Method for producing a customized progressive ophthalmic lens

The invention claimed is: 1. A method for producing a customized progressive ophthalmic lens intended for a wearer having a prescription for a wearer's eye corresponding to said lens, the method comprising the following: providing an initial progressive ophthalmic lens design having a meridian line; providing binocular convergence data for the wearer; the providing of the binocular convergence data comprising the following: providing a visual stimulus in a sagittal plane of the wearer; moving the visual stimulus within the sagittal plane between a predetermined maximum distance and a predetermined minimum distance; determining, for each of a plurality of visual stimulus distances between the predetermined maximum and minimum distances, an azimuth angle existing for an ocular axis of the wearer's eye when the wearer is looking at the visual stimulus located at the visual stimulus distance; and calculating a convergence distance for each azimuth angle determined at the determining of the plurality of the azimuth angles, modifying the initial design so that the meridian line is laterally shifted in position with respect to the initial design, for matching the convergence data provided when calculating each convergence distance, for said prescription; and using the modified design as resulting from modifying the initial design to manufacture the customized lens, wherein an assignment of each convergence distance to the corresponding visual stimulus distance forms the convergence data used in the modifying of initial design. 2. The method according to claim 1 , wherein the meridian line is laterally shifted in the modifying of initial design so as to intersect the ocular axis of the wearer's eye when the wearer is looking at the visual stimulus located at said visual stimulus distance, and the modified design for said visual stimulus distance produces a same mean refractive power as the mean refractive power produced at a gaze direction intersecting the meridian line, by the initial design for said visual stimulus distance. 3. The method according to claim 1 , wherein the determining of the plurality of visual stimulus distances is carried out with the wearer being devoid of ophthalmic lens, and the modifying of initial design includes taking into account a gaze direction deviation produced by the progressive ophthalmic lens when matching the prescription. 4. The method according to claim 1 , wherein the moving of said visual stimulus comprises varying a height of the visual stimulus in the sagittal plane as a function of at least said visual stimulus distance. 5. The method according to claim 1 , wherein the predetermined maximum distance is substantially equal to 2 m and the predetermined minimum distance is substantially equal to 20 cm. 6. The method according to claim 1 , wherein the moving of said visual stimulus is performed at a constant speed during the moving of the visual stimulus within the sagittal plane. 7. The method according to claim 1 , wherein the moving of said visual stimulus is performed at a speed comprised between 0.05 m/s and 0.3 m/s. 8. The method according to claim 1 , wherein the modifying of initial design comprises implementing an optimization process for shifting the meridian line laterally from the initial design. 9. The method according to claim 1 , wherein the modifying of initial design comprises the following: for the initial design, obtaining respective distributions for a mean refractive power PPO(α, β) and a module of resulting astigmatism ASR(α, β); from said distributions, and for a plurality of gaze directions intersecting the meridian line as existing before the modifying of initial design, at lowering angles α, obtaining azimuth angles βmer(α); respectively for said gaze directions, determining target azimuth angle values based on the convergence data provided at the providing of binocular convergence data; based on the initial design, forming a target design comprising, for a plurality of gaze directions (α, β), at least one of the following values: a mean refractive power PPOtarget(α, β) such that PPOtarget(α, β)=PPO(α, β−βmer_target(α)+βmer(α)); and a module of resulting astigmatism ASRtarget(α, β) such that ASRtarget(α, β)=ASR(α, β−βmer_target(α)+βmer(α)); and optimizing a test lens design with respect to the target design, and the test lens design as resulting from optimization forming the modified design. 10. The method according to claim 1 , wherein the meridian line of the initial design is determined from a set of gaze directions through a progressive ophthalmic lens which is provided with said initial design, where a module of resulting astigmatism is minimum when varying an azimuth angle β at constant lowering angle α. 11. The method according to claim 1 , wherein the method comprises initially measuring the wearer's break value and comparing the wearer's break value to a predetermined threshold, performing the providing of the initial progressive ophthalmic lens design, the providing of binocular convergence data, and the modifying of the initial design if the wearer's break value is lower than or equal to the predetermined threshold. 12. A method for manufacturing a customized pair of progressive ophthalmic lenses intended for a wearer having a prescription for each eye, wherein the method according to claim 1 is performed for each lens of the pair separately. 13. A customized progressive ophthalmic lens manufactured by the method according to claim 1 .