System and method for three-dimensional mapping using two-dimensional LiDAR laser ranging
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
G01C-003/08
G01S-017/89
G01S-007/481
G01S-017/42
출원번호
US-0221685
(2016-07-28)
등록번호
US-10175361
(2019-01-08)
발명자
/ 주소
Haines, Darin
Vojak, William
Gaebel, Gary
Thomas, John
출원인 / 주소
Sharp Laboratories of America, Inc.
대리인 / 주소
ScienBiziP, P.C.
인용정보
피인용 횟수 :
0인용 특허 :
11
초록▼
A system and method are presented for using a two-dimensional (2D) LiDAR for three dimensional (3D) laser mapping. The 2D-LiDAR is mounted in a chassis. The method laser ranges a planar slice of the environment. Simultaneous with laser ranging the planar slice, the 2D LiDAR chassis is rotated about
A system and method are presented for using a two-dimensional (2D) LiDAR for three dimensional (3D) laser mapping. The 2D-LiDAR is mounted in a chassis. The method laser ranges a planar slice of the environment. Simultaneous with laser ranging the planar slice, the 2D LiDAR chassis is rotated about an axis to create a 3D laser mapping of at least a portion of the environment. More explicitly, the 2D LiDAR may include a laser ranger with a planar actuator, typically the combination of a laser and a rotating mirror. In addition, the 2D LiDAR chassis is mounted on a reciprocating actuator. Thus, the step of laser ranging the planar slice includes laser ranging the planar slice in response to the planar actuator. The step of rotating the 2D LiDAR chassis includes rotating the 2D LiDAR chassis around an axis parallel to the planar slice, in response to the reciprocating actuator.
대표청구항▼
1. A method for using a two-dimensional (2D) LiDAR for three dimensional (3D) laser mapping, the method comprising: providing a 2D LiDAR mounted in a chassis; wherein providing the 2D LiDAR includes: providing a laser ranging system with a planar actuator;mounting the 2D LiDAR chassis on a reciproca
1. A method for using a two-dimensional (2D) LiDAR for three dimensional (3D) laser mapping, the method comprising: providing a 2D LiDAR mounted in a chassis; wherein providing the 2D LiDAR includes: providing a laser ranging system with a planar actuator;mounting the 2D LiDAR chassis on a reciprocating actuator;laser ranging a planar slice of an environment; wherein laser ranging the planar slice includes laser ranging the planar slice in response to the planar actuator;simultaneous with laser ranging the planar slice, rotating the 2D LiDAR chassis about an axis; wherein rotating the 2D LiDAR chassis includes rotating the 2D LiDAR chassis around an axis parallel to the planar slice, in response to the reciprocating actuator; wherein laser ranging the planar slice in response to the planar actuator includes completing a first plurality of planar sweeps for every reciprocating actuator rotation; andcreating a 3D laser mapping of at least a portion of the environment; wherein creating the 3D laser mapping includes creating a forward-looking map comprising a first plurality of adjacent figure-8 laser scans. 2. A method for using a two-dimensional (2D) LiDAR for three dimensional (3D) laser mapping, the method comprising: providing a 2D LiDAR mounted in a chassis; wherein providing the 2D LiDAR includes: providing a laser ranging system with a planar actuator;mounting the 2D LiDAR chassis on a reciprocating actuator;laser ranging a planar slice of an environment; wherein laser ranging the planar slice includes laser ranging the planar slice in response to the planar actuator;simultaneous with laser ranging the planar slice, rotating the 2D LiDAR chassis about an axis; wherein rotating the 2D LiDAR chassis includes rotating the 2D LiDAR chassis around an axis parallel to the planar slice, in response to the reciprocating actuator; wherein rotating the 2D LiDAR chassis in response to the reciprocating actuator includes completing a first plurality of reciprocating rotations for every planar actuator sweep; andcreating a 3D laser mapping of at least a portion of the environment; and, wherein creating the 3D laser mapping includes creating a forward-looking map with a spiral pattern of laser scans. 3. A three-dimensional (3D) LiDAR system using a two-dimensional (2D) LiDAR, the system comprising: a reciprocating actuator having a rotation axis;a chassis, attached to the reciprocating actuator, and capable of reciprocal rotation about the rotation axis; wherein the reciprocating actuator rotates the chassis around an axis parallel to the first planar slice;a first 2D laser ranging system, having an interface for laser ranging a planar slice of an environment, mounted in the chassis; wherein the first 2D laser ranging system includes a planar actuator for laser ranging a first planar slice;wherein the simultaneous laser ranging of the planar slice and chassis rotation create a 3D laser mapping of at least a portion of the environment; wherein the planar actuator completes a first plurality of planar sweeps for every reciprocating actuator rotation; andwherein a forward-looking 3D map is created comprising a first plurality of adjacent figure-8 laser scans. 4. A three-dimensional (3D) LiDAR system using a two-dimensional (2D) LiDAR, the system comprising: a reciprocating actuator having a rotation axis;a chassis, attached to the reciprocating actuator, and capable of reciprocal rotation about the rotation axis; wherein the reciprocating actuator rotates the chassis around an axis parallel to the first planar slice;a first 2D laser ranging system, having an interface for laser ranging a planar slice of an environment, mounted in the chassis; wherein the first 2D laser ranging system includes a planar actuator for laser ranging a first planar slice;wherein the simultaneous laser ranging of the planar slice and chassis rotation create a 3D laser mapping of at least a portion of the environment; wherein the reciprocating actuator completes a first plurality of reciprocating rotations for every planar actuator sweep; andwherein a forward-looking 3D map is created with a spiral pattern of laser scans. 5. The method of claim 1 wherein rotating the 2D LiDAR chassis around the axis includes alternating the direction of rotation prior to the completion of a complete revolution of the 2D LiDAR chassis around the axis. 6. The method of claim 5 wherein alternating the direction of rotation prior to the completion of a complete revolution of the 2D LiDAR chassis around the axis includes: rotating the 2D LiDAR chassis in a first direction less than or equal to 180 degrees; and, rotating the 2D LiDAR chassis in a second direction, opposite to the first direction, less than or equal to 180 degrees. 7. The system of claim 3 wherein the reciprocating actuator alternates the direction of rotation prior to the completion of a complete revolution around the axis. 8. The system of claim 7 wherein the reciprocating actuator rotates the 2D LiDAR chassis in a first direction less than or equal to 180 degrees, and then rotates the 2D LiDAR chassis is a second direction, opposite to the first direction, less than or equal to 180 degrees. 9. The method of claim 2 wherein rotating the 2D LiDAR chassis around the axis includes alternating the direction of rotation prior to the completion of a complete revolution of the 2D LiDAR chassis around the axis. 10. The method of claim 9 wherein alternating the direction of rotation prior to the completion of a complete revolution of the 2D LiDAR chassis around the axis includes: rotating the 2D LiDAR chassis in a first direction less than or equal to 180 degrees; and, rotating the 2D LiDAR chassis in a second direction, opposite to the first direction, less than or equal to 180 degrees. 11. The system of claim 4 wherein the reciprocating actuator alternates the direction of rotation prior to the completion of a complete revolution around the axis. 12. The system of claim 11 wherein the reciprocating actuator rotates the 2D LiDAR chassis in a first direction less than or equal to 180 degrees, and then rotates the 2D LiDAR chassis is a second direction, opposite to the first direction, less than or equal to 180 degrees.
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이 특허에 인용된 특허 (11)
Fiess, Reinhold; Steinkogler, Sascha, Adaptive angle and power adaptation in 3D-micro-mirror LIDAR.
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