Tire tread for a farm tractor

The invention claimed is: 1. A tire for a vehicle for agricultural use, comprising: a tread comprising a plurality of bars, at least one of said plurality of bars extending radially outwards from a base surface of the tread over a bar height (H), axially towards an inside from an axial end of the tread and circumferentially, in one rotational direction of the tire, between a leading face and a trailing face, at least one of the plurality of bars comprising, in an axial plane (P xy ) parallel to an axis of rotation of the tire, a leading profile, an intersection of the leading face and of the axial plane (P xy ), and a trailing profile, the intersection of the trailing face and of the axial plane (P xy ), wherein an angle (A) of a straight line (T) tangential to the leading profile at a point (M) on the leading profile, with respect to an equatorial plane (P) of the tire passing through a middle of the tread, increases continuously from an axially outermost point (E) of the leading profile to a point of inflection (I) of the leading profile, when an axial distance (L) between the point (M) of the leading profile and the axially outermost point (E) of the leading profile increases, in that the angle (A) reaches a maximum value (A m ) at the point of inflection (I) of the leading profile, and in that a radius of curvature (R), at any point on the leading profile positioned axially between the axially outermost point (E) and the point of inflection (I), is at least equal to 0.4 times the bar height (H). 2. A tire according to claim 1 , wherein an axial distance (L1) between the point of inflection (I) of the leading profile and the equatorial plane (P) of the tire is at least equal to 0.8 times an axial distance (L2) between the axially outermost point (E) of the leading profile and the equatorial plane (P) of the tire. 3. A tire according to claim 1 , wherein an axial distance (L 1 ) between the point of inflection (I) of the leading profile and the equatorial plane (P) of the tire is at most equal to 0.93 times the axial distance (L 2 ) between the axially outermost point (E) of the leading profile and the equatorial plane (P) of the tire. 4. A tire according to claim 1 , wherein a circumferential distance (D1) between the axially outermost point (E) of the leading profile and the trailing profile is at most equal to 0.5 times a distance (D2) between the point of inflection (I) of the leading profile and the trailing profile, measured perpendicular to the trailing profile. 5. A tire according to claim 1 , wherein the angle (A) of the straight line (T) tangential to the leading profile at the axially outermost point (E) of the leading profile, with respect to the equatorial plane (P) of the tire, is at most equal to 5°. 6. A tire according to claim 1 , wherein the angle (A) of the straight line (T) tangential to the leading profile at the point of inflection (I) of the leading profile, with respect to the equatorial plane (P) of the tire, is at least equal to 40°. 7. A tire according to claim 1 , wherein the angle (A) of the straight line (T) tangential to the leading profile at the point of inflection (I) of the leading profile, with respect to the equatorial plane (P) of the tire, is at most equal to 75°. 8. A tire according to claim 1 , wherein the leading face is connected to the base surface by a connection that is continuous and tangential to the base surface. 9. A tire according to claim 1 , wherein the plurality of bars is made up of a first and of a second row of bars which are arranged in a chevron pattern with respect to the equatorial plane (P) of the tire.