Cross-talk mitigation using wavelength switching

What is claimed is: 1. A lidar system comprising: a lighting module configured to (i) select a wavelength from among a plurality of wavelength values, for a particular time period, and (ii) concurrently emit a plurality of beams of light, including emit light in a first one of the plurality of beams at the selected wavelength and apply a respective offset to the selected wavelength for each remaining beam in the plurality of beams, wherein the lighting module emits light in the first one of the plurality of beams at different wavelengths during at least two adjacent periods of time; a scanner configured to direct the emitted light to illuminate different regions within a field of regard of the lidar system, to scan the field of regard of the lidar system; and a receiver module including a plurality of single-photon detectors, each for detecting a respective one of the plurality of beams and configured to (i) receive a light signal, (ii) determine whether the received light signal includes light at a wavelength of the corresponding one of the plurality of beams, emitted by the lighting module and scattered by a remote target, and (iii) generate a respective row of pixels. 2. The lidar system of claim 1 , wherein the lighting module includes: a light source, and a filter electronically tunable to one of the plurality of wavelength values. 3. The lidar system of claim 1 , wherein the lighting module comprises a plurality of laser diodes corresponding, respectively, to the plurality of wavelength values, wherein each laser diode is configured to produce light at a particular wavelength of the plurality of wavelength values. 4. The lidar system of claim 1 , wherein the receiver module includes: a wavelength filter adjustable to receive the wavelength selected by the lighting module. 5. The lidar system of claim 4 , wherein the wavelength filter is electronically tunable to the wavelength selected by the lighting module. 6. The lidar system of claim 4 , wherein the wavelength filter includes one or more passive filters mechanically adjusted to the wavelength selected by the lighting module. 7. The lidar system of claim 1 , further comprising a controller to control wavelength selection at the lighting module and the receiver. 8. The lidar system of claim 7 , wherein the controller is configured to select a new wavelength according to a predefined schedule. 9. The lidar system of claim 7 , wherein the controller is configured to select a new wavelength in response to detecting a cross-talk event. 10. A method for scanning a field of regard of a lidar system, the method comprising: selecting a first wavelength from among a plurality of wavelength values; emitting, by a lighting module, light at the selected first wavelength during a first time period; detecting a triggering event for changing the first wavelength, including detecting that a scan of the entire field of regard of the lidar system, corresponding to one frame of pixels, has been completed; in response to detecting the triggering event, selecting a second wavelength from among the plurality of wavelength values; emitting, by the lighting module, light at the selected second wavelength during a second time period; receiving light signals during the first time period and the second time period; determining whether the received light signal includes the light emitted by the lighting module and scattered by a remote target, based at least in part on the wavelength used by the lighting module during the corresponding time period; and using the received light to generate pixels only if it is determined that the received light signal includes the light emitted by the lighting module during the corresponding time period. 11. The method of claim 10 , wherein the second wavelength is selected from among the plurality of wavelength values randomly. 12. The method of claim 10 , wherein the second wavelength is selected from among the plurality of wavelength values in accordance with an order assigned to wavelength values in the plurality of wavelength values. 13. The method of claim 10 , wherein emitting light at the selected first wavelength includes using a light source and a filter electronically tuned to the first wavelength, and emitting light at the selected second wavelength includes using the light source and the filter electronically tuned to the second wavelength. 14. The method of claim 10 , wherein emitting light at the selected first wavelength and at the selected second wavelength includes using a first laser diode configured to produce light at the first wavelength and a second laser diode configured to produce light at the second wavelength, respectively. 15. The method of claim 10 , wherein determining whether the received light signal includes the light emitted by the lighting module includes electronically tuning a wavelength filter to receive the wavelength selected by the lighting module. 16. The method of claim 10 , wherein determining whether the received light signal includes the light emitted by the lighting module includes mechanically adjusting a wavelength filter to receive the wavelength selected by the lighting module. 17. An autonomous vehicle comprising: one or more components configured to maneuver the autonomous vehicle; a lidar system configured to generate a point cloud representing objects within a field of regard of the lidar system, the lidar system including: a lighting module configured to emit pulses of light at different wavelengths during different respective periods of time; a scanner configured to direct the emitted pulses of light to illuminate respective regions within the field of regard of the lidar system; and a receiver module configured to receive light signals and generate pixels for the point cloud based on the received light signals only when a received light signal includes a wavelength at which the lighting module emitted a pulse of light during a corresponding period of time; and a vehicle controller configured to (i) analyze the point cloud, (ii) detect a cross-talk event based on analyzing the point cloud, and (iii) in response to detecting the cross-talk event, provide a command to the lidar system to switch to a different wavelength, the vehicle controller further configured to provide control signals to the one or more components to maneuver the autonomous vehicle, based at least in part on the point cloud generated from the lidar system. 18. A method for scanning a field of regard of a lidar system, the method comprising: selecting a first wavelength from among a plurality of wavelength values; emitting, by a lighting module, light at the selected first wavelength during a first time period; detecting a triggering event for changing the first wavelength, including detecting that a scan of one horizontal scan line has been completed; in response to detecting the triggering event, selecting a second wavelength from among the plurality of wavelength values; emitting, by the lighting module, light at the selected second wavelength during a second time period; receiving light signals during the first time period and the second time period; determining whether the received light signal includes the light emitted by the lighting module and scattered by a remote target, based at least in part on the wavelength used by the lighting module during the corresponding time period; and using the received light to generate pixels only if it is determined that the received light signal includes the light emitted by the lighting module dur