Method for determining the far visual point for a spectacle lens and system therefor

What is claimed is: 1. A method for determining a far vision point on a spectacle lens mountable in a spectacle frame defining a frame plane, the method comprising the steps of: providing a camera defining an optical axis; capturing an image of at least one section of the spectacle frame worn by a subject with the camera wherein the image lies in an image plane and includes pupils of eyes of the subject and while the subject looks in a viewing direction passing through the frame plane with at least one eye into the camera wherein the viewing direction and the frame plane conjointly define an intercept; determining a pantoscopic angle α′ of the spectacle frame referred to the position of said image plane; capturing an inclination angle γ of said image plane relative to a vertical direction; correcting said pantoscopic angle α′ to a pantoscopic angle α referred to said vertical direction in correspondence to said captured inclination angle γ; determining a head rotation angle β of the head of the subject conjointly defined by the optical axis of the camera and a plane perpendicular to the distance line of the pupils of the eyes of the subject; correcting the head rotation angle β in correspondence to the captured inclination angle γ of the image plane relative to the vertical direction to a head rotation angle β′ corrected in correspondence to a horizontal alignment of the optical axis of the camera; determining the far vision point by analyzing the image lying in the image plane while considering the head rotation angle β′ corrected in correspondence to the horizontal alignment of the optical axis of the camera; determining said intercept of the viewing direction and the frame plane via image evaluation; determining the far vision point as an intercept of a virtual viewing direction and the frame plane wherein the virtual viewing direction lies in a horizontal plane; determining the virtual viewing direction as the direction of a virtual straight line which is detected by rotating a further straight line defined by a reference point arranged on the eye wherein the reference point has a known position with reference to the camera or the spectacle frame and the intercept of the viewing direction; in that, said further straight line is rotated in a virtual pivot about a first angle β OD ″, β OS ″, which is dependent upon the corrected head rotation angle β′, about an axis parallel to the vertical direction and wherein the virtual pivot is spaced from the reference point and lies within the eye on the further straight line; and, in that, the further straight line is rotated in said virtual pivot about a further axis by a further angle α″, wherein the further axis is parallel to the distance line of the pupils of the eyes of the subject and the further angle α″ is dependent upon the corrected pantoscopic angle α; wherein the following applies for the first angle β OD ″ when the eye is a right eye of the subject: tan β OD ″=(0.5× P D ×cos β′+ YZ )/( D+HSA ) said first angle β OD ″ being dependent upon the corrected head rotation angle β′; wherein the following applies for the first angle β OS ″ when the eye is a left eye of the subject: tan β OS ″=(0.5× P D ×cos β′− YZ )/( D+HSA ) said first angle β OS ″ being dependent upon the corrected head rotation angle β′; in the above: P D is the interpupillary distance of the eyes of the subject; and, (D+HSA) is the perpendicular distance of the camera from a vertical plane wherein the distance line of the pupils of the eyes lies; YZ is the distances between the intercept Y of the distance line of the pupils of the eyes with the perpendicular projection of the optical axis of the camera in a horizontal plane wherein the distance lines of the pupils of the eyes are located and the intercept Z of the distance line of the pupils of the eyes with a vertical plane which intersects the distance line of the pupils of the eyes and is perpendicular to the frame plane and wherein the vertical symmetry axis of the spectacle frame lies; for the further angle α″, the following applies: α″=−(γ+δ) wherein the further angle is dependent from the corrected pantoscopic angle α; and, wherein δ is the angle conjointly defined by the optical axis of the camera and the perpendicular projection of the viewing direction in a vertical plane wherein the optical axis of the camera lies. 2. The method of claim 1 , wherein: the pantoscopic angle α′ of the spectacle frame is determined via image analysis of the captured image of at least one section of the spectacle frame wherein the pantoscopic angle α is referred to the position of the image plane and the spectacle frame is worn by the subject; and/or, the head rotation angle β of the head of the subject is determined via an image analysis of the captured image of the at least one section of the spectacle frame worn by the subject and wherein the head rotation angle β is conjointly defined by the optical axis of the camera and a plane perpendicular to the distance line of the pupils of the eyes of the subject. 3. The method of claim 1 , wherein the corrected pantoscopic angle α satisfies the following relationship: α=α′−γ. 4. The method of claim 1 , wherein the corrected head rotation angle β′ satisfies the following relationship: β′=β/cos (α′−γ). 5. The method of claim 1 , wherein the reference point is the corneal vertex of the eye of the subject and/or the reference point is a fixed center of the pupil of the eye of the subject. 6. The method of claim 1 , wherein the position of the virtual pivot on the further straight line is determined by specifying a fixed distance of the virtual pivot from the reference point wherein the further straight line is determined by the reference point of the known position with reference to the camera or spectacle frame and the intercept of the viewing direction. 7. The method of claim 1 , wherein the interpupillary distance P D of the eyes of the subject is determined via image analysis of an image captured by the camera wherein the captured image holds the pupils of the eyes of the subject and at least one section of the spectacle frame worn by the subject. 8. The method of claim 1 , wherein the angle δ is conjointly defined by the optical axis of the camera and the perpendicular projection of the viewing direction in a vertical plane; and, the angle δ is determined via image analysis of the captured image of the at least one section of the spectacle frame worn by the subject. 9. The method of claim 1 , wherein said distance YZ is determined via image analysis of said image captured by the camera. 10. The method of claim 1 , wherein the determination of a far vision point and the determination of an adaptation parameter from the determined far vision point and from additional information obtained from the captured image is obtained via image analysis. 11. A system for determining a far vision point on a spectacle lens mountable in a spectacle frame defining a frame plane, the system comprising: a camera having an image plane and including an inclination sensor configured to detect the inclination of said image plane about a horizontal axis; a computer unit including: first means for determining a pantoscopic angle α of said spectacle frame with said pantoscopic angle α′ being referenced to the position of said image plane; second means for correcting said pantoscopic angle α′ of said spectacle frame to a pantoscopic angle α referred to a vertical direction in correspondence to a captured inclination angle γ of the image plane relative to said vertical direction; third means for determining a head rotation angle β of the head of