System comprising a multifocal diffractive lens component

The invention claimed is: 1. A simultaneously bifocal optical system, the said optical system being defined by a first system focal point and a second system focal point and a pupil, said system comprising: a simultaneously bifocal diffractive lens component having a first focal point, a second focal point and a plurality of diffractive zones, the plurality of diffractive zones including a central zone and a plurality of annular concentric zones surrounding the central zone, the lens component having a first optical power P1 and a second optical power P2 associated with the first focal point and the second focal point respectively, the first focal point and the second focal point respectively corresponding to points of convergence of the most luminous orders of diffraction generated by the lens component for a nominal wavelength, the first system focal point and the second system focal point having a position dependent upon a value of the first optical power P1 and the second optical power P2 of the lens respectively, wherein the central zone has a surface area value configured such that a predetermined optical performance optimization parameter φ is optimized, said optical performance optimization parameter φ being considered in the vicinity of the first and second system focal points and varying as a function of a surface area value of the central zone without modifying the operational function of the diffractive zones, said predetermined optical performance optimization parameter φ being such as the brightness and/or the Modulation Transfer Function in the vicinity of the first and second system focal points, whereby the central zone has a surface area value determined as a function of the pupil of the optical system, of the first optical power P1 and of the second optical power P2, and the surface area of the annular zones surrounding the central zone does not change with the optimization parameter φ while the area of the central zone does change with optimization parameter φ. 2. A system according to claim 1 , wherein each of the plurality of diffractive zones has a spherical profile or a binary type profile. 3. A system according to claim 2 , wherein the pupil has a variable surface area value. 4. A system according to claim 2 , wherein the pupil has a fixed surface area value. 5. A system according to claim 1 , wherein the pupil has a variable surface area value. 6. A system according to claim 1 , wherein the pupil has a fixed surface area value. 7. A system according to claim 1 , wherein the lens component is configured as a contact lens. 8. A system according to claim 1 , wherein the lens component is part of an intraocular implant. 9. A system according to claim 1 , wherein the lens component constitutes the optical system. 10. A system according to claim 1 , wherein the lens component is part of a near vision zone of a progressive, multifocal ophthalmic lens having a complex surface comprising a far vision zone with a far vision reference point, said near vision zone with a near vision reference point, and an intermediate vision zone wherein a main meridian of the progression crosses the three said vision zones, wherein the first optical power P1 differs from the second optical power P2. 11. A system according to claim 10 , wherein the lens component comprises a refractive component and a simultaneously bifocal diffractive component in which the refractive component is juxtaposed with the diffractive component and wherein the refractive component has an optical power equal to P1/2+P2/2 and the diffractive component has a first power equal to ΔP/2 and a second power equal to −ΔP/2, where ΔP=P1−P2. 12. A method of determining a simultaneously bifocal diffractive optical system, said optical system being defined by a first system focal point and a second system focal point and a pupil, said system comprising a lens component having a first focal point, a second focal point and a plurality of diffractive zones, the plurality of diffractive zones including a central zone and a plurality of annular concentric zones surrounding the central zone, the lens component having a first optical power P1 and a second optical power P2 associated with the first focal point and the second focal point respectively, the first focal point and the second focal point respectively corresponding to points of convergence of the most luminous orders of diffraction generated by the lens component for a nominal wavelength, the first system focal point and the second system focal point having a position dependent upon the value of the first optical power P1 and the second optical power P2 of the lens respectively, wherein the method comprises: a step of determining a surface area value of the central zone by optimization of a predetermined optical performance optimization parameter φ, said optical performance optimization parameter φ being considered in the vicinity of the first and second system focal points and varying as a function of a surface area value of the central zone without modifying the operational function of the diffractive zones, said predetermined optical performance optimization parameter φ being such as the brightness and/or the Modulation Transfer Function in a vicinity of the first and second system focal points, whereby the surface area value of the central zone is determined as a function of the pupil of the optical system, of the first optical power P1 and of the second optical power P2,and the surface area of the annular zones surrounding the central zone does not change with the optimization parameter φ while the area of the central zone does change with optimization parameter φ. 13. A method according to claim 12 , wherein the component constitutes the optical system. 14. A method according to claim 13 , wherein the pupil of the optical system has a surface area value variable within a range of surface area values and wherein the step of determining the surface area value of the central zone comprises: evaluating surface area values of the central zone, associated with a set of pupils of the said optical system, each pupil having a surface area value within the said range of surface area values, by optimization of the optical performance optimization parameter φ for each pupil of this set; evaluating an optical performance of the optical system for each of the surface area values of the central zone as a mean of the optimized optical performance optimization parameters φ on the set of pupil surface area values of the said optical system; and determining an optimum performance among the evaluated optical performances of the said optical system and deducing therefrom the surface area value of the central zone which corresponds to the determined optimum performance. 15. A method according to claim 14 , wherein the optical performance optimization parameter φ is based on the Modulation Transfer Functions at the system focal planes associated with the first and second focal points. 16. A method according to claim 12 , wherein the pupil of the optical system has a fixed surface area value and the step of determining the surface area value of the central zone by optimization of the optical performance optimization parameter φ is carried out in considering the pupil surface area value. 17. A method according to claim 12 , wherein the pupil of the optical system has a surface area value variable within a range of surface area values and wherein the step of determining the surface area value of the central zone comprises: evaluating surface area values of the central zone, associated with a set