RU96108389A - MULTIFOCAL EYE LENS, METHOD OF PROVIDING MULTIFOCAL CORRECTION OF VISION OF THE PATIENT, EYE LENS - Google Patents

Claims (15)

1. A multifocal ophthalmic lens comprising a body including a central region and at least first and second concentric annular regions, a first annular region located around the central region, and a second annular region located around the first annular region, characterized in that the central region has an optical surface area and a first optical power, the first annular region includes a plurality of concentric, annular first subdomains, and The regions are arranged radially and sequentially and include a radially located, lying most deeply first region and at least one additional first subdomain, a radially located, lying most deeply first subdomain, has a second optical power and has an optical surface area approximately equal to or larger than the optical area the surface of the Central region, the sum of the areas of the optical surfaces of the Central region and the first annular region, which have the first optical power, riblizitelno equals the sum of the areas of optical surfaces of the first annular region, which have a second optical power, and about half or more of the optical surface area has a first lens optical power.  2. The lens according to claim 1, characterized in that said first subdomains include said radially located most deeply first subdomain and a plurality of additional first subdomains, and additional first subdomains have alternately first and second optical power.  3. The lens according to claim 2, characterized in that said first optical power is a long-range optical power and said second optical power is a short-range optical power.  4. The lens according to claim 1, characterized in that about 60 or more percent of the optical surface area of the lens has a first optical power.  5. The lens according to claim 4, characterized in that about 70% of the optical surface area of the lens has a first optical power, and about 30% of the optical surface area of the lens has a second optical power.  6. The lens according to claim 1, characterized in that the second annular region includes a plurality of concentric, annular second subregions, each of the second subregions has a corresponding optical surface area, and each of the second subregions has one of the optical forces: the first or second, and about half or more of the optical surface area of the second subregions has a first optical power.  7. The lens according to claim 6, characterized in that about 60 or more percent of the optical surface area of the second subregions has a first optical power.  8. The lens according to claim 7, characterized in that about 70% of the optical surface area of the lens has a first optical power; and about 30% of the optical surface area of the lens has a second optical power.  9. A method for providing multifocal correction of a patient’s vision, which requires optical correction, which varies between optical correction for close distances and optical correction for long distances, characterized in that a first relationship is established between the diameter of the pupil of the patient and the light intensity, a second relationship is established between the intensity illumination and the changing needs of the patient in optical correction for either close or long distances, determine the optical The short-range power required for the patient is determined by the long-range optical power required by the patient, an eye lens is constructed with many concentric regions having optical forces for long and short range, and when the lens is worn by the patient, the short-range optical power ratio is and the optical power for long-range action provided by the lens varies as a function of the diameter of the patient’s pupil, and the size of the specified set of concentric areas is determined based on of the first and the second dependency on the basis of said desired optical power for near and far action so that when the lens is worn by the patient, the ratio is changed to meet these changing needs of the patient.  10. The method according to claim 9, characterized in that the stage of establishing the first dependence includes the stage of obtaining the first dependence on the age of the patient. 11. The method according to claim 9, characterized in that the design step includes the step of providing an ophthalmic lens with a central circular region having optical power for long-range action, a first annular region located around the central circular region and having optical power for both near and long-range, and a second annular region located around the first annular region and having optical power for long-range, and the step of determining the size is that
1) provide the first annular region with a first area having optical power for long-range action and a second area having optical power for long-range action so that the total area of the central region and the first annular region having optical power for long-range is approximately equal to the total area of the central a region and a first annular region having optical power for short-range action, and
o) determine the size of the second annular region in such a way that the total area of the central region, the first annular region and the second annular region having optical power for long-distance action is larger than the total area of the central region, the first annular region and the second annular region having optical power for short range action.  12. An eye lens having optical power for both near and long-range, characterized in that it contains an optical surface with a Central part having the specified optical power for long-range, the first annular part located on the outside of the specified Central part and having a larger area with optical power for short-range than the total area with optical power for long-range in the central and first annular parts combined, and the second annular part, is located the outer side of the specified first annular part and having an area with optical power for long-range, sufficient to ensure that the total area with optical power for long-range in the central, first annular and second annular parts combined is larger than the total area with short-range optical power in the central, first annular and second annular parts combined.  13. The lens of claim 12, wherein the lens comprises annular parts of a concentric structure.  14. The lens of claim 12, wherein at least one of said annular parts has more than one optical power.  15. The lens of claim 14, wherein the optical powers of said annular parts extend to optical zones that are radial segments across the boundaries of said annular parts.