Retro-reflective sensor with multiple detectors

What is claimed is: 1. A photoelectric sensor system to detect objects in a protected field between a light source and a retro-reflecting target, the system comprising: a retro-reflective substrate operable to redirect a portion of light from an incident optical path to a reflected optical path that is substantially parallel with the incident path; and, an optical transceiver comprising: an emitter configured to generate an optical signal directed along the incident optical path; a first photo-detector element having a first detection surface configured to receive at least a portion of the generated optical signal incident along the reflected optical path and to detect a first pattern of light incident at the first detection surface; a second photo-detector element having a second detection surface disposed proximate the first detection surface, the second photo-detector element configured to receive a second optical signal and to detect a second light pattern of light incident at the second detection surface; and, a controller operably coupled to the first photo-detector element and to the second photo-detector element, and configured to generate a notification signal in response to determining that the incident optical path is obstructed between the emitter and the retro-reflective substrate based on the detected first and second light patterns, wherein the notification signal is further determined by: receiving a first signal count representative of an amount of light incident on the first detection surface; receiving a second signal count representative of an amount of light incident on the second detection surface; determining an excess gain ratio by dividing the first signal count by a detector threshold level, and, generating the notification signal based on the determined excess gain ratio, wherein the detector threshold level is determined based on the received second signal count. 2. The system of claim 1 , wherein the emitter further comprises a light source and a beam splitter to direct the generated optical signal through a lens and along the incident optical path. 3. The system of claim 2 , wherein the reflected optical path extends through the lens and is redirected by the beam splitter onto the first detection surface. 4. The system of claim 1 , wherein the generated optical signal is directed along the incident optical path through a first lens having a first optical axis, and the portion of the generated optical signal received along the reflected optical path passes through a second lens having a second optical axis, wherein the first optical axis is substantially parallel to the second optical axis. 5. The system of claim 4 , wherein the emitter is substantially aligned with the first optical axis, and the first photo-detector element is substantially aligned with the second optical axis, and the second detection surface is proximately adjacent to the first detection surface to receive optical signals that are incident on the second lens and not substantially parallel to the second optical axis. 6. The system of claim 1 , wherein the second detection surface comprises a plurality of detection areas disposed proximately adjacent to the first detection surface. 7. The system of claim 6 , wherein the plurality of detection areas are asymmetrically arranged about the first detection surface. 8. The system of claim 1 , wherein the determination that the incident optical path is obstructed is further based on a difference between a first number of pixels associated with the first detected light pattern and a second number of pixels associated with the second detected light pattern. 9. The system of claim 1 , wherein the first photo-detector element and the second photo-detector element have substantially co-planar detection surfaces. 10. The system of claim 1 , wherein the first photo-detector element and the second photo-detector element each comprise a plurality of photo-detectors arranged as an array of pixels on a semiconductor substrate. 11. The system of claim 1 , wherein the first photo-detector element and the second photo-detector element are formed on the same semiconductor substrate. 12. The system of claim 1 , further comprising a housing configured to contain the emitter, the first photo-detector element, the second photo-detector element, and the controller, and to support the first photo-detector element and the second photo-detector element in optical alignment with the retro-reflective substrate. 13. A photoelectric sensor system to detect objects in a protected field between a light source and a retro-reflecting target, the system comprising: an emitter configured to generate an optical signal directed along an incident optical path from the emitter to a retro-reflective substrate operable to redirect a portion of light from an incident optical path to a reflected optical path that is substantially parallel with from the incident path; a first photo-detector element having a first detection surface configured to receive at least a portion of the generated optical signal incident along the reflected optical path and to detect a first pattern of light incident at the first detection surface; a second photo-detector element having a second detection surface disposed proximate the first detection surface, the second photo-detector element configured to receive a second optical signal and to detect a second pattern of light incident at the second detection surface; and, a controller operably coupled to the first photo-detector element and to the second photo-detector element, and configured to generate a notification signal in response to determining that the incident optical path is obstructed between the emitter and the retro-reflective substrate based on the detected first and second light patterns, wherein the notification signal is further determined by: receiving a first signal count representative of an amount of light incident on the first detection surface; receiving a second signal count representative of an amount of light incident on the second detection surface; determining an excess gain ratio by dividing the first signal count by a detector threshold level; and, generating the notification signal based on the determined excess gain ratio, wherein the detector threshold level is determined based on the received second signal count. 14. The system of claim 13 , further comprising a polarizing filter through which pass the light incident on the first detection surface and the light incident on the second detection surface. 15. The system of claim 13 , wherein the emitter further comprises a light source and a beam splitter to direct the generated optical signal through a lens and along the incident optical path. 16. The system of claim 15 , wherein the reflected optical path extends through the lens and is redirected by the beam splitter onto the first detection surface. 17. The system of claim 13 , wherein the generated optical signal is directed along the incident optical path through a first lens having a first optical axis, and the portion of the generated optical signal received along the reflected optical path passes through a second lens having a second optical axis, wherein the first optical axis is substantially parallel from the second optical axis. 18. The system of claim 17 , wherein the emitter is substantially aligned with the first optical axis, and the first photo-detector element is substantially aligned with the second optical axis, and the second detection surface is proximately adjacent