Optical sensor with Tx/Rx aperture sharing element (ASE) to block detection of the received active signal

We claim: 1. An optical sensor, comprising: an outer gimbal that rotates around a first gimbal axis; an inner gimbal that rotates around a second gimbal axis orthogonal to the first gimbal axis to point an optical axis in a multi-dimensional space defined by said first and second gimbal axes; a common Tx/Rx telescope mounted on the inner gimbal along the optical axis; an off-gimbal detector responsive to light at a plurality of wavelengths in a detection band; an off-gimbal optical source that emits an optical transmit signal in a transmit band within the detection band at a fixed off-gimbal access point; a free-space optical path along the first and second gimbal axes to couple light from the common Tx/Rx telescope to the off-gimbal detector; an off-gimbal aperture sharing element (ASE) positioned in a common Tx/Rx aperture in the free-space optical path at a fixed angle to the free-space optical path, said ASE free-space coupling the optical transmit signal from the off-gimbal access point into the free-space optical path and to the common Tx/Rx telescope for transmission along the optical axis towards a scene, said common Tx/Rx telescope collecting both passive emissions within the detection band and a returned transmit signal in the transmit band from the scene along the optical axis, said ASE configured at the fixed angle to block the returned transmit signal and to direct the passive emissions to said off-gimbal detector to passively image the scene at a plurality of wavelengths in the detection band not including the returned transmit signal; and an absorber configured to absorb the returned transmit signal; wherein the transmitted optical transmit signal and the collected returned transmit signal and passive emissions are co-boresighted along the optical axis. 2. The optical sensor of claim 1 , wherein said common Tx/Rx telescope produces an intermediate image at a first field stop from received light, said free-space optical path includes gimbal optics that couple light across the first and second gimbal axes and off-gimbal focusing optics that relay the intermediate image of the scene to the off-gimbal detector, wherein the ASE is positioned off-gimbal in the focusing optics. 3. The optical sensor of claim 2 , wherein the off-gimbal focusing optics include one or more optical elements to re-image the intermediate image from the telescope at a second field stop and a plurality of optical elements that relay the intermediate image from the second field stop to the off gimbal-detector, wherein the ASE is positioned within the plurality of optical elements that relay the intermediate image at a position at which any structure or optical imperfections of the ASE are not imaged at the detector. 4. The optical sensor of claim 1 , wherein one or more off-gimbal optical sources emit light at a plurality of transmission wavelengths within the transmit band, wherein said ASE couples the light at the plurality of transmission wavelengths to the common Tx/Rx telescope and couples light received by the common Tx/Rx telescope at wavelengths other than the plurality of transmission wavelengths to the off-gimbal detector to passively image the scene at wavelengths not including the plurality of transmission wavelengths. 5. The optical sensor of claim 1 , further comprising a guided munition on which the optical sensor is mounted. 6. The optical sensor of claim 1 , further comprising an autonomous vehicle on which the optical sensor is mounted. 7. The optical sensor of claim 1 , further comprising control circuitry coupled to the off-gimbal detector, said control circuitry configured to process the passive emissions detected by the detector to generate a guidance command to control the inner and outer gimbals to point the optical axis. 8. The optical sensor of claim 1 , further comprising control circuitry coupled to the off-gimbal detector and the off-gimbal optical source, said control circuitry configured to process the passive emissions detected the detector to detect a target in the scene and to then activate the off gimbal optical source to emit the optical transmit signal to engage the target. 9. The optical sensor of claim 1 , wherein the ASE comprises a dichroic beam splitter that at the fixed angle separates light within the transmit band from light at wavelengths other than the transmit band, wherein said dichroic beam splitter is positioned at the fixed angle to direct light from the off-gimbal optical source within the transmit band into the free-space optical path and to direct light received by the common Tx/Rx telescope at wavelengths other than within the transmit band to the off-gimbal detector. 10. The optical sensor of claim 9 , wherein the dichroic beam splitter reflects light from the off-gimbal optical source within the transmit band and transmits light at wavelengths within the detection band other than within the transmit b. 11. The optical sensor of claim 1 , wherein the scene emits unpolarized light including first and second polarization states, wherein the off-gimbal optical source is configured to emit the optical transmit signal in the first polarization state, wherein the ASE comprises a polarization beam splitter at the fixed angle that directs the optical transmit signal in only the first polarization state into the free-space optical path, directs light received by the common Tx/Rx telescope in only the second polarization state to the off-gimbal detector and blocks light received in the first polarization state from the off-gimbal detector. 12. The optical sensor of claim 11 , wherein the polarization beam splitter reflects light in the first polarization state and transmits light in the orthogonal polarization state. 13. An optical sensor, comprising: an outer gimbal that rotates around a first gimbal axis; an inner gimbal that rotates around a second gimbal axis orthogonal to the first gimbal axis to point an optical axis in a multi-dimensional space defined by said first and second gimbal axes; a common Tx/Rx telescope mounted on the inner gimbal along the optical axis, said common Tx/Rx telescope receiving light to produce an intermediate image; an off-gimbal detector responsive to light at a plurality of wavelengths in a detection band; an off-gimbal optical source that emits an optical transmit signal in a transmit band within the detection band at a fixed off-gimbal access point; a free-space optical path including gimbal optics that route light along the first and second gimbal axes and off-gimbal focus optics that relay the intermediate image to the off-gimbal detector; a an off-gimbal aperture sharing element (ASE) positioned in a common Tx/Rx aperture in the free-space optical path at a fixed angle to the free-space optical path, said ASE free-space coupling the optical transmit signal from the off-gimbal access point into the free-space optical path and to the common Tx/Rx telescope for transmission along the optical axis, towards a scene, said common Tx/Rx telescope collecting both passive emissions within the detection band and a returned transmit signal in the transmit band from the scene along the optical axis, said ASE configured at the fixed angle to block the returned transmit signal and to direct the passive emissions to said off-gimbal detector to passively image the scene at a plurality of wavelengths in the detection band not including the returned transmit signal; an absorber configured to absorb the returned transmit signal; and control circuitry coupled to the off-gimbal detector, said control circuitry configured to process the passive emission to generate a guidance command to control the inner and