Diffractive optical element in a lidar system to correct for backscan
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
G01S-003/08
G01S-007/481
G01S-007/486
G01S-017/93
G01S-017/10
G01S-007/484
출원번호
US-0728950
(2017-10-10)
등록번호
US-10061019
(2018-08-28)
발명자
/ 주소
Campbell, Scott R.
Eichenholz, Jason M.
출원인 / 주소
LUMINAR TECHNOLOGIES, INC.
대리인 / 주소
Marshall, Gerstein & Borun LLP
인용정보
피인용 횟수 :
0인용 특허 :
68
초록▼
To detect return light pulses in a lidar system when scanning in the forward-scanning and reverse-scanning directions, a light source may transmit first light pulses having a first wavelength when scanning in the forward-scanning direction and may transmit second light pulses having a second wavelen
To detect return light pulses in a lidar system when scanning in the forward-scanning and reverse-scanning directions, a light source may transmit first light pulses having a first wavelength when scanning in the forward-scanning direction and may transmit second light pulses having a second wavelength when scanning in the reverse-scanning direction. A diffractive optical element (DOE) is configured to deflect the two wavelengths in opposite directions, so that light pulses are transmitted ahead of the field of view of the detector in the scanning direction of the lidar system. A controller may determine the scanning direction of a scanner in the lidar system and transmit a control signal to a light source indicative of a wavelength that corresponds to the scanning direction. The light source may then transmit light pulses at the requested wavelength.
대표청구항▼
1. A lidar system comprising: one or more light sources configured to transmit light pulses comprising a plurality of first light pulses having a first wavelength and a plurality of second light pulses having a second wavelength;a diffractive optical element that deflects the first and second light
1. A lidar system comprising: one or more light sources configured to transmit light pulses comprising a plurality of first light pulses having a first wavelength and a plurality of second light pulses having a second wavelength;a diffractive optical element that deflects the first and second light pulses at different angles according to the respective first and second wavelengths;a scanner configured to scan a field of view of the one or more light sources in a forward-scanning direction during a first time interval and a reverse-scanning direction during a second time interval; anda detector configured to detect: scattered light from at least a portion of the first light pulses when the scanner is scanning the field of view in the forward-scanning direction during the first time interval; andscattered light from at least a portion of the second light pulses when the scanner is scanning the field of view in the reverse-scanning direction during the second time interval. 2. The lidar system of claim 1, wherein: the scanner alternately scans the field of view of the one or more light sources in the forward-scanning and reverse-scanning directions; andthe one or more light sources include a single light source configured to transmit the plurality of first light pulses when the scanner is scanning in the forward-scanning direction and the plurality of second light pulses when the scanner is scanning in the reverse-scanning direction. 3. The lidar system of claim 1, wherein a pixel corresponds to an angle of a field of view of the detector or the one or more light sources and the diffractive optical element is configured to: deflect the first light pulses by less than or equal to one pixel in the forward-scanning direction so that, when scanning in the forward-scanning direction, each of the first light pulses is transmitted ahead of a field of view of the detector by less than or equal to one pixel; anddeflect the second light pulses by less than or equal to one pixel in the reverse-scanning direction so that, when scanning in the reverse-scanning direction, each of the second light pulses is transmitted ahead of the field of view of the detector by less than or equal to one pixel. 4. The lidar system of claim 1, wherein the one or more light sources include 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. 5. The lidar system of claim 1, wherein the detector is aligned with the light source such that the field of view of the light source and a field of view of the detector are at least partially overlapped. 6. The lidar system of claim 1, wherein the one or more light sources include a first light source configured to transmit the plurality of first light pulses and a second light source configured to transmit the plurality of second light pulses. 7. The lidar system of claim 6, wherein the first light source transmits the plurality of first light pulses when the scanner is scanning in the forward-scanning direction and the second light source transmits the plurality of second light pulses when the scanner is scanning in the reverse-scanning direction. 8. The lidar system of claim 1, wherein a pixel corresponds to an angle of a field of view of the detector or the one or more light sources and the diffractive optical element is configured to: deflect the first light pulses by less than or equal to one pixel in the forward-scanning direction; anddeflect the second light pulses by less than or equal to one pixel in the reverse-scanning direction. 9. A method for bi-directional scanning of a field of regard, the method comprising: generating light pulses by one or more light sources in a lidar system, the light pulses comprising a plurality of first light pulses having a first wavelength and a plurality of second light pulses having a second wavelength;deflecting, by a diffractive optical element in the lidar system, the first and second light pulses at different angles according to the respective first and second wavelengths;scanning, by a scanner in the lidar system, a field of view of the one or more light sources in a forward-scanning direction during a first time interval and a reverse-scanning direction during a second time interval;detecting, by a receiver of the lidar system, scattered light from the first light pulses when the scanner is scanning the field of view in the forward-scanning direction during the first time interval; anddetecting, by the receiver of the lidar system, scattered light from the second light pulses when the scanner is scanning the field of view in the reverse-scanning direction during the second time interval. 