Manufacturing method for manufacturing a spectacle lens, spectacle lens and lens design method

The invention claimed is: 1. A manufacturing method for manufacturing a spectacle lens, the method comprising: obtaining prescription data descriptive of an ophthalmic prescription of a user in a plus prescription range; providing a lens blank having a convex front surface and a back surface; determining a final cutting surface to be machined on the back surface of the lens blank in a secondary cutting phase; obtaining frame data descriptive of a perimeter of a spectacle frame in which the lens is to be mounted; determining an intermediate cutting surface to be machined on the back surface of the lens blank in a primary cutting phase, wherein the intermediate cutting surface is different from the final cutting surface; wherein the final cutting surface includes: a prescription zone in which the final cutting surface together with the front surface fulfills the ophthalmic prescription of the user, wherein a boundary perimeter of the prescription zone encloses the perimeter of the spectacle frame; and a non-prescription blending zone surrounding the prescription zone in which the final cutting surface together with the front surface provides at least a predetermined minimum thickness of the spectacle lens; wherein the intermediate cutting surface is determined based on the final cutting surface; wherein a maximum curvature of the intermediate cutting surface is smaller than a maximum curvature of the final cutting surface; and wherein a lens thickness provided by the intermediate cutting surface exceeds a lens thickness provided by the final cutting surface at least within the prescription zone; machining the intermediate cutting surface on the back surface of the lens blank in the primary cutting phase; and machining the final cutting surface on the back surface of the lens blank in the secondary cutting phase. 2. A manufacturing method for manufacturing a spectacle lens, the method comprising: obtaining prescription data descriptive of an ophthalmic prescription of a user in a plus prescription range; providing a lens blank having a convex front surface and a back surface; determining a final cutting surface to be machined on the back surface of the lens blank in a secondary cutting phase; obtaining frame data descriptive of a perimeter of a spectacle frame in which the lens is to be mounted; determining an intermediate cutting surface to be machined on the back surface of the lens blank in a primary cutting phase, wherein the intermediate cutting surface is different from the final cutting surface; wherein the final cutting surface includes: a prescription zone in which the final cutting surface together with the front surface fulfills the ophthalmic prescription of the user, wherein a boundary perimeter of the prescription zone encloses the perimeter of the spectacle frame; and a non-prescription blending zone surrounding the prescription zone in which the final cutting surface together with the front surface provides at least a predetermined minimum thickness of the spectacle lens, and wherein the non-prescription blending zone provides a transition from the prescription zone to a remainder of the intermediate cutting surface machined on the back surface; wherein the intermediate cutting surface is determined based on the final cutting surface; wherein a maximum curvature of the intermediate cutting surface is smaller than a maximum curvature of the final cutting surface; and wherein a lens thickness provided by the intermediate cutting surface exceeds a lens thickness provided by the final cutting surface at least within the prescription zone; machining the intermediate cutting surface on the back surface of the lens blank in the primary cutting phase; and machining the final cutting surface on the back surface of the lens blank in the secondary cutting phase. 3. The manufacturing method according to claim 1 , wherein the intermediate cutting surface is a smoothed final cutting surface. 4. The manufacturing method according to claim 1 , wherein—for at least one point of the final cutting surface—a meridian curvature of the intermediate cutting surface correspond to a meridian curvature of the final cutting surface. 5. The manufacturing method according to claim 1 , wherein the intermediate cutting surface is configured to be machined with a primary coarse cutting tool and the final cutting surface is configured to be machined with a secondary fine cutting tool. 6. The manufacturing method according to claim 1 , wherein a surface height difference between the intermediate cutting surface and the final cutting surface to be machined in the prescription zone is within a predetermined thickness range. 7. The manufacturing method according to claim 1 , wherein determining the final or intermediate cutting surface comprises incorporating a prism into the final or intermediate cutting surface. 8. The manufacturing method according to claim 1 , wherein the final cutting surface is determined under the boundary condition of minimizing a maximum thickness of the spectacle lens in the prescription zone while achieving a predetermined thickness range along the boundary perimeter of the prescription zone. 9. The manufacturing method according to claim 1 , wherein the final cutting surface and the intermediate cutting surface intersect outside of the prescription zone along an intersection curve, and wherein the final cutting surface is machined only inside the intersection curve. 10. The manufacturing method according to claim 1 , wherein the final cutting surface in the non-prescription blending zone is steeper than the intermediate cutting surface in at least one point of the non-prescription blending zone. 11. The manufacturing method according to claim 1 , wherein the boundary perimeter comprising the frame perimeter corresponds to a smoothed frame perimeter. 12. The manufacturing method according to claim 1 , further comprising centering the prescription zone on the lens blank. 13. The manufacturing method according to claim 1 , further comprising machining the final cutting surface in a turning process, wherein the final cutting surface is determined under the condition of minimizing variations in sagittal curvature within the non-prescription blending zone. 14. A computer implemented method for designing a spectacle lens, the method comprising: obtaining prescription data descriptive of an ophthalmic prescription of a user in the plus prescription range; determining a final cutting surface to be machined on the back surface of a lens blank in a secondary cutting phase; obtaining frame data descriptive of a perimeter of a spectacle frame in which the lens is to be mounted; determining an intermediate cutting surface to be machined on the back surface of the lens blank in a primary cutting phase, wherein the intermediate cutting surface is different from the final cutting surface; wherein the final cutting surface comprises a prescription zone in which the final cutting surface together with the front surface fulfills the ophthalmic prescription of the user, wherein a boundary perimeter of the prescription zone encloses the perimeter of the spectacle frame; and a non-prescription blending zone surrounding the prescription zone in which the final cutting surface together with the front surface provides at least a predetermined minimum thickness of the spectacle lens; wherein the intermediate cutting surface is determined based on the final cutting surface, wherein a maximum curvature of the intermediate cutting surface is smaller than a maximum curvature of the final cutting surface, and wherein a lens thickn