Compact transform optics for spectral beam combining

What is claimed is: 1. A multi-element transform optic for a spectral beam combining system comprising: a first optical element, the first optical element being a cylindrical optical element having positive optical power in a first axis; a second optical element, the second optical element having negative optical power in the first axis; and a third optical element, the third optical element being a toroid having positive optical power in the first axis and either positive or negative optical power in a second axis that is orthogonal to the first axis, the first and third optical elements being positioned on opposite sides of the second optical element and equidistant from the second optical element, wherein the multi-element transform optic has an optical path length extending between a front focal plane and a back focal plane that is shorter than an effective focal length of the multi-element transform optic, the first optical element being positioned between the front focal plane and the second optical element, and the third optical element being positioned between the second optical element and the back focal plane. 2. The multi-element transform optic of claim 1 wherein the second optical element is a cylindrical optical element, and wherein the third optical element has negative optical power in the second axis. 3. The multi-element transform optic of claim 1 wherein the second optical element is a toroid having negative optical power in the second axis, and wherein the third optical element has positive optical power in the second axis. 4. The multi-element transform optic of claim 1 wherein the first, second, and third optical elements are mirrors. 5. The multi-element transform optic of claim 4 wherein the first optical element and the third optical element have a same radius of curvature. 6. The multi-element transform optic of claim 1 wherein the first, second, and third optical elements are lenses. 7. The multi-element transform optic of claim 1 wherein a first distance between the front focal plane and the first optical element is equal to a second distance between the third optical element and the back focal plane. 8. The multi-element transform optic of claim 7 wherein a third distance between the first optical element and the second optical element is equal to a fourth distance between the second optical element and the third optical element. 9. A spectral beam combining system comprising: a multi-element transform optic including a first optical element having positive optical power in a first axis, a second optical element having negative optical power in the first axis, and a third optical element having positive optical power in the first axis, the second optical element being positioned between the first and third optical elements along the first axis; a diffraction grating positioned at a back focal plane of the multi-element transform optic; and a plurality of optical fibers positioned at a front focal plane of the multi-element transform optic and configured to generate a corresponding plurality of individual optical beams, the multi-element transform optic and the diffraction grating in combination being configured to spectrally overlap the plurality of individual optical beams to form a combined output beam, the first axis corresponding to a dispersion axis of the plurality of optical fibers, wherein an effective focal length of the multi-element transform optic is longer than an optical path length of the multi-element transform optic that extends from the front focal plane to the back focal plane. 10. The spectral beam combining system of claim 9 wherein the plurality of optical fibers are fiber lasers. 11. The spectral beam combining system of claim 9 wherein the first, second, and third optical elements are mirrors. 12. The spectral beam combining system of claim 11 wherein the first and third optical elements have a same radius of curvature. 13. The spectral beam combining system of claim 9 wherein the first, second, and third optical elements are lenses. 14. The spectral beam combining system of claim 9 wherein the first and second optical elements are cylindrical optical elements, and the third optical element is a toroid having negative optical power in a second axis that is orthogonal to the first axis, the second axis corresponding to a non-dispersion axis of the plurality of optical fibers. 15. The spectral beam combining system of claim 9 wherein the first optical element is a cylindrical optical element, the second optical element is toroid having negative optical power in a second axis that is orthogonal to the first axis, and the third optical element is a toroid having positive optical power in the second axis, the second axis corresponding to a non-dispersion axis of the plurality of optical fibers. 16. The spectral beam combining system of claim 9 wherein the second optical element is equidistant from the front and back focal planes along the first axis. 17. The spectral beam combining system of claim 16 wherein a first distance between the first optical element and the front focal plane is equal to a second distance between the third optical element and the back focal plane. 18. The spectral beam combining system of claim 9 further comprising aft optics configured to receive the combined output beam from the diffraction grating. 19. The spectral beam combining system of claim 18 wherein the combined output beam received from the diffraction grating has an elliptical beam profile, and wherein the aft optics are configured to reshape the elliptical beam profile into a circular beam profile.