Light system for supplying light

The invention claimed is: 1. A light system comprising a light supply arrangement, a Homogenizing Light Pipe (HLP) comprising an input end and an output end, and a fiber bundle, said light supply arrangement comprises a laser light source and is arranged to supply light to be received by the input end of said HLP, said HLP being configured for scrambling said received light such that a light beam at the output end of the HLP has a substantially cross-sectional uniformity, and said HLP being configured for delivering a beam of light to a common packed input end of said fiber bundle, wherein the light supply arrangement is arranged relative to the input end of the HLP, such that the light from the light supply arrangement is diverging to increase a beam diameter of the light such that the HLP is essentially filled by the light at a distance of up to 1 cm into the HLP from an entrance aperture of the HLP, wherein at the distance of up to 1 cm into the HLP from an entrance aperture of the HLP, the fill factor is 0.5 or more. 2. The light system of claim 1 , wherein said light supply arrangement comprises a beam conditioner arranged for conditioning the light beam, said beam conditioner is arranged to deliver said light to the input end of the HLP, such that the beam diameter of the light at the input end of the HLP is larger than an entrance aperture diameter of the HLP. 3. The light system of claim 1 , wherein said fiber bundle comprises at least 50 optical fibers, at least a plurality of said fibers of said fiber bundle has a core and a cladding at the common packed input end. 4. The light system of claim 1 , wherein said fiber bundle is an N branched fiber bundle comprising N output sub-fiber bundles, each output sub-fiber bundle comprises at least two fibers and wherein the optical fibers of the fiber bundle are arranged such that each of the N output sub-fiber bundles comprises randomly selected fibers relative to their position at the common packed input end of said fiber. 5. The light system of claim 1 , wherein said laser light source is selected from a fiber laser, a solid-state laser, a semiconductor laser or any combinations thereof. 6. The light system of claim 1 , wherein said laser light source spans over at least about 100 nm. 7. The light system of claim 1 , wherein said light supply arrangement comprises a wavelength filter, said wavelength filter being wavelength tunable and being configured for filtering off two or more wavelength ranges from an input light beam. 8. The light system of claim 1 , wherein said light supply arrangement comprises a wavelength combiner. 9. The light system of claim 1 , wherein said light supply arrangement is configured for supplying said light to the input end of the HLP directly from the laser light source, or directly from a wavelength filter, when present, or directly from a wavelength combiner, when present. 10. The light system of claim 1 , wherein said light supply arrangement comprises an output fiber arranged for supplying said light to the input end of the HLP, said output fiber having a numerical aperture of at least about 0.10. 11. The light system of claim 1 , wherein said HLP has a reflecting boundary with an entrance aperture diameter and a cross sectional rotationally asymmetrical shape. 12. The light system of claim 1 , wherein said HLP comprises a rod of material capable of transmitting at least a portion of the light supplied from said light supply arrangement. 13. The light system of claim 1 , wherein said HLP comprises a hollow tubular body with an inner reflective surface, said inner reflective surface having a cross-sectional rotationally asymmetrical shape. 14. The light system of any claim 1 , wherein said entrance aperture of the HLP has a cross-sectional dimension from about 1 mm to about 20 mm. 15. The light system of claim 1 , wherein the beam diameter of the light at the input end of the HLP is at least about 20% of an entrance aperture diameter of the HLP. 16. The light system of claim 1 , wherein the beam diameter of the light at the input end of the HLP is at least about 50% of an entrance aperture diameter of the HLP. 17. The light system of claim 1 , wherein the laser light source is configured for generating a light beam with a first beam M 2 factor and the HLP is configured for scrambling the light beam to increase the first beam M 2 factor to a second beam M 2 factor, larger than the first beam M 2 factor. 18. The light system of claim 1 , wherein said HLP is configured for scrambling the light from the light supply arrangement such that the light beam at the output end of the HLP has a uniform modal power distribution. 19. The light system of claim 1 , wherein said laser light source is a supercontinuum light source. 20. The light system of claim 2 , wherein said beam conditioner comprises a diffuser, a diverging lens, a plano-concave lens, a gradient index lens and/or a micro lens array. 21. The light system of claim 7 , wherein said light supply arrangement comprises an Acousto Optic Tunable Filter (AOTF). 22. The light system of claim 11 , wherein sides or reflecting boundaries of said HLP are coated with a reflective coating. 23. The light system of claim 11 , wherein said HLP is guiding light by total internal reflection. 24. The light system of claim 12 , wherein said rod comprises a glass rod. 25. The light system of claim 13 , wherein said hollow tubular body comprises a glass body, a metal body, a ceramic body or any combinations thereof. 26. The light system of claim 17 , wherein the second beam M 2 factor is at least about 10% larger than the first beam M 2 factor.