Optical scanning apparatus, system and method

What is claimed is: 1. An optical scanning apparatus comprising: an array of optical emitters to provide a plurality of optical beams; a plurality of microlenses to receive the optical beams and form an intermediate image of the array at substantially unity array magnification, the intermediate image comprising a plurality of spots, each spot corresponding to a different one of the optical beams; a collimator to receive the plurality of optical beams from the intermediate image; a beam scanner to scan the optical beams received from the collimator in an in-scan direction; and a scan lens to focus the scanned optical beams to form an arrangement of illumination spots on a scanning surface, the arrangement of illumination spots forming an image of the array. 2. The optical scanning apparatus of claim 1 , wherein each microlens of the plurality comprises a first microlens element having a first associated magnification to provide fast-axis direction convergence of the corresponding optical beam and a second microlens element having a second associated magnification to provide slow-axis direction convergence of the corresponding optical beam. 3. The optical scanning apparatus of claim 1 , wherein each microlens of the plurality has a first surface to provide fast-axis direction convergence of the optical beam and a second surface to provide slow-axis direction convergence of the optical beam. 4. The optical scanning apparatus of claim 1 , wherein the optical emitters are edge emitting laser diodes and, wherein the microlenses reduce a magnitude of a half-width-half-maximum (HWHM) cone angle of the optical beams produced by the edge emitting laser diodes by at least a factor of ten at an output of the microlenses. 5. The optical scanning apparatus of claim 1 , wherein the collimator is an adjustable collimator having an adjustable focal length, the adjustable focal length being adjustable to vary a spacing between illumination spots in the arrangement of illumination spots on the scanning surface. 6. The optical scanning apparatus of claim 5 , wherein the focal length of the adjustable collimator is adjustable between about plus five percent and about minus five percent around a central value of the focal length. 7. The optical scanning apparatus of claim 5 , wherein the focal length of the adjustable collimator is adjustable according to a measured spacing of the illumination spots on the scanning surface, the measured spacing being provided by a real-time feedback measurement system. 8. The optical scanning apparatus of claim 1 , wherein the scan lens comprises: a first lens element having an optical power in the in-scan direction and having an optical power in a cross-scan direction, the cross-scan direction optical power of the first lens element being both positive and greater than the in-scan direction optical power of the first lens element, the cross-scan direction being perpendicular to the in-scan direction; a second lens element having a negative optical power in the in-scan direction and a negative optical power in the cross-scan direction; a third lens element having a positive optical power in the in-scan direction and a positive optical power in the cross-scan direction; and a fourth lens element having an optical power in the in-scan direction and an optical power in the cross-scan direction, the cross-scan optical power of the fourth lens element being both positive and greater than the in-scan direction optical power of the fourth lens element, wherein the first, second, third, and fourth lens elements are optically positioned in ascending numeric order between the beam scanner and the scanning surface. 9. A scanning system comprising: an emitter module to provide a plurality of optical beams, the emitter module comprising an array of optical beam emitters and a corresponding array of microlenses, each microlens comprising a first microlens element operating at a first magnification and a second microlens element operating at a second, separate magnification; an adjustable collimator having a focal length that is variable to adjustably establish a spacing between illumination spots produced by the optical beams from the array of optical beam emitters; a beam scanner to scan the optical beams in an in-scan direction; and a scanning surface to move in a cross-scan direction that is substantially perpendicular to the in-scan direction, wherein the illumination spots are imaged on the scanning surface in a row that is substantially parallel to the cross-scan direction. 10. The scanning system of claim 9 , wherein the scanning surface comprises a surface of a photoconductive drum of a laser printer, a rotation of the photoconductive drum providing the cross-scan direction motion of the scanning surface. 11. The scanning system of claim 9 , wherein the focal length of the adjustable collimator is variable according to a measured spacing of the illumination spots, the measured spacing being provided by a real-time feedback measurement system, and wherein the focal length of the adjustable collimator provides a focal length range that is between about plus five percent and about minus five percent around a central value of the focal length. 12. The scanning system of claim 9 , wherein the corresponding array of microlenses comprises a first array of first microlens elements to provide fast-axis direction convergence of the optical beams and a second array of second microlens elements to provide slow-axis direction convergence of the optical beams. 13. The scanning system of claim 9 , further comprising a scan lens between the beam scanner and the scanning surface to focus the optical beams onto the scanning surface, the scan lens comprising: a first lens element having an optical power in the in-scan direction and having an optical power in a cross-scan direction, the cross-scan direction optical power of the first lens element being both positive and greater than the in-scan direction optical power of the first lens element, the cross-scan direction being perpendicular to the in-scan direction; a second lens element having a negative optical power in the in-scan direction and a negative optical power in the cross-scan direction; a third lens element having a positive optical power in the in-scan direction and a positive optical power in the cross-scan direction; and a fourth lens element having an optical power in the in-scan direction and an optical power in the cross-scan direction, the cross-scan optical power of the fourth lens element being both positive and greater than the in-scan direction optical power of the fourth lens element, wherein the first, second, third, and fourth lens elements are optically positioned in ascending numeric order between the beam scanner and the scanning surface. 14. A method of optical scanning, the method comprising: adjusting cone angles of a plurality of optical beams produced by an array of optical emitters by individually imaging each of the optical emitters using separate microlenses to form an intermediate image of the array at substantially unity array magnification with respect to the emitter array, the intermediate image comprising a plurality of spots at an intermediate image plane; adjusting a spacing between illumination spots produced by the optical beams at a scanning surface using an adjustable collimator; and scanning the optical beams in an in-scan direction across the scanning surface, wherein an arrangement of the illumination spots forms an image of the array. 15. The method of optical scanning of claim 14 , further comprising: measu