A robot system including: a robot manipulator that includes links interconnected by joints with degrees of freedom that are at least partially redundant to one another; an operating unit configured to detect an input from a user with respect to at least one selected direction of a force; and a control unit configured to receive the input from the operating unit, determine components of a transpose of a Jacobian matrix associated with a respective selected direction for a predetermined position and/or orientation of a distal end of the robot manipulator in a null space such that a first metric based on the components satisfies one of following criteria: unequal to zero, greater than a specified limit, or a maximum, and control the robot manipulator to move a subset of the links in the null space so as to assume a pose according to the components as determined.

A method and computing system comprising identifying a plurality of robot configurations for each inspection point of a plurality of inspection points of a problem. A graph may be generated with each feasible robot configuration as a node on the graph. A distance may be calculated between a pair of feasible robot configurations. A shortest complete path connecting each node on the graph may be obtained based upon, at least in part, the distance between the pair of feasible robot configurations.

Systems, methods, devices, and other techniques are described for planning motions of one or more robots to perform at least one specified task. In some implementations, a task to execute with a robotic system using a tool is identified. A partially constrained pose is identified for the tool that is to apply during execution of the task. A set of possible constraints for the unconstrained pose parameter are selected for each unconstrained pose parameter. The sets of possible constraints are evaluated for the unconstrained pose parameters with respect to one or more task execution criteria. A nominal pose is determined for the tool based on a result of evaluating the sets of possible constraints for the unconstrained pose parameters with respect to the one or more task execution criteria. The robotic system is then directed to execute the task, including positioning the tool according to the nominal pose.

The present disclosure provides a method for performing a non-revisiting coverage task by a manipulator with a least number of lift-offs, and relates to the technical field of manipulator path planning. By explicitly considering lift-offs of an end-effector from a surface of an object due to kinematic constraints when the manipulator performs a task of covering the surface of the object, this method transforms a problem of coverage path design into a problem of sub-cell decomposition and solves the problem to obtain an approach for the manipulator to cover a sub-cell. The method of the present disclosure minimizes the number of lift-offs of the end-effector from the surface of the object when the manipulator performs the coverage task.

Systems, methods, devices, and other techniques are described for planning motions of one or more robots to perform at least one specified task. In some implementations, a task to execute with a robotic system using a tool is identified. A partially constrained pose is identified for the tool that is to apply during execution of the task. A set of possible constraints for the unconstrained pose parameter are selected for each unconstrained pose parameter. The sets of possible constraints are evaluated for the unconstrained pose parameters with respect to one or more task execution criteria. A nominal pose is determined for the tool based on a result of evaluating the sets of possible constraints for the unconstrained pose parameters with respect to the one or more task execution criteria. The robotic system is then directed to execute the task, including positioning the tool according to the nominal pose.

Methods, systems, and apparatus, including computer programs encoded on computer storage media, for generating motions for components in a robotic operating environment. One of the methods includes receiving a request to generate a motion for a kinematic system having a plurality of connected entities. An entity-specific sampling module for each of multiple degree-of-freedom (DOF) groups representing respective entities of the kinematic system is identified. A plurality of joint configuration samples are generated according to an ordering of a plurality of nonfunctional DOF groups using a respective entity-specific sampling module for each nonfunctional DOF group. A final joint configuration sample is generated for one or more one or more control points using a respective entity-specific sampling module for a functional DOF group. A motion comprising a sequence of respective joint configuration samples from each of the plurality of DOF groups is generated.

Methods, systems, and apparatus, including computer programs encoded on computer storage media, for generating motions for components in a robotic operating environment. One of the methods includes receiving a request to generate a motion for a kinematic system having a plurality of connected entities. An entity-specific sampling module for each of multiple degree-of-freedom (DOF) groups representing respective entities of the kinematic system is identified. A plurality of joint configuration samples are generated according to an ordering of a plurality of nonfunctional DOF groups using a respective entity-specific sampling module for each nonfunctional DOF group. A final joint configuration sample is generated for one or more one or more control points using a respective entity-specific sampling module for a functional DOF group. A motion comprising a sequence of respective joint configuration samples from each of the plurality of DOF groups is generated.

Systems, methods, devices, and other techniques are described for planning motions of one or more robots to perform at least one specified task. In some implementations, a task to execute with a robotic system using a tool is identified. A partially constrained pose is identified for the tool that is to apply during execution of the task. A set of possible constraints for the unconstrained pose parameter are selected for each unconstrained pose parameter. The sets of possible constraints are evaluated for the unconstrained pose parameters with respect to one or more task execution criteria. A nominal pose is determined for the tool based on a result of evaluating the sets of possible constraints for the unconstrained pose parameters with respect to the one or more task execution criteria. The robotic system is then directed to execute the task, including positioning the tool according to the nominal pose.

In some aspects, computer-implemented methods for selecting a robotic tool path for a manufacturing processing system to execute a material processing sequence in three-dimensional space can include: providing to a computer-readable product including robotic system data of a robotic tool handling system and workpiece data relating to a processing path of a tool along the workpiece; generating a plurality of possible robotic tool paths to be performed to move the tool along the processing path; identifying one or more obstacles, or an absence of obstacles, associated with the robotic tool paths; comparing robotic tool paths based on a predetermined robotic parameter to be controlled as the tool moves from the start point to the end point; and based on the identified obstacles, determining feasible tool paths, between the start point and the end point that avoid the obstacles, that can be obtained by adjusting the predetermined robotic parameter.

In some aspects, computer-implemented methods for selecting a robotic tool path for a manufacturing processing system to execute a material processing sequence in three-dimensional space can include: providing to a computer-readable product including robotic system data of a robotic tool handling system and workpiece data relating to a processing path of a tool along the workpiece; generating a plurality of possible robotic tool paths to be performed to move the tool along the processing path; identifying one or more obstacles, or an absence of obstacles, associated with the robotic tool paths; comparing robotic tool paths based on a predetermined robotic parameter to be controlled as the tool moves from the start point to the end point; and based on the identified obstacles, determining feasible tool paths, between the start point and the end point that avoid the obstacles, that can be obtained by adjusting the predetermined robotic parameter.