Eyeglass optimization using an individual eye model

The invention claimed is: 1. A computer-implemented method for producing a spectacle lens by calculating or optimizing the spectacle lens for at least one eye of a spectacle wearer, the method comprising: providing a refraction data storage device configured to store measured refraction data of the at least one eye of the spectacle wearer; defining, by a computer, an individual eye model, which defines at least: the topography of a corneal front surface of the at least one eye, position and power of a lens of the eye, and a retina position of the eye such that the eye model exhibits the collected refraction data; specifying, by the computer, a first surface and a second surface for the spectacle lens to be calculated or optimized and a power of at least the first and second surfaces of the spectacle lens from data stored in a database; determining, by the computer, a path of a main ray through at least one visual point of at least one spectacle lens surface to be calculated or optimized; specifying, by the computer, a spherical wavefront incident on the first surface of the spectacle lens along the main ray; determining, by the computer, a wavefront in the at least one eye, which results from the spherical wavefront in a surrounding of the main ray due to the power of at least the first and second surfaces of the spectacle lens, the corneal front surface, and the lens of the at least one eye; iteratively varying, by the computer, the at least one spectacle lens surface to be calculated or optimized until an aberration of the resulting wavefront corresponds to a specified target aberration; and manufacturing the thus calculated or optimized spectacle lens on a manufacturing machine. 2. The method according to claim 1 , wherein defining the individual eye model comprises: specifying a plurality of refractive surfaces of the eye, at least one of which being described by a set of parameters; and determining, by the computer, individual values for the set of parameters such that the eye of the eye model exhibits the collected refraction data. 3. The method according to claim 1 , wherein the collecting refraction data of the at least one eye comprises measuring the refraction data by means of light of a measurement wavelength, and wherein defining the individual eye model comprises: defining a wavelength dependency of at least one optical element of the individual eye model; and determining, by the computer, a geometry of the optical element such that the eye of the eye model exhibits the measured refraction data for the defined wavelength dependency and for the measurement wavelength. 4. The method according to claim 1 , wherein defining an individual eye model comprises: Collecting individual topographic data of the corneal front surface and/or of an individual retina position of the at least one eye; and determining, by the computer, the power of the lens of the eye such that the eye in the eye model exhibits a refraction according to the collected refraction data of the spectacle wearer. 5. The method according to claim 1 , wherein the resulting wavefront is determined by means of wavefront tracing. 6. The method according to claim 1 , wherein the determining the resulting wavefront comprises: calculating a wavefront refracted at the first surface of the spectacle lens from the specified spherical wavefront and the specified first surface; calculating a wavefront propagated through the spectacle lens along the main ray from the calculated wavefront refracted at the first surface; calculating a wavefront refracted at the second surface of the spectacle lens from the calculated wavefront, propagated through the spectacle lens, and the specified second surface; calculating a wavefront propagated along the main ray to the corneal front surface from the calculated wavefront refracted at the second surface; calculating a wavefront refracted at the corneal front surface from the calculated wavefront, propagated to the corneal front surface, and the topography of the corneal front surface defined by the individual eye model; calculating a wavefront propagated along the main ray to the lens from the calculated wavefront refracted at the corneal front surface; and calculating a wavefront refracted by the lens from the calculated wavefront propagated to the lens, and the power of the lens defined by the individual eye model. 7. The method according to claim 1 , wherein the iteratively varying the at least one spectacle lens surface to be calculated or optimized comprises minimizing a target function. 8. The method according to claim 1 , wherein the collecting refraction data comprises collecting data relating to the spherical power, the magnitude of the astigmatism, the astigmatism axis, and at least one further higher-order refraction of the eye. 9. The method according to claim 8 , wherein the collecting refraction data comprises collecting first refraction data for a first object distance and second refraction data for a second object distance. 10. The method according to claim 1 , further comprising: specifying an object distance model Al(x, y), where Al designates an object distance and (x,y) a visual point or visual spot of the spectacle lens in a specified or specifiable direction of sight; specifying a function r0=g(AI), which describes a dependence of a pupil size r0 on the object distance Al; and determining a pupil size for the main ray on the basis of the object distance model Al(x, y) and the specified function r0=g(AI). 11. The method according to claim 1 , wherein the spectacle lens to be optimized is a progressive spectacle lens. 12. A non-transitory storage medium with a computer program stored thereon, wherein the computer program is adapted, when loaded and executed on a computer, to perform a method for calculating or optimizing a spectacle lens according to claim 1 . 13. An apparatus for calculating or optimizing a spectacle lens for at least one eye of a spectacle wearer, comprising: a refraction data storage device configured to store measured refraction data of the at least one eye of the spectacle wearer; a computer in communication with the refraction data storage device and comprising: one or more processors; and a memory configured to store a program of instructions executable by the processors for: a data interface adapted to collect refraction data of the at least one eye of the spectacle wearer; a modeler adapted to define an individual eye model, which defines at least: the topography of a corneal front surface of the at least one eye, position and power of a lens of the eye, and a retina position of the eye such that the eye model exhibits the collected refraction data; a surface lens specifier to specify a first surface and a second surface for the spectacle lens to be calculated or optimized and a power of at least the first and second surfaces of the spectacle lens from data stored in a database; a main ray determiner adapted to determine a path of a main ray through at least one visual point of at least one spectacle lens surface to be calculated or optimized; an object modeler adapted to specify a spherical wavefront incident on the first surface of the spectacle lens along the main ray; a wavefront calculator adapted to determine a wavefront in the at least one eye, which results from the spherical wavefront in a surrounding of the main ray due to the power of at least the first and second surfaces of the spectacle lens, the corneal front surface, and the lens of the at least one eye; and an optimizer adapted to iteratively vary the at least one spectacle lens surface t