Dual mode optical and RF reflector

What is claimed is: 1. A dual-mode optical and radio frequency (RF) reflector comprising: a mirror having a reflective surface including a first zone having a first surface precision, a remainder of the reflective surface outside of the first zone having a second surface precision that is substantially lower than the first surface precision, wherein the mirror is positioned to receive an RF signal and an optical signal, the RF signal and the optical signal having a common phase center, and wherein the mirror is configured to collimate and reflect the RF signal from the reflective surface and collimate and reflect the optical signal from the first zone as co-aligned plane wave signals with the common phase center. 2. The dual-mode optical and RF reflector of claim 1 wherein the reflective surface has an off-axis parabolic shape. 3. The dual-mode optical and RF reflector of claim 2 wherein the first zone is substantially centrally located in the reflective surface. 4. The dual-mode optical and RF reflector of claim 3 wherein the first zone has a diameter of approximately 250 millimeters. 5. The dual-mode optical and RF reflector of claim 2 wherein the first zone is offset relative to a center of the reflective surface. 6. The dual-mode optical and RF reflector of claim 1 wherein the mirror includes a first layer of aluminum and a second layer nickel disposed on the first layer of aluminum. 7. The dual-mode optical and RF reflector of claim 1 wherein the mirror is made from heat-treated and thermally stabilized aluminum. 8. The dual-mode optical and RF reflector of claim 1 wherein the first surface precision is in a range of λ/2 to λ/10 RMS surface deviation, λ being the wavelength of a surface metrology test signal in a range of approximately 630 nm to 635 nm. 9. A multi-mode alignment test system comprising: a test chamber; a multi-mode signal emitter configured to emit at least a radio frequency (RF) signal and an optical signal, the RF signal and the optical signal having a common phase center; and a dual-mode optical and RF reflector including a mirror having a reflective surface configured to collimate and reflect the RF signal into a test volume within the test chamber, the mirror including a zone within the reflective surface and corresponding to a portion of the reflective surface that is less than an entirety of the reflective surface, a remainder of the reflective surface outside of the zone having a surface precision that is lower than a surface precision of the zone, the zone being configured to collimate and reflect the optical signal into the test volume, wherein the reflective surface and the zone within the reflective surface are configured to collimate and reflect the RF signal and the optical signal as co-aligned plane wave signals with the common phase center. 10. The multi-mode alignment test system of claim 9 wherein the multi-mode signal emitter is configured to emit the RF signal and the optical signal coincident with one another. 11. The multi-mode alignment test system of claim 9 wherein the mirror has a bi-metallic structure. 12. The multi-mode alignment test system of claim 11 , wherein the mirror includes an aluminum substrate and a layer of nickel disposed on the aluminum substrate, the layer of nickel being polished to provide the reflective surface. 13. The multi-mode alignment test system of claim 9 wherein the dual-mode optical and RF reflector has an off-axis parabolic shape. 14. The multi-mode alignment test system of claim 9 wherein the zone is approximately centrally located within the reflective surface. 15. The multi-mode alignment test system of claim 9 wherein the zone is offset from a center of the reflective surface. 16. The multi-mode alignment test system of claim 15 wherein the test system is configured for testing an article including an optical system having a central obscuration, and wherein a size and a decenter of the zone is selected such that optical signal reflected from the zone is not blocked by the central obscuration.