Multi-focal lens

The invention claimed is: 1. An imaging lens structure comprising: a lens region defining an effective aperture of the lens structure, said lens region comprising an arrangement of lens zones distributed within the lens region and comprising zones of at least two different optical functions differently affecting light passing therethrough, said arrangement of lens zones being formed by a surface relief on an outer surface of the lens region, such that the lens zones of the at least two different optical functions are arranged in an interlaced fashion along said lens region and adjacent lens zones of the different optical functions are spaced apart from one another along an optical axis of the lens structure a distance larger than a coherence length of white light illumination; and a phase coder comprising multiple phase coding patterns associated with the lens zones of the at least two different optical functions. 2. The lens structure of claim 1 , wherein said lens region comprises two or more different patterns formed by said arrangement of the lens zones differently affecting light passing therethrough, features of said two or more different patterns being arranged in the interlaced fashion forming said surface relief. 3. The imaging lens structure of claim 1 , wherein said lens zones of at least two optical functions are arranged in a disordered fashion. 4. The lens structure of claim 3 , wherein said lens zones of at least two optical functions are arranged in a random fashion. 5. The lens structure of claim 1 , wherein at least some of the lens zones have a dimension along the surface of the lens region larger than a wavelength of light within a-spectral range for which the lens was designed. 6. The lens structure of claim 1 , further comprising a base lens having a certain first optical function and an optical mask formed by a plurality of lens zones having at least one second optical function, said optical mask being aligned with at least a part of the base lens thereby defining said lens region formed by the lens zones of said at least two different optical functions. 7. The lens structure of claim 6 , wherein said mask is a separate element attached or located close to the base lens. 8. The lens structure of claim 6 , wherein said mask is embedded in the base lens. 9. The lens structure of claim 8 , wherein said mask is the surface relief etched in said base lens. 10. The lens structure of claim 1 , wherein at least one of said at least two different optical functions defines a focal length. 11. The lens structure of claim 10 , wherein the lens zones of said at least one optical function defining the focal length are formed by segments of at least one diffractive lens. 12. The lens structure of claim 10 , wherein the lens zones of said at least one optical function defining the focal length are formed by segments of at least one refractive lens. 13. The lens structure of claim 10 , wherein said lens zones of the different focal lengths are formed by segments of refractive and diffractive lenses. 14. The imaging lens structure of claim 1 , wherein the lens zones are configured as angular segments of the lens region arranged around the optical axis. 15. The imaging lens structure of claim 14 , wherein said angular segments comprise segments of two different focal lengths arranged in the interlaced fashion. 16. The imaging lens structure of claim 15 , wherein said two different focal lengths corresponding to a patient's prescribed far and near vision respectively. 17. The imaging lens structure of claim 15 , wherein the lens zones are associated with the two different focal lengths and are arranged around the optical axis with radial symmetry. 18. The imaging lens structure of claim 17 , wherein the angular segments of the different focal lengths are arranged such that the angular segments of the same focal length comprise segments arranged along two perpendicular axes, thereby enabling to orient the imaging lens structure with respect to a line of sight such that vertically and horizontally oriented segments within the lens region are those having the focal length corresponding to the near field vision, and the angular segment of other orientations with respect to the line of sight are those corresponding to the far field vision. 19. The imaging lens structure of claim 15 wherein the phase coder comprises first and second phase coding patterns associated with lens zones of the two different focal lengths respectively to provide extended depth of focus for imaging via said angular segments. 20. The imaging lens of claim 19 , wherein the phase coder may have one of the following configuration: (i) is a separate phase mask located close to or attached to the lens region along the optical axis; (ii) is a phase mask integral with the lens region. 21. A multi-focal ophthalmic lens formed by the imaging lens structure of claim 1 . 22. The multi-focal ophthalmic lens of claim 21 , configured as intraocular lens, intracorneal lens or contact lens. 23. The imaging lens of claim 1 , configured for use as spectacles lens. 24. An imaging lens unit comprising a multi-focal lens region, said lens region comprising: a plurality of angular segments of at least two different focal lengths arranged in a radial symmetry around an optical axis of said lens region, and a phase coder comprising at least two phase coding patterns associated with the angular segments of said at least two different focal lengths respectively, the angular segments of said at least two different focal lengths being arranged such that the angular segments of one focal length comprise segments arranged along two perpendicular axes, thereby enabling orientation of the imaging lens structure with respect to a line of sight such that vertically and horizontally oriented segments within the lens region are those having said one focal length. 25. The imaging lens unit of claim 24 , wherein said two different focal lengths corresponding to patient's prescribed far and near vision respectively. 26. The imaging lens unit of claim 25 , wherein the angular segments of the different focal lengths are arranged such that the angular segments of the same focal length comprise segments arranged along the two perpendicular axes, thereby enabling to orient the imaging lens structure with respect to a line of sight such that vertically and horizontally oriented segments within the lens region are those having the focal length corresponding to the near field vision, and the angular segments of other orientations with respect to the line of sight are those corresponding to the far field vision. 27. The imaging lens unit of claim 24 , wherein the at least two phase coding patterns associated with the lens regions of the at least two different focal lengths respectively are configured to provide extended depth of focus for imaging via said angular segments. 28. The imaging lens of claim 24 , wherein the phase coder has one of the following configuration: (i) is a separate phase mask located close to or attached to the lens region along the optical axis; (ii) is a phase mask integral with the lens region.