axis of rotation of said solid inertial element perpendicularly to said oscillation plane, and wherein embedding points of said first flexible strips in said first rigid support element and said solid inertial element define two strip directions, which are parallel to said oscillation plane and which form between them, in the rest position, in projection onto said oscillation plane, a vertex angle, the position of said crossing point being defined by a ratio X=D/L, where D is a distance between the projection onto said oscillation plane of one of the embedding points of said first strips in said first rigid support element and said crossing point, and where L is a total length of the projection, onto said oscillation plane, of said strip, where a value of said ratio D/L is comprised between 0 and 1, wherein said vertex angle (a) is less than or equal to 60 0 , and wherein, for each said first flexible strip, the embedding point ratio is comprised between 0.15 and 0.85 inclusive. 2. The mechanical oscillator according to claim 1 , wherein the centre of mass of said oscillator in its rest position is separated from said crossing point by an offset which is comprised between 10% and 20% of said total length of the projection, onto said oscillation plane, of said strip. 3. The mechanical oscillator according to claim 2 , wherein said offset is comprised between 12% and 18% of said total length of the projection, onto said oscillation plane, of said strip. 4. The mechanical oscillator according to claim 1 , wherein said first strips and their embedding points define together a pivot which, in projection onto said oscillation plane, is symmetrical with respect to an axis of symmetry passing through said crossing point. 5. The mechanical oscillator according to claim 4 , wherein, in the rest position, in projection onto said oscillation plane, the centre of mass of said solid inertial element is located on said axis of symmetry of said pivot. 6. The mechanical oscillator according to claim 5 , wherein, in projection onto said oscillation plane, the centre of mass of said solid inertial element is at a non-zero distance from said crossing point corresponding to the axis of rotation of said solid inertial element, which non-zero distance is comprised between 0.1 times and 0.2 times the total length of the projection, onto said oscillation plane, of said strip. 7. The mechanical oscillator according to claim 1 , wherein said first strips are straight strips. 8. The mechanical oscillator according to claim 1 , wherein said embedding point ratio is comprised between 0.15 and 0.49 inclusive, or between 0.51 and 0.85 inclusive. 9. The mechanical oscillator according to claim 8 , wherein said vertex angle (a) is less than or equal to 50°, and wherein said embedding ratio is comprised between 0.25 and 0.75 inclusive. 10. The mechanical oscillator according to claim 9 , wherein said vertex angle is less than or equal to 40 0 , and wherein said embedding point ratio is comprised between 0.30 and 0.70 inclusive. 11. The mechanical oscillator according to claim 10 , wherein said vertex angle is less than or equal to 35 0 , and wherein said embedding point ratio is comprised between 0.40 and 0.60 inclusive. 12. The mechanical oscillator according to claim 1 , wherein said vertex angle is less than or equal to 30′. 13. The mechanical oscillator according to claim 1 , wherein said apex angle and said ratio X=D/L satisfy the relation h 1 (D/L)<α<h 2 (D/L), where, for 0.2< X< 0.5: h 1( X )=116−473*( X+ 0.05)+3962*( X+ 0,05) 3 −6000*( X+ 0.05) 4 , h 2( X )=128−473*( X− 0.05)+3962*( X− 0.05) 3 −6000*( X− 0.05) 4 , for 0.5< X< 0.8: h 1( X )=116−473*(1.05− X )+3962*(1.05− X ) 3 −6000*(1.05− X ) 4 , h 2( X )=128−473*(0.95− X )+3962*(0.95− X ) 3 −6000*(0.95− X ) 4 . 14. The mechanical oscillator according to claim 1 , wherein said first flexible strips have the same length L and the same distance D. 15. The mechanical oscillator according to claim 14 , wherein, between their embedding points, said first flexible strips are identical. 16. The mechanical oscillator according to claim 1 , wherein said first rigid support element is also directly or indirectly movable with respect to a stationary structure comprised in said oscillator, and is carried by a third rigid element, by means of two second flexible strips arranged in a similar manner to said first flexible strips. 17. The mechanical oscillator according to claim 16 , wherein the projections of said first flexible strips and of said second flexible strips onto said oscillation plane intersect at the same said crossing point. 18. The mechanical oscillator according to claim 16 , wherein said first strips and their embedding points define together a pivot which, in projection onto said oscillation plane, is symmetrical with respect to an axis of symmetry passing through said crossing point, and wherein, in the rest position, in projection onto said oscillation plane, the projections of said first flexible strips and of said second flexible strips onto said oscillation plane intersect at two distinct points both located on said axis of symmetry of said pivot. 19. The mechanical oscillator according to claim 16 , wherein the embedding points of said second flexible strips in said first rigid support element and said third rigid element define two strip directions that are parallel to said oscillation plane and form between them, in projection onto said oscillation plane, the same said vertex angle as said first, flexible strips. 20. The mechanical oscillator according to claim 16 , wherein said second flexible strips are identical to said first flexible strips. 21. The mechanical oscillator according to claim 16 , wherein said first strips and their embedding points define together a pivot which, in projection onto said oscillation plane, is symmetrical with respect to an axis of symmetry passing through said crossing point, and wherein, in the rest position, in projection onto said oscillation plane, the centre of mass of said solid inertial element is located on said axis of symmetry of said pivot. 22. The mechanical oscillator according to claim 17 , wherein said first strips and their embedding points define together a pivot which, in projection onto said oscillation plane, is symmetrical with respect to an axis of symmetry passing through said crossing point, and wherein, in the rest position, in projection onto said oscillation plane, the centre of mass of said solid inertial element is located on said axis of symmetry of said pivot, and wherein, in the rest position, the projections of said first flexible strips and of said second flexible strips onto the oscillation plane intersect at the same crossing point, which also corresponds to the