10. The method of claim 9, wherein: scanning the field of view of the one or more light sources includes alternately scanning, by the scanner, the field of view of the one or more light sources in the forward-scanning and reverse-scanning directions; andwherein the one or more light sources include a single light source configured to transmit the plurality of first light pulses when the scanner is scanning in the forward-scanning direction and the plurality of second light pulses when the scanner is scanning in the reverse-scanning direction. 11. The method of claim 10, wherein the detector is aligned with the light source such that the field of view of the light source and a field of view of the detector are at least partially overlapped. 12. The method of claim 9, wherein a pixel corresponds to an angle of a field of view of the detector or the one or more light sources and wherein deflecting the first and second light pulses includes: deflecting, by the diffractive optical element, the first light pulses by less than or equal to one pixel in the forward-scanning direction so that, when scanning in the forward-scanning direction, each of the first light pulses is transmitted ahead of a field of view of the detector by less than or equal to one pixel; anddeflecting, by the diffractive optical element, the second light pulses by less than or equal to one pixel in the reverse-scanning direction so that, when scanning in the reverse-scanning direction, each of the second light pulses is transmitted ahead of the field of view of the detector by less than or equal to one pixel. 13. The method of claim 9, wherein the one or more light sources include 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. 14. The method of claim 9, wherein the one or more light sources include a first light source configured to transmit the plurality of first light pulses and a second light source configured to transmit the plurality of second light pulses. 15. The method of claim 14, wherein the first light source transmits the plurality of first light pulses when the scanner is scanning in the forward-scanning direction and the second light source transmits the plurality of second light pulses when the scanner is scanning in the reverse-scanning direction. 16. The method of claim 15, wherein a pixel corresponds to an angle of a field of view of the detector or the light sources and wherein deflecting the first and second light pulses includes: deflecting, by the diffractive optical element, the first light pulses by less than or equal to one pixel in the forward-scanning direction; anddeflecting, by the diffractive optical element, the second light pulses by less than or equal to one pixel in the reverse-scanning direction. 17. A controller in a lidar system comprising: one or more processors; anda non-transitory computer-readable memory coupled to the one or more processors and storing instructions thereon that, when executed by the one or more processors, cause the controller to: determine a scanning direction of a field of view of a light source, the scanning direction including a forward-scanning direction during a first time interval or a reverse-scanning direction during a second time interval; andin response to determining the scanning direction, provide a control signal to the light source to emit first light pulses having a first wavelength or second light pulses having a second wavelength in accordance with the scanning direction, wherein the first light pulses are emitted for the forward-scanning direction and the second light pulses are emitted for the reverse-scanning direction;wherein a pixel corresponds to an angle of a field of view of the detector or the light source and a diffractive optical element is configured to: deflect the first light pulses by less than or equal to one pixel in the forward-scanning direction so that, when scanning in the forward-scanning direction during the first time interval, each of the first light pulses is transmitted ahead of a field of view of the detector by less than or equal to one pixel; anddeflect the second light pulses by less than or equal to one pixel in the reverse-scanning direction, so that, when scanning in the reverse-scanning direction during the second time interval, each of the second light pulses is transmitted ahead of the field of view of the detector by less than or equal to one pixel. 18. The controller of claim 17, wherein the light source includes a plurality of light sources including a first light source configured to transmit the plurality of first light pulses and a second light source configured to transmit the plurality of second light pulses; and wherein to provide a control signal to the light source to emit first light pulses having a first wavelength or second light pulses having a second wavelength, the instructions cause the controller to provide a first control signal to the first light source to transmit the first plurality of light pulses in response to determining the forward-scanning direction and the instructions cause the controller to provide a second control signal to the second light source to transmit the second plurality of light pulses in response to determining the reverse-scanning direction. 19. The controller of claim 17, wherein the instructions cause the controller to determine the scanning direction of the field of view of the light source based at least in part on a change in the scanning direction. 20. The controller of claim 19, wherein in response to determining that the scanning direction changed, the instructions cause the controller to provide a control signal to the light source to switch from the first light pulses to the second light pulses or from the second light pulses to the first light pulses.
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