公开(公告)号：US20220206501A1

公开(公告)日：2022-06-30

申请号：US17462019

申请日：2021-08-31

Applicant: UBTECH ROBOTICS CORP LTD

Inventor： Xingxing Ma ,  Chunyu Chen ,  Yizhang Liu ,  Ligang Ge ,  Hongge Wang ,  Jie Bai ,  Jiangchen Zhou ,  Zheng Xie

IPC: G05D1/02 ,  B25J9/16

Abstract: A dynamic footprint set generation method, a biped robot using die same, and a computer readable storage medium are provided. The method includes: obtaining preset footprint calculation parameters; calculating a landing point position based on the preset footprint calculation parameters; determining a landing point range based on a landing point position, and performing a collision detection on the landing point range; recording the corresponding landing point position in a footprint set in response to the detection result representing there being no collision; obtaining a preset adjustment amplitude to update a preset displacement angle after the recording is completed; and returning to the calculating the landing point position until the footprint set is generated. By continuously adjusting the preset displacement angle, each landing point position is calculated accordingly, and the valid landing point positions are recorded in the footprint set, which provides more feasible landing points for navigation planning.

公开(公告)号：US20210197379A1

公开(公告)日：2021-07-01

申请号：US17115712

申请日：2020-12-08

Applicant: UBTECH ROBOTICS CORP LTD

Inventor： Dake Zheng ,  Yizhang Liu ,  Zheng Xie ,  Jianxin Pang ,  Youjun Xiong

IPC: B25J9/16 ,  G05B19/4155

Abstract: The present disclosure provides a method for controlling an arm of a robot, including obtaining obstacle information relating to the arm of the robot by at least one sensor, obtaining current posture information of the arm of the robot by a least one detector and obtaining an expected posture information of an end-portion of the arm of the robot, determining an expected trajectory of the end-portion of the arm of the robot, determining an expected speed of the end-portion of the arm of the robot in accordance with the expected trajectory of the end-portion, determining a virtual speed of a target point on the arm of the robot, and configuring a target join speed corresponding to a joint of the arm of the robot. Such that the redundant arm of the robot may be configured to prevent from contacting the obstacles in the complex environment while performing corresponding tasks.

公开(公告)号：US20210181748A1

公开(公告)日：2021-06-17

申请号：US17120232

申请日：2020-12-13

Applicant: UBTECH ROBOTICS CORP LTD

Inventor： Chunyu Chen ,  Yizhang Liu ,  Ligang Ge ,  Zheng Xie ,  Youjun Xiong ,  Jianxin Pang

IPC: G05D1/02 ,  G01L5/16 ,  B62D57/02 ,  G05B19/4155

Abstract: A robot balance control method includes: obtaining force information associated with a left foot and a right foot of the robot; calculating a zero moment point of a center of mass (COM) of a body of the robot based on the force information; calculating a first position offset and a second position offset of the robot according to the zero moment point of the COM of the body; updating a position trajectory of the robot according to the first position offset and the second offset to obtain an updated position of the COM of the body; performing inverse kinematics analysis on the updated position of the COM of the body to obtain joint angles of the left leg and the right leg of the robot; and controlling the robot to move according to the joint angles.

公开(公告)号：US20210146538A1

公开(公告)日：2021-05-20

申请号：US16734393

申请日：2020-01-05

Applicant: UBTECH ROBOTICS CORP LTD

Inventor： Zecai Lin ,  Zhaohui An ,  Zheng Xie ,  Yizhang Liu ,  Youjun Xiong ,  Jianxin Pang

IPC: B25J9/16 ,  B25J13/08

Abstract: A method for controlling an arm of a robot to imitate a human arm, includes: acquiring first pose information of key points of a human arm to be imitated; converting the first pose information into second pose information of key points of an arm of a robot; determining an angle value of each joint of the arm according to inverse kinematics of the arm based on the second pose information; and controlling the arm to move according to the angle values.

公开(公告)号：US20210107577A1

公开(公告)日：2021-04-15

申请号：US16724413

申请日：2019-12-23

Applicant: UBTECH ROBOTICS CORP LTD

Inventor： Chunyu Chen ,  Yizhang Liu ,  Ligang Ge ,  Xianwei Su ,  Zheng Xie ,  Youjun Xiong ,  Jianxin Pang

IPC: B62D57/02 ,  G01L5/16

Abstract: The present disclosure provides a zero moment point jitter processing method as well as an apparatus and a robot using the same. The method includes: obtaining left foot force information and right foot force information collected by sensors; calculating a first zero moment point and a second zero moment point of soles of two feet of a robot based on the left foot force information and the right foot force information; calculating a third zero moment point of the robot according to the first zero moment point and the second zero moment point; calculating a jitter amplitude of the third zero moment point within a preset period; and adjusting a position of the third zero moment point in response to the jitter amplitude being not larger than a predetermined jitter amplitude threshold. In this manner, the robot can eliminate zero moment point jitters within a certain amplitude.

