Offset illumination using multiple emitters in a fluorescence imaging system is described. A system includes an emitter for emitting pulses of electromagnetic radiation and an image sensor comprising a pixel array for sensing reflected electromagnetic radiation. The emitter comprises a first emitter and a second emitter for emitting different wavelengths of electromagnetic radiation. The system is such that at least a portion of the pulses of electromagnetic radiation emitted by the emitter comprises electromagnetic radiation having a wavelength from about 770 nm to about 790 nm.

A light detection and ranging (LIDAR) device including a laser source configured to provide a transmit beam, the laser source being positioned with a first offset relative to a reference line, a transmit/receive (T/R) interface configured to pass the transmit beam and reflect received light towards a detector, the T/R interface being positioned with a second offset relative to the reference line, and a lens positioned between the laser source and the T/R interface, the lens being positioned with a third offset relative to the reference line, wherein the laser source and the lens, as positioned, are configured to steer the transmit beam.

A light detection and ranging (LIDAR) device including a plurality of illumination sources, each of the plurality of illumination sources configured to emit illumination light, an optical scanning device disposed in an optical path of the plurality of illumination sources, the optical scanning device configured to oscillate about a first axis to redirect the illumination light emitted by the plurality of illumination sources from the LIDAR device into a three-dimensional (3-D) environment, a plurality of photosensitive detectors, each of the plurality of photosensitive detectors configured to detect a respective portion of return light reflected from the 3-D environment when illuminated by a respective portion of the illumination light, and a scanning mechanism configured to rotate the optical scanning device about a second axis orthogonal to the first axis.

A light detection and ranging (LIDAR) device including a plurality of laser sources configured to provide a plurality of transmit beams, each laser source being positioned with a respective offset of a first plurality of offsets relative to a reference line, a plurality of transmit/receive (T/R) interfaces configured to pass the plurality of transmit beams and reflect received light towards a plurality of detectors, each T/R interface being positioned with a respective offset of a second plurality of offsets relative to the reference line, and a plurality of lenses positioned between the plurality of laser sources and the plurality of T/R interfaces, each lens being positioned with a respective offset of a third plurality of offsets relative to the reference line, wherein the plurality of laser sources and the plurality of lenses, as positioned, are configured to provide beam-steering of the plurality of transmit beams.

Various measurement systems and methods are disclosed to enable characterizing the optical characteristics of light beams emitted by a light detection and range finding (LIDAR) system or sensor and evaluating the range finding function of user selected lidar channels while the lidar operates under a real operational condition and is exposed to a range of user defined environmental conditions.

A LiDAR system includes a light source and an arrayed micro-optic configured to receive light from the light source so as to produce and project a two-dimensional array of light spots on a scene. The LiDAR system also includes receiver optics having an array of optical detection sites configured so as to be suitable for establishing a one-to-one correspondence between light spots in the two-dimensional array and optical detection sites in the receiver optics. The LiDAR system further includes a birefringent prism and a lens. The LiDAR system may also include a mask placed in the light path between the birefringent prism and the receiver optics. Alternatively, the LiDAR system may include a controller programmed to activate or deactivate each optical detection site.

The technology disclosed relates to determining positional information of an object in a field of view. In particular, it relates to measuring, using a light sensitive sensor, one or more differences in an intensity of returning light that is (i) emitted from respective directionally oriented non-coplanar light sources of a plurality of directionally oriented light sources that have at least some overlapping fields of illumination and (ii) reflected from the target object as the target object moves through a region of space monitored by the light sensitive sensor, and recognizing signals in response to (i) positional information of the target object determined based on, a first position in space at a first time t0 and a second position in space at a second time t1 sensed using the measured one or more differences in the intensity of the returning light and (ii) a non-coplanar movement of the target object.

Described examples include an apparatus having a phase light modulator. The apparatus also has a first light source configured to direct a first light beam to the phase light modulator, the phase light modulator configured to provide a first modulated light beam directed to a first field of view. The apparatus also has a second light source configured to direct a second light beam to the phase light modulator, the phase light modulator configured to provide a second modulated light beam directed to a second field of view. The apparatus also has a first light detector configured to detect the first modulated light beam as reflected from the first field of view; and a second light detector configured to detect the second modulated light beam as reflected from the second field of view.

A distance measuring device according to one embodiment includes a light emitter, a first light receiver, and a second light receiver. The light emitter includes a light source. The light source emits an optical signal. The first light receiver includes a first sensor and a first optical system. The first sensor includes first pixels. The first optical system is configured to guide a reflected light of the optical signal emitted from the light emitter to the first sensor. The second light receiver includes a second sensor and a second optical system. The second sensor includes second pixels. The second optical system is configured to guide the reflected light to the second sensor.

The present disclosure relates to light detection and ranging (lidar) systems, lidar-equipped vehicles, and associated methods. An example method includes causing a firing circuit to trigger emission of an initial group of detection pulses from at least one light-emitter device of a lidar system in accordance with an initial set of one or more light-emission parameters. The method also includes causing the firing circuit to trigger emission of one or more test pulses and receiving, from at least one detector, information indicative of one or more return test pulses. The method yet further includes determining, based on the received information, a presence of a retroreflector based on an intensity of the return test pulse. The method additionally includes determining a subsequent set of light-emission parameters and causing the firing circuit to trigger emission of a subsequent group of detection pulses in accordance with the subsequent set of light-emission parameters.