Light ranging device with electronically scanned emitter array and synchronized sensor array

What is claimed is: 1. A solid state optical system comprising: a light transmission module including a transmitter layer that includes a plurality of light emitters aligned to project light into a field external to the optical system according to an illumination pattern; a light sensing module including a sensor layer that includes a plurality of photosensors configured to detect photons emitted from the plurality of light emitters and reflected from surfaces within the field external to the optical system, wherein each photosensor in the plurality of photosensors senses is paired with a corresponding light emitter in the plurality of light emitters; emitter array firing circuitry coupled to the plurality of light emitters and configured to electronically scan the emitter array by executing a plurality of emission cycles where, during each emission cycle the emitter firing circuitry activates only a subset of light emitters at a time until the illumination pattern is generated; and sensor array 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 so that each photosensor in the plurality of photosensors can be readout through one emission cycle. 2. The solid state optical system of claim 1 wherein a one-to-one correspondence exists between each photosensor in the plurality of photosensors and each corresponding light emitter in the plurality of light emitters. 3. The solid state optical system of claim 1 wherein a field of view for each light emitter in the plurality of light emitters matches a field of view for its corresponding photosensor in the plurality of photosensors. 4. The solid state optical system of claim 3 wherein the light transmission module further includes a bulk transmitter optic and the light sensing module further includes a bulk receiver optic. 5. The solid state optical system of claim 4 wherein the plurality of light emitters is arranged in a two-dimensional array having first dimensions and configured to project discrete beams of light through the bulk transmitter optic into a field external to the optical system; the plurality of photosensors is arranged in a two-dimensional array having second dimensions and configured to detect photons reflected from surfaces in the field after the photons pass through the bulk receiver optic; and the combination of first dimensions, second dimensions, bulk transmitter optics and bulk receiver optics is designed such that a field of view of each emitter column going through bulk transmitter optic is significantly the same as a field of view of a corresponding photosensor column going through the bulk receiver optic. 6. The solid state optical system of claim 5 wherein the plurality of light emitters and the plurality of photosensors are activated by column or by row. 7. The solid state optical system of claim 1 wherein each photosensor in the plurality of photosensors includes a plurality of SPADS, and each light emitter in the plurality of light emitters is a vertical-cavity surface-emitting laser (VCSEL). 8. The solid state optical system of claim 1 wherein: the light transmission module is a first light transmission module, the transmitter layer is a first transmitter layer, and the plurality of light emitters is a first plurality of light emitters; the system further comprising a second light transmission module including a second transmitter layer that includes a second plurality of light emitters; and the first and second pluralities of light emitters are aligned to project discrete beams of light into a field external to the optical system according to a first illumination pattern and a second illumination pattern, respectively, where the first and second illumination patterns are aligned such that one discrete beam from the first illumination pattern and one discrete beam from the second illumination pattern falls within the field-of-view of each photosensor in the plurality of photosensors. 9. A solid state optical system for performing distance measurements, the solid state optical system comprising: a light emission system comprising a bulk transmitter optic, and a two-dimensional array of light emitters arranged according to an illumination pattern and aligned to project discrete beams of light through the bulk transmitter optic into a field ahead of the optical system; a light detection system comprising a bulk receiver optic and a photosensor layer including a two-dimensional array of photosensors configured to detect photons emitted from the two-dimensional array of light emitters and reflected from surfaces within the field after passing through the bulk receiver optic, wherein each photosensor in the two-dimensional array of photosensors senses light from a different light emitter in the two-dimensional array of light emitters; emitter array firing circuitry coupled to the two-dimensional array of light emitters and configured to activate only a subset of light emitters at a time; sensor array readout circuitry coupled to the two-dimensional array of photosensors and configured to synchronize the readout of individual photosensors within the array concurrently with the firing of corresponding light emitters so that each light emitter in the array of light emitters can be activated and each photosensor in the array of photosensors can be readout through one emission cycle; and a micro-optic channel array disposed between the two-dimensional array of light emitters and the bulk transmitter optic, the micro-optic channel array defining a plurality of micro-optic transmitter channels, each micro-optic transmitter channel including a micro-optic lens spaced apart from a light emitter from the two-dimensional array of light emitters with the micro-optic lens being configured to receive a light cone from the light emitter in its respective transmitter channel and generate a reduced-size spot image of the light emitter at a focal point displaced from the light emitter at a location between the light emitter and the bulk transmitter optic. 10. The solid state optical system of claim 9 wherein a field of view for each light emitter represents a non-overlapping field of view within the field and matches a field of view for its corresponding photosensor. 11. The solid state optical system of claim 9 wherein the emitter array firing circuitry activates subsets of light emitters by one column or one row at a time and the sensor array readout circuitry synchronizes the readout of corresponding photosensors by one column or one row at a time. 12. The solid state optical system of claim 11 wherein each photosensor in the array of photosensors includes an array of SPADS, and each light emitter is a vertical-cavity surface-emitting laser (VCSEL). 13. The solid state optical system of claim 11 wherein the emitter array firing circuitry sequentially activates columns or rows of light emitters in a single direction throughout each emission cycle. 14. The solid state optical system of claim 9 wherein the light detection system further comprises an aperture layer including a plurality of apertures, and wherein the aperture layer and photosensor layer are arranged to form a plurality of sense channels arranged in a sensing pattern that corresponds to the illumination pattern where, for each sense channel in the plurality of sense channels, a sensing area for the photosensor in the sense channel is larger than an area of its respective aperture. 15. The solid state optical system of clai