Electronically scanned light ranging device having multiple emitters sharing the field of view of a single sensor

What is claimed is: 1. A solid state optical system for performing distance measurements, the solid state optical system comprising: a first illumination source comprising a first plurality of light emitters aligned to project discrete, nonoverlapping beams of light into a field external to the optical system according to a first illumination pattern; a second illumination source comprising a second plurality of light emitters aligned to project discrete, nonoverlapping beams of light into the field according to a second illumination pattern having a same size and geometry as the first illumination pattern; and a light detection module including a plurality of photosensors configured to detect photons emitted from the first and second illumination sources and reflected from surfaces within the field, wherein the plurality of photosensors are aligned according to a sensing pattern that has substantially the same size and geometry as the first and second illumination patterns such that each photosensor in the plurality of photosensors has a field-of-view that overlaps with a field-of-view of one emitter from the first plurality of light emitters and one emitter from the second plurality of light emitters; wherein the first and second pluralities of light emitters and the plurality of photosensors operate in synchronization such that when one or more light emitters are activated, a corresponding one or more of the photosensors are read. 2. The optical system set forth in claim 1 further comprising emitter firing circuitry coupled to the first and second pluralities of light emitters and configured to execute a plurality of image capture periods where, for each image capture period the emitter firing circuitry sequentially fires a subset of emitters from the first plurality of light emitters followed by a subset of emitters from the second plurality of light emitters until the first and second illumination patterns are generated. 3. The optical system set forth in claim 2 wherein, for each image capture period, each subset of emitters from the first plurality of light emitters fired by the emitter firing circuitry represents a distinct portion of the first illumination pattern and each subset of emitters from the second plurality of light emitters fired subsequent to the subset of emitters from the first plurality of light emitters represents a distinct portion of the second illumination pattern that corresponds to the distinct portion of the first illumination pattern. 4. The optical system set forth in claim 3 further comprising sensor readout circuitry coupled to the plurality of photosensors and configured to synchronize the readout of individual photosensors within the plurality of photosensors concurrently with the firing of corresponding light emitters from the first and second light plurality of light emitters. 5. The optical system set forth in claim 1 wherein the plurality of photosensors is disposed between the first and second pluralities of light emitters. 6. The optical system set forth in claim 1 wherein each discrete spot in the first illumination pattern and its corresponding discrete spot in the second illumination pattern represent non-overlapping portions of the field of view of the corresponding sense channel. 7. The optical system set forth in claim 6 wherein the light detection module further includes an aperture layer including a plurality of apertures, the aperture layer and the plurality of photosensors being arranged to form a plurality of sense channels with each sense channel in the plurality of sense channels including one photosensor from the plurality of photosensors, a first aperture in the aperture layer that defines a first field of view for the photosensor in the channel and a second aperture in the aperture layer that defines a second field of view for the photosensor in the channel, wherein the first field of view is aligned with a field of view of an emitter in the first illumination source and the second field of view is aligned with a field of view of an emitter in the second illumination source. 8. The optical system set forth in claim 7 wherein each sense channel includes a first micro-lens aligned with the first aperture and a second micro-lens aligned with the second aperture. 9. The optical system set forth in claim 1 wherein each discrete spot in the first illumination pattern overlaps with and is substantially the same size as its corresponding spot in the second illumination pattern. 10. The optical system set forth in claim 1 further comprising a third illumination source comprising a third plurality of light emitters aligned to project discrete beams of light into a field external to the optical system according to a third illumination pattern having a same size and geometry as the first illumination pattern; and wherein the plurality of photosensors is further configured to detect photons emitted from the third illumination source and the third plurality of light emitters operates in synchronization with the first and second plurality of light emitters and the plurality of photosensors such that when one or more light emitters are activated, a corresponding one or more of the photosensors are read. 11. The optical system set forth in claim 1 wherein the first and second pluralities of light emitters and the plurality of photosensors operate in synchronization such that when a column of light emitters are activated, a corresponding column of the photosensors are read. 12. A solid state optical system for performing distance measurements, the solid state optical system comprising: a first light emission module including a first bulk transmitter optic and a first illumination source comprising a first plurality of light emitters aligned to project discrete beams of light through the first bulk transmitter optic into a field external to the optical system according to a first illumination pattern; a second light emission module including a second bulk transmitter optic and a second illumination source comprising a second plurality of light emitters aligned to project discrete beams of light through the second bulk transmitter optic into the field according to a second illumination pattern having a same size and geometry as the first illumination pattern; and a light detection module including a bulk receiver optic, an aperture layer including a plurality of apertures, and a photosensor layer including a plurality of photosensors configured to detect photons emitted from the first and second illumination sources and reflected from surfaces within the field through the bulk receiver optic, wherein the aperture layer and the photosensor layer are arranged to form a plurality of sense channels, each sense channel including an aperture from the aperture layer and a photosensor from the photosensor layer and having a field-of-view that overlaps with a field-of-view of one emitter from the first plurality of light emitters and one emitter from the second plurality of light emitters; wherein the first and second pluralities of light emitters and the plurality of photosensors operate in synchronization such that when one or more light emitters are activated, a corresponding ones of the photosensors are read. 13. The optical system set forth in claim 12 further comprising: emitter firing circuitry coupled to the first and second pluralities of light emitters and configured to execute a plurality of image capture periods where, for each image capture period the emitter firing circuitry sequentially fires a subset of emitters from the first plurality of light emitters followed by a subset of emitters from the second pluralit