公开(公告)号：USD910782S1

公开(公告)日：2021-02-16

申请号：US29627303

申请日：2017-11-26

Applicant: UBTECH Robotics Corp

Designer： Jian Zhou ,  Huaqiang Lu ,  Yiping Li ,  Youjun Xiong ,  John Rhee ,  Peng Deng ,  Jianxin Pang ,  Zheng Xie ,  Shulong Liu ,  Yangyu Pi ,  Youpeng Li ,  Jing Shi ,  Yizhang Liu ,  Kunlei Zhao

公开(公告)号：US20200206898A1

公开(公告)日：2020-07-02

申请号：US16572637

申请日：2019-09-17

Applicant: UBTECH ROBOTICS CORP LTD

Inventor： YOUJUN XIONG ,  Ligang Ge ,  Yizhang Liu ,  Chunyu Chen ,  Zheng Xie ,  Jianxin Pang

IPC: B25J9/00 ,  B25J13/08 ,  B25J9/16

Abstract: There are a biped robot gait control method and a biped robot, where the method includes: obtaining six-dimensional force information, and determining a motion state of two legs of the biped robot; calculating a ZMP position of each of two legs of the biped robot; determining a ZMP expected value of each of the two legs in real time; obtaining a compensation angle of an ankle joint of each of the two legs of the biped robot by inputting the ZMP position, a change rate of the ZMP position, the ZMP expected value, and a change rate of the ZMP expected value to an ankle joint smoothing controller so as to perform a close-loop ZMP tracking control on each of the two legs; adjusting a current angle of the ankle joint of each of the two legs of the biped robot in real time; and repeating the forgoing steps.

公开(公告)号：US12076860B2

公开(公告)日：2024-09-03

申请号：US17561609

申请日：2021-12-23

Applicant: UBTECH ROBOTICS CORP LTD

Inventor： Ligang Ge ,  Yizhang Liu ,  Chunyu Chen ,  Zheng Xie ,  Youjun Xiong

IPC: B62D57/032 ,  B25J9/16 ,  B62D57/024

CPC classification number: B25J9/1602 ,  B25J9/1633

Abstract: A control method for a robot includes: determining a desired zero moment point (ZMP) of the robot; obtaining a position of a left foot and a position of a right foot of the robot, and calculating desired support forces of the left foot and the right foot according to the desired ZMP, the positions of the left foot and the right foot; obtaining measured support forces of the left foot and the right foot, and calculating an amount of change in length of the left leg and an amount of change in length of the right leg according to the desired support forces of the left foot and the right foot, the measured support forces of the left foot and the right foot; and controlling the robot to walk according to the amount of change in length of the left leg and the right leg.

公开(公告)号：US11983012B2

公开(公告)日：2024-05-14

申请号：US17462019

申请日：2021-08-31

Applicant: UBTECH ROBOTICS CORP LTD

Inventor： Xingxing Ma ,  Chunyu Chen ,  Yizhang Liu ,  Ligang Ge ,  Hongge Wang ,  Jie Bai ,  Jiangchen Zhou ,  Zheng Xie

IPC: G05D1/00 ,  B62D57/032

CPC classification number: G05D1/0214 ,  G05D1/0231 ,  B62D57/032

Abstract: A dynamic footprint set generation method, a biped robot using die same, and a computer readable storage medium are provided. The method includes: obtaining preset footprint calculation parameters; calculating a landing point position based on the preset footprint calculation parameters; determining a landing point range based on a landing point position, and performing a collision detection on the landing point range; recording the corresponding landing point position in a footprint set in response to the detection result representing there being no collision; obtaining a preset adjustment amplitude to update a preset displacement angle after the recording is completed; and returning to the calculating the landing point position until the footprint set is generated. By continuously adjusting the preset displacement angle, each landing point position is calculated accordingly, and the valid landing point positions are recorded in the footprint set, which provides more feasible landing points for navigation planning.

公开(公告)号：US20230271656A1

公开(公告)日：2023-08-31

申请号：US18144160

申请日：2023-05-05

Applicant: UBTECH ROBOTICS CORP LTD

Inventor： Ligang Ge ,  Yizhang Liu ,  Chunyu Chen ,  Zheng Xie ,  Youjun Xiong

IPC: B62D57/032 ,  G01M1/12 ,  B25J9/16 ,  B25J13/08

CPC classification number: B62D57/032 ,  G01M1/122 ,  B25J9/161 ,  B25J9/1633 ,  B25J13/085

Abstract: A robot state estimation method, a computer-readable storage medium, and a legged robot are provided. The method includes: obtaining force information of a left leg of a robot and a right leg of the robot; calculating a ZMP of the robot in a world coordinate system based on the force information of the left leg and the force information of the right leg; and calculating a position of a center of mass (CoM) of the robot based on a preset linear inverted pendulum model. In this manner, a brand-new linear inverted pendulum model is constructed in advance, which uses the ZMP of the robot as a supporting point of the model, thereby fully considering the influence of the change of the position of the ZMP of the robot on the position of the CoM.