Apparatus for generating a line-beam from a diode-laser array

What is claimed is: 1. An apparatus for generating a line-beam, comprising: a diode-laser bar emitting laser-radiation in an emission direction, the diode-laser bar having perpendicular slow-axis and fast-axis directions; a collimating lens arranged to intercept the laser-radiation and collimate the laser-radiation in the fast-axis direction; a focusing lens; a linear micro-lens array having a plurality of cylindrical micro-lenses arranged in an elongated array thereof, the linear micro-lens array having a first direction parallel with the elongated array of cylindrical micro-lenses and a second direction perpendicular to the elongated array of cylindrical micro-lenses; a first cylindrical lens and a second cylindrical lens; wherein the collimating lens, the focusing lens, the linear micro-lens array, the first cylindrical lens, and the second cylindrical lens located in recited order along an optical axis in the emission direction, and arranged to form the line-beam from the laser-radiation emitted by the diode-laser bar; and wherein, the slow-axis and fast-axis directions are rotated from parallel alignment with the first and second directions by a fixed angle of at least 2°. 2. The apparatus of claim 1 , where in the fixed angle is between about 2° and 20°. 3. The apparatus of claim 1 , wherein the first cylindrical lens has positive optical power in the first direction and the second cylindrical lens has positive optical power in the second direction. 4. The apparatus of claim 1 , wherein the collimating lens, the focusing lens, and the second cylindrical lens are selected and arranged to illuminate an image plane in the second direction with a far-field image of the diode-laser bar. 5. The apparatus of claim 1 , wherein the collimating lens has a first focal length, the collimating lens and the diode-laser bar being separated by about the first focal length. 6. The apparatus of claim 1 , wherein the focusing lens has positive optical powers in the fast-axis and slow-axis directions. 7. The apparatus of claim 6 , wherein the optical powers of the focusing lens are about the same in the slow-axis and fast-axis directions. 8. The apparatus of claim 1 , wherein the focusing lens has a second focal length in the slow-axis direction, the focusing lens and the diode-laser bar being separated by about the second focal length. 9. The apparatus of claim 8 , wherein the focusing lens and the linear micro-lens array are separated by about the second focal length. 10. The apparatus of claim 1 , wherein the diode-laser bar includes a plurality of diode-laser emitters, the focusing lens and the linear micro-lens array arranged to spread the laser-radiation in the slow-axis direction and illuminate every one of the cylindrical micro-lenses with laser-radiation from every one of the diode-laser emitters. 11. The apparatus of claim 10 , wherein each cylindrical micro-lens is a source of mixed laser-radiation, the first cylindrical lens arranged to overlap mixed laser-radiation from every one of the cylindrical micro-lenses in a first illumination plane, the overlapping mixed-beams of laser-radiation forming the line-beam in the first illumination plane, the line-beam being parallel with the first direction. 12. The apparatus of claim 11 , wherein the first cylindrical lens has a third focal length, the first cylindrical lens and the first illumination plane being separated by about the third focal length. 13. An apparatus for generating a line-beam, comprising: a diode-laser bar emitting laser-radiation in an emission direction, the diode-laser bar having perpendicular slow-axis and fast-axis directions; a fast-axis collimating lens arranged to intercept the laser-radiation and collimate the laser-radiation in the fast-axis direction; a first linear micro-lens array having a plurality of first cylindrical micro-lenses arranged in an elongated array thereof, the first linear micro-lens array having a first direction parallel with the elongated array of first cylindrical micro-lenses and a second direction perpendicular to the elongated array of first cylindrical micro-lenses; a focusing lens; a second linear micro-lens array having a plurality of second cylindrical micro-lenses arranged in an elongated array thereof, the second linear micro-lens array having a third direction parallel with the elongated array of second cylindrical micro-lenses and a fourth direction perpendicular to the elongated array of second cylindrical micro-lenses; a cylindrical lens; wherein the fast-axis collimating lens, the first linear micro-lens array, the focusing lens, the second linear micro-lens array, and the cylindrical lens located in recited order along an optical axis in the emission direction, and arranged to form the line-beam from the laser-radiation emitted by the diode-laser bar; and wherein, the first and second directions are rotated from parallel alignment with the third and fourth directions by a fixed angle of at least 2°. 14. The apparatus of claim 13 , wherein the fixed angle is between about 2° and 20°. 15. The apparatus of claim 13 , wherein the slow-axis direction is parallel to the third direction and the fast-axis direction is parallel to the fourth direction. 16. The apparatus of claim 13 , wherein the focusing lens has positive optical powers in the first and second directions, and the cylindrical lens has positive optical power in the third direction. 17. The apparatus of claim 13 , further including a slow-axis collimating-lens array located on the optical axis between the fast-axis collimating lens and the first linear micro-lens array, the slow-axis collimating-lens array arranged to intercept the laser-radiation and collimate the laser-radiation in the slow-axis direction. 18. An apparatus for generating a line-beam, comprising: a diode-laser bar emitting laser-radiation in an emission direction, the diode-laser bar having perpendicular slow-axis and fast-axis directions; a collimating lens arranged to intercept the laser-radiation and collimate the laser-radiation in the fast-axis direction; a focusing lens; a linear micro-lens array having a plurality of cylindrical micro-lenses arranged in an elongated array thereof, the linear micro-lens array having a first direction parallel with the elongated array of cylindrical micro-lenses and a second direction perpendicular to the elongated array of cylindrical micro-lenses, the slow-axis and fast-axis directions rotated from parallel alignment with the first and second directions by a fixed angle of at least 2°, the focusing lens and the linear micro-lens array arranged for uniform illumination of the linear micro-lens array by the laser-radiation; a cylindrical lens, the collimating lens, the focusing lens, the linear micro-lens array and the cylindrical lens located in recited order along an optical axis in the emission direction, and arranged to form the line-beam in a first illumination plane from the laser-radiation emitted by the diode-laser bar; an aperture located in a second illumination plane, the aperture arranged to partially block the line-beam in the first direction; and a spherical lens, the spherical lens located on the optical axis and arranged to project an image of the partially-blocked line-beam in the second illumination plane to a third illumination plane. 19. The apparatus of claim 18 , where in the fixed angle is between about 2° and 20°. 20. The apparatus of claim 18 , wherein the cylindrical lens has positive optical power in the