Integrated pumplight homogenizer and signal injector for high-power laser system

What is claimed is: 1. A system comprising: a master oscillator configured to generate a first optical beam; a planar waveguide (PWG) amplifier configured to receive the first optical beam and pumplight, the PWG amplifier also configured to generate a second optical beam using the first optical beam and the pumplight; and a light pipe comprising: a first optic configured to substantially homogenize the pumplight via internal reflection and to inject the substantially homogenized pumplight into a planar waveguide of the PWG amplifier, and a cladding comprising second and third optics separated from one another by a first gap, the first gap forming a first area of reflection, the first area of reflection configured to: fold the first optical beam and thereby redirect the first optical beam into the planar waveguide, and reflect stray pumplight toward a first beam dump; wherein the second optical beam has a higher power than the first optical beam. 2. The system of claim 1 , wherein the light pipe forms a pumplight aperture and an optical beam aperture that are aligned with the planar waveguide. 3. The system of claim 1 , wherein the light pipe comprises: a core comprising the first optic, the first optic configured to guide the pumplight along a guiding axis, the first optic also configured to deliver the substantially homogenized pumplight into the planar waveguide. 4. The system of claim 1 , wherein the cladding of the light pipe further comprises: fourth and fifth optics separated from one another by a second gap, the second gap forming a second area of reflection, the second area of reflection configured to reflect stray pumplight toward a second beam dump. 5. The system of claim 1 , wherein the light pipe comprises: at least two sets of substantially parallel reflective surfaces; and a core that comprises the first optic and that is located between the sets of reflective surfaces, the core configured to guide the pumplight along a guiding axis and deliver the substantially homogenized pumplight into the planar waveguide. 6. The system of claim 5 , wherein the core comprises a gas-filled space. 7. The system of claim 1 , wherein the light pipe comprises one or more evanescent wave coatings applied to one or more surfaces of the light pipe. 8. An apparatus comprising: a light pipe comprising: a first optic configured to substantially homogenize pumplight via internal reflection and to inject the substantially homogenized pumplight into a planar waveguide of a planar waveguide (PWG) amplifier; and a cladding comprising second and third optics separated from one another by a first gap, the first gap forming a first area of reflection, the first area of reflection configured to: fold an optical beam and thereby redirect the optical beam into the planar waveguide, and reflect stray pumplight toward a first beam dump. 9. The apparatus of claim 8 , wherein the light pipe forms a pumplight aperture and an optical beam aperture that are configured to align with the planar waveguide. 10. The apparatus of claim 8 , wherein the light pipe comprises: a core comprising the first optic, the first optic configured to guide the pumplight along a guiding axis, the first optic also configured to deliver the substantially homogenized pumplight into the planar waveguide. 11. The apparatus of claim 8 , wherein the cladding of the light pipe further comprises: fourth and fifth optics separated from one another by a second gap, the second gap forming a second area of reflection, the second area of reflection configured to reflect stray pumplight toward a second beam dump. 12. The apparatus of claim 8 , wherein the light pipe comprises: at least two sets of substantially parallel reflective surfaces; and a core that comprises the first optic and that is located between the sets of reflective surfaces, the core configured to guide the pumplight along a guiding axis and deliver the substantially homogenized pumplight into the planar waveguide. 13. The apparatus of claim 8 , wherein the light pipe comprises one or more evanescent wave coatings applied to one or more surfaces of the light pipe. 14. A method comprising: generating a first optical beam using a master oscillator; generating pumplight using one or more laser diode pump arrays; generating a second optical beam based on the first optical beam and the pumplight using a planar waveguide (PWG) amplifier; using a first optic of a light pipe to substantially homogenize the pumplight via internal reflection and to inject the substantially homogenized pumplight into a planar waveguide of the PWG amplifier; and using a first area of reflection to fold the first optical beam and thereby redirect the first optical beam into the planar waveguide and to reflect stray pumplight toward a first beam dump, the first area of reflection formed by a first gap separating second and third optics in a cladding of the light pipe; wherein the second optical beam has a higher power than the first optical beam. 15. The method of claim 14 , wherein the light pipe comprises: a core comprising the first optic, the first optic configured to guide the pumplight along a guiding axis, the first optic configured to deliver the substantially homogenized pumplight into the planar waveguide. 16. The method of claim 14 , wherein the cladding of the light pipe further comprises: fourth and fifth optics separated from one another by a second gap, the second gap forming a second area of reflection, the second area of reflection configured to reflect stray pumplight toward a second beam dump. 17. The method of claim 14 , wherein the light pipe comprises: at least two sets of substantially parallel reflective surfaces; and a core that comprises the first optic and that is located between the sets of reflective surfaces, the core configured to guide the pumplight along a guiding axis and deliver the substantially homogenized pumplight into the planar waveguide. 18. An apparatus comprising: a light pipe comprising a first optic configured to pass pumplight and to inject the pumplight into a planar waveguide of a planar waveguide (PWG) amplifier; and the light pipe also comprising a cladding that comprises second and third optics separated from one another by a first gap, the first gap forming a first area of reflection, the first area of reflection configured to: fold an optical beam and thereby redirect the optical beam into the planar waveguide, and reflect stray pumplight toward a first beam dump. 19. The apparatus of claim 18 , wherein the light pipe comprises: a core comprising the first optic configured to guide the pumplight along a guiding axis, the first optic configured to deliver the pumplight into the planar waveguide. 20. An apparatus comprising: a light pipe configured to pass pumplight from one or more laser diode pump arrays and to inject the pumplight into a planar waveguide of a planar waveguide (PWG) amplifier; the light pipe also configured to fold an optical beam and thereby redirect the optical beam from a master oscillator into the planar waveguide; the light pipe further configured to scrape stray pumplight so that the stray pumplight is redirected away from the planar waveguide; wherein the light pipe comprises: a core comprising a first optic configured to guide the pumplight along a guiding axis, the first optic configured to deliver the pumplight into the planar waveguide; and a cladding comprising second and third optics separate