Light ranging device having an electronically scanned emitter array

What is claimed is: 1. A light ranging device comprising: a semiconductor emitter array comprising a two-dimensional array of light emitters aligned to project discrete beams of light into a field external to the device according to an illumination pattern in which each discrete beam in the illumination pattern represents a non-overlapping field-of-view within the field, the two-dimensional array of light emitters comprising a plurality of emitter banks aligned side-by-side, wherein each emitter bank includes a subset of emitters in the two-dimensional array of light emitters and is independently operable to emit light from its subset of emitters; emitter array driving circuitry coupled to the plurality of emitter banks, the emitter array driving circuitry configured to activate one emitter bank in the plurality of emitter banks at a time according to a firing sequence in which the subset of emitters in the activated bank are fired; a plurality of pixels operable to detect photons emitted from the two-dimensional array of light emitters after being reflected from surfaces within the field; and sensor array readout circuitry coupled to the plurality of pixels and configured to, concurrently with the activation of each bank of light emitters, synchronize the readout of individual pixels within the plurality of pixels corresponding to the emitters in the activated emitter bank. 2. The light ranging device of claim 1 wherein a field of view for each light emitter in the plurality of light emitters is aligned with a field of view for a corresponding pixel in the plurality of pixels. 3. The light ranging device of claim 1 wherein each pixel in the plurality of pixels comprises a plurality of single-photon avalanche diodes (SPADs). 4. The light ranging device of claim 1 further comprising an image-space telecentric bulk transmitter optic and an image-space telecentric bulk receiver optic disposed adjacent to the bulk transmitter optic, wherein the semiconductor emitter array is aligned to project light through the bulk transmitter optic and bulk receiver optic collects light from the field and projects the collected light toward the plurality of pixels. 5. The light ranging device of claim 4 wherein the two-dimensional array of light emitters has first dimensions and is configured to project discrete beams of light through the bulk transmitter optic into the field external to the device; the plurality of pixels 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 optic and bulk receiver optic 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 pixel column going through the bulk receiver optic. 6. The light ranging device of claim 1 wherein the plurality of light emitters are arranged in a two-dimensional array and the emitter array driving circuitry activates subsets of emitters by column or by row. 7. The light ranging device of claim 1 wherein the device computes distances to objects in the field based on an elapsed time between emitted light pulses from the plurality of light emitters and reflections of the pulses detected by pixels in the plurality of pixels. 8. The light ranging device of claim 1 wherein the device can measure a Doppler shift of emitted light pulses detected by the pixels and can compute a relative velocity between the light sensing module and a reflecting surface based on measured Doppler shifts. 9. The light ranging device of claim 1 wherein the device is configured to estimate reflectivity of a reflecting surface based on a strength of pulses detected by the pixels in the plurality of pixels. 10. The light ranging device of claim 1 wherein the device is configured to determine if a reflecting surface is a hard or diffuse material based on a shape of a detected pulse. 11. A light ranging device comprising: an image-space telecentric bulk emitter optic; a two-dimensional array of light emitters aligned to project beams of light through the bulk emitter optic into a field external to the device according to an illumination pattern in which each beam in the illumination pattern represents a non-overlapping field-of-view within the field, the two-dimensional array of light emitters comprising a plurality of emitter banks, wherein each emitter bank includes a subset of emitters in the two-dimensional array of light emitters and is independently operable to emit light from its subset of emitters; emitter array driving circuitry coupled to the plurality of emitter banks, the emitter array driving circuitry configured to activate one emitter bank in the plurality of emitter banks at a time according to a firing sequence in which, during one emission cycle, each emitter bank in the plurality of emitter banks is activated to project a pulse of light into the field; an image-space telecentric bulk imaging optic; a plurality of pixels operable to detect photons emitted from the two-dimensional array of light emitters and received through the bulk imaging optic after being reflected from surfaces within the field, wherein each pixel in the plurality of pixels comprises a plurality of single-photon avalanche diodes (SPADs) and each is aligned to sense light from a corresponding light emitter in the plurality of light emitters; an optical filter disposed between the bulk imaging optic and the plurality of pixels, wherein the optical filter allows a band of wavelengths of light, including an operating wavelength of the array of light emitters, to pass through the optical filter while blocking light outside the band from reaching the plurality of pixels; and sensor array readout circuitry coupled to the plurality of pixels and configured to, concurrently with the activation of each bank of light emitters, synchronize the readout of individual pixels within the plurality of pixels corresponding to the emitters in the activated emitter bank. 12. The light ranging device of claim 11 wherein the two-dimensional array of light emitters comprises a plurality of vertical cavity surface emitting lasers (VCSELs). 13. The light ranging device of claim 11 wherein each bank of emitters is disposed on a separate integrated circuit. 14. The light ranging device of claim 11 wherein a plurality of banks of emitters are disposed on a single integrated circuit. 15. The light ranging device of claim 11 wherein: each bank in the plurality of banks includes x columns and the emitter array driving circuitry is configured to, during a single emission cycle, activate each bank in the plurality of banks x times; and each time a particular bank is activated in the single emission cycle, the sensor array readout circuitry is synchronized with the emitter array driving circuitry to readout a different column in the sensor array that corresponds to the activated bank. 16. The light ranging device of claim 11 wherein the system computes distances to objects in the field based on an elapsed time between emitted light pulses from the plurality of light emitters and reflections of the pulses detected by pixels in the plurality of pixels. 17. A light ranging device comprising: a light transmission module comprising: an image-space telecentric bulk emitter optic; a semiconductor emitter array comprising a two-dimensional array of light emitters aligned to project beams of ligh