Integral lighting assembly

The invention claimed is: 1. An integral lighting assembly comprising: an optical arrangement; a first light source for generating a first beam of light; a first collimator for directing the first beam at the optical arrangement; a second light source for generating a second beam of light; and a second collimator for directing the second beam at the optical arrangement; wherein the collimators are arranged such that each collimator on one side of an optical axis of the lighting assembly directs its beam of light essentially at a region of the optical arrangement on the other side of the optical axis such that at least a portion of the first beam and at least a portion of the second beam cross the optical axis at a common point on the optical axis before arriving at the optical arrangement, wherein the optical arrangement is configured to manipulate the first beam to provide a low exit beam and to manipulate the second light beam to provide a high exit beam such that the low exit beam and the high exit beam are partially combined in an overlap region on a projection plane located at a predefined distance from the integral lighting assembly and such that a majority of the high exit beam is non-overlapping with respect to the low exit beam in the projection plane, and wherein the optical arrangement comprises a first lens and comprises, on a surface of said first lens, a plurality of linear prism elements and a plurality of linear lenses that are oriented on said surface essentially perpendicular to the linear prism elements such that one of said first beam and said second beam intersects said plurality of liner prism elements and the other of said first beam and said second beam intersects said plurality of linear lenses. 2. The integral lighting assembly according to claim 1 , wherein the plurality of linear lenses compose a spreading element for horizontally spreading any light incident at the spreading element and the plurality of linear prism elements compose a shifting element for vertically shifting any light incident at the shifting element. 3. The integral lighting assembly according to claim 2 wherein the spreading element is configured to spread at least part of the first beam prior to manipulation by the first lens such that the low exit beam is projected to give two overlapping first beam regions in the projection plane. 4. The integral lighting assembly according to claim 2 , wherein the shifting element is configured to shift at least part of the second beam prior to manipulation by the first lens such that the high exit beam is projected to give two overlapping second beam regions in the projection plane. 5. The integral lighting assembly according to claim 2 , wherein the first lens is a projection lens and wherein the shifting element is arranged to vertically shift the light incident at the shifting element prior to refraction by the projection lens. 6. The integral lighting assembly according to claim 2 , wherein the first lens is a projection lens and wherein the plurality of linear lenses are a plurality of cylindrical lens elements and are arranged to refract and horizontally spread the light incident at the spreader element prior to refraction by the projection lens. 7. The integral lighting assembly according to claim 1 , wherein the first lens is a projection lens. 8. The integral lighting assembly according to claim 1 , wherein the first and second beams intersect at least partially in a focal plane overlap region on a focal plane of the optical arrangement so that the projection plane overlap region corresponds to the focal plane overlap region. 9. The integral lighting assembly according to claim 1 , comprising a collimator arrangement in which light exit openings of the first collimator and the second collimator are located in close proximity to the focal plane of the optical arrangement. 10. The integral lighting assembly according to claim 1 , comprising a collimator arrangement in which at least one of the first or second collimators comprises a prism element at its corresponding light exit opening, wherein the prism element of the collimator arrangement is configured to refract the corresponding beam of light towards the optical axis. 11. The integral lighting assembly according to claim 1 , wherein at least one of the first or second light sources comprises an LED source. 12. The integral lighting assembly according to claim 1 , wherein at least one of the first or second collimators comprises a near-die collimator with a length of between 6 mm and 18 mm. 13. The integral lighting assembly according to claim 1 , wherein the optical arrangement is further configured to manipulate the first and second light beams such that a majority of the low exit beam is non-overlapping with respect to the high exit beam in the projection plane. 14. The integral lighting assembly according to claim 13 , wherein the predefined distance is 25 meters. 15. An automotive headlamp arrangement comprising the integral lighting assembly according to claim 1 . 16. An integral lighting assembly comprising an optical arrangement; a first light source for generating a first beam of light; a first collimator for directing the first beam at the optical arrangement; a second light source for generating a second beam of light; and a second collimator for directing the second beam at the optical arrangement, wherein the collimators are arranged such that each collimator on one side of an optical axis of the lighting assembly directs its beam of light essentially at a region of the optical arrangement on the other side of the optical axis such that the first beam crosses the second beam before arriving at the optical arrangement, wherein the optical arrangement is configured to manipulate the first and second light beams to give a low exit beam and a high exit beam such that the low exit beam and the high exit beam are partially combined in an overlap region on a projection plane located at a predefined distance from the integral lighting assembly, and wherein the optical arrangement comprises a first lens and comprises, on a surface of said first lens, a plurality of linear prism elements and a plurality of linear lenses that are oriented on said surface essentially perpendicular to the linear prism elements such that one of said first beam and said second beam intersects said plurality of liner prism elements and the other of said first beam and said second beam intersects said plurality of linear lenses.