Wavelength division multiplexed LiDAR

The invention claimed is: 1. A method of operating a chip-scale wavelength division multiplexed LiDAR comprising: providing a multiwavelength optical signal; directing the multiwavelength optical signal via a distribution network to an optical phased array, said optical phased array including emitter elements and phase shifters; separating the multiwavelength optical signal into its component wavelengths through the effect of at least one reflective grating or transmission grating receiving the multiwavelength optical signal from the emitter elements and emitting individual component wavelengths as individual beams in an individual direction toward a scene according to their wavelength, where said individual beam directions span an emission plane; and steering the individual beams through the effect of the phase shifters, said individual beams collectively steered about an axis substantially parallel to the emission plane. 2. The method of claim 1 further comprising: receiving at least a portion of the individual beams after the portion of the individual beams are reflected by an object in the scene. 3. The method of claim 2 further comprising: determining a distance between the object and the chip-scale wavelength division multiplexed LiDAR. 4. A wavelength division multiplexed LiDAR system comprising: a substrate; a multiwavelength light source formed on the substrate; an active optical phased array formed on the substrate, said active optical phased array including phase shifters and emitter elements; an optical splitter network formed on the substrate, said optical splitter network optically connecting the multiwavelength light source to the active optical phased array; and a plurality of transmitter/receiver (TX/RX) units formed on the substrate, wherein each individual TX/RX unit is configured to generate an individual wavelength of the multiwavelength light source and to detect that same individual wavelength. 5. The wavelength division multiplexed LiDAR system of claim 4 further comprising a wavelength multiplexer interposed between the plurality of TX/RX units and the optical splitter network, said multiplexer configured to combine the individual wavelengths of the TX/RX units into a multiwavelength beam and provide that multiwavelength beam to the optical splitter network. 6. The wavelength division multiplexed LiDAR system of claim 5 further configured to separate and directionally emit the multiwavelength beam according to its wavelength through the effect of the emitter elements and to orthogonally steer the directionally emitted light by adjusting the phase shifters. 7. The wavelength division multiplexed LiDAR system of claim 6 wherein the directionally emitted and orthogonally steered light is backscattered by an object, received by selective emitters of the active optical phased array and directed to a respective TX/RX unit based upon its wavelength. 8. The wavelength division multiplexed LiDAR system of claim 7 further comprising a separate transmitter optical phased array that emits light and a separate receiver optical phased array that receives the backscattered light. 9. The wavelength division multiplexed LiDAR system of claim 8 wherein the receiver optical phased array directs received light to a modulator and into a wavelength demultiplexer for subsequent detection by a plurality of detectors, one for each wavelength emitted. 10. A wavelength division multiplexed LiDAR system comprising: a substrate; a light source integrated with the substrate providing a multiwavelength optical signal; an active optical phased array formed on the substrate, said active optical phased array including phase shifters and emitter elements; an optical splitter network formed on the substrate, said optical splitter network optically connecting the multiwavelength optical signal to the active optical phased array; and driver electronics configured to control phase shifts applied by the phase shifters to steer individual beams exhibiting different wavelengths emitted in individual directions that span an emission plane such that said individual beams are collectively steered about an axis substantially parallel to the emission plane. 11. The wavelength division multiplexed LiDAR system of claim 10 further configured to: receive at least a portion of the individual beams after the portion of the individual beams are reflected by an object. 12. The wavelength division multiplexed LiDAR system of claim 11 further configured to: determine a distance between the object and the wavelength division multiplexed LiDAR system.