Isochronous pivot for timepiece resonators

What is claimed is: 1. An isochronous pivot for a timepiece resonator, with a flexure bearing, comprising: a first pair including two flexible strips each joining a first point of attachment of a first element to a second point of attachment of a second element, said first attachment points defining, with said respective second attachment points, two main strip directions, said first element and said second element each being stiffer than each of said flexible strips, and each able to form a movable inertial element inside said resonator, and said two main strip directions defining a theoretical pivot axis at their intersection when said two flexible strips are coplanar, or symmetrical in projection onto a reference plane parallel to said two flexible strips when said two flexible strips extend on two levels parallel to said reference plane but are not coplanar, each said flexible strip having a free length between its two attachment points, and having an axial distance between said theoretical pivot axis and whichever of its two attachment points is farthest therefrom, wherein, for each said flexible strip, the main attachment point ratio between said axial distance and said free length is greater than one, wherein said two main strip directions define with said theoretical pivot axis a first apex angle whose value in degrees satisfies the relation f 1 (D/L)<α<f 2 (D/L), with f 1 (X)=108+67/(10X−6), and f 2 (X)=113+67/(10X−6), with X=D/L, wherein said two main strip directions define with said theoretical pivot axis a first apex angle comprised between 115° and 130° inclusive, wherein said pivot includes a second pair including two other flexible strips each joining a primary attachment point of said first element or a secondary attachment point of said second element, to a third attachment point comprised in a third element arranged to be fixedly secured to a fixed structure of said resonator, wherein said primary attachment points of said first element or secondary attachment points of said second element and said tertiary attachment points define two secondary strip directions together forming a second apex angle at a secondary axis defined by the intersection, in plane or in projection, of said secondary strip directions, said second apex angle being comprised between 115° and 130° inclusive, and whose value in degrees satisfies the relation f 1 (D/L)<β<f 2 (D/L), with f 1 (X)=108+67/(10X−6), and f 2 (X)=113+67/(10X−6), with X=D/L, wherein a median function fm(X)=110.5+67/(10X−6) defines an intermediate ratio between said first lower function f 1 (X)=108+67/(10X−6), and said first upper function f 2 (X)=113+67/(10X−6), with X=D/L, wherein said first apex angle and said second apex angle are positioned between said first lower function f 1 and said first upper function f 2 , on either side of said median function fm, wherein said first element or said second element comprises a concave surface arranged to surround at a distance, over at least 180°, a convex surface comprised in said second element or said first element respectively, with, in a rest position of said pivot, a clearance which, at every point, is greater than or equal to a safety clearance between said convex surface and said concave surface, and wherein said theoretical pivot axis is geometrically located in an eye, the eye being an opening in said first element or said second element. 2. The pivot according to claim 1 , wherein said first element or said second element is an inertial element, and wherein said theoretical pivot axis is geometrically located in said eye comprised in said inertial element. 3. An isochronous pivot for a timepiece resonator, with a flexure bearing, comprising: a first pair including two flexible strips each joining a first point of attachment of a first element to a second point of attachment of a second element, said first attachment points defining, with said respective second attachment points, two main strip directions, said first element and said second element each being stiffer than each of said flexible strips, and each able to form a movable inertial element inside said resonator, and said two main strip directions defining a theoretical pivot axis at their intersection when said two flexible strips are coplanar, or symmetrical in projection onto a reference plane parallel to said two flexible strips when said two flexible strips extend on two levels parallel to said reference plane but are not coplanar, each said flexible strip having a free length between its two attachment points, and having an axial distance between said theoretical pivot axis and whichever of its two attachment points is farthest therefrom, wherein, for each said flexible strip, the main attachment point ratio between said axial distance and said free length is greater than one, wherein said two main strip directions define with said theoretical pivot axis a first apex angle whose value in degrees satisfies the relation f 1 (D/L)<α<f 2 (D/L), with f 1 (X)=108+67/(10X−6), and f 2 (X)=113+67/(10X−6), with X=D/L, wherein said two main strip directions define with said theoretical pivot axis a first apex angle comprised between 115° and 130° inclusive, wherein said pivot includes a second pair including two other flexible strips each joining a primary attachment point of said first element to a third attachment point comprised in a third element arranged to be fixedly secured to a fixed structure of said resonator, wherein said primary attachment points of said first element or secondary attachment points of said second element and said tertiary attachment points define two secondary strip directions together forming a second apex angle at a secondary axis defined by the intersection, in plane or in projection, of said secondary strip directions, said second apex angle being comprised between 115° and 130° inclusive, and whose value in degrees satisfies the relation f 1 (D/L)<β<f 2 (D/L), with f 1 (X)=108+67/(10X−6), and f 2 (X)=113+67/(10X−6), with X=D/L, wherein a median function fm(X)=110.5+67/(10X−6) defines an intermediate ratio between said first lower function f 1 (X)=108+67/(10X−6), and said first upper function f 2 (X)=113+67/(10X−6), with X=D/L, wherein said first apex angle and said second apex angle are positioned between said first lower function f 1 and said first upper function f 2 , on either side of said median function fm, wherein said first element or said second element is an inertial element, and wherein said third element comprises an internal surface arranged to surround at a distance a convex surface comprised in said inertial element, with, in a rest position of said pivot, a clearance which, at every point, is greater than or equal to a safety clearance between said convex surface and said internal surface, wherein said theoretical pivot axis is geometrically located in an eye, the eye being an opening in said first element or said second element, and wherein said first element completely surrounds said second element and said third element. 4. The pivot according to claim 1 , wherein said theoretical pivot axis and secondary axis are coincident. 5. The pivot according to claim 1 , wherein said two flexible strips of the first pair are either identical in symmetry with respect to a plane of symmetry passing through said theoretical pivot axis when said two flexible strips are coplanar, or identical in symmetry in projection onto a reference plane parallel to said two flexible strips when said two flexible strips extend on two levels parallel to said reference plane but are not coplanar, with respect to a plane of symmetry passing through said theoretical pivot axis. 6. The pivot according to claim 5 , wherein said two flexible strips of each of the first pair and the second pair are eithe