A robot off-line programming method. The method includes: respectively obtaining a first data representing positions and orientations of the plurality of targets on at least one work piece, a second data representing position of the at least one work piece, a third data representing geometry of a tool, and a fourth data representing the tool position and orientation with respect to an end of the robot; obtaining the robot path for which the tool tip passes through the plurality of the targets on the at least one work piece; using a function of an inverse kinematics for the robot model in consideration of the first data, the second data, the third data and the fourth data, calculating how many of the targets on the obtained robot path are reachable to the tool in relation to various rotation angle of the tool around the tool axis within a predetermined range so as to comply with optimization criteria. With the automatic calculation and intuitive preview, users could get to know directly about how many targets can be processed actually on a robot path. If the reachability is unsatisfied, the users could also have chances to modify the settings to obtain a more reasonable and precise path. An apparatus for implementing the method is also disclosed.

A robot off-line programming method. The method includes: respectively obtaining a first data representing positions and orientations of the plurality of targets on at least one work piece, a second data representing position of the at least one work piece, a third data representing geometry of a tool, and a fourth data representing the tool position and orientation with respect to an end of the robot; obtaining the robot path for which the tool tip passes through the plurality of the targets on the at least one work piece; using a function of an inverse kinematics for the robot model in consideration of the first data, the second data, the third data and the fourth data, calculating how many of the targets on the obtained robot path are reachable to the tool in relation to various rotation angle of the tool around the tool axis within a predetermined range so as to comply with optimization criteria. With the automatic calculation and intuitive preview, users could get to know directly about how many targets can be processed actually on a robot path. If the reachability is unsatisfied, the users could also have chances to modify the settings to obtain a more reasonable and precise path. An apparatus for implementing the method is also disclosed.

There is provided a method and an apparatus for controlling a robot arm. In this control scheme, a position error indicating a deviation between a command position, which is a control target position, and a current position, which is a position where the arm of the robot is currently located, is acquired. When the acquired position error exceeds a threshold, a new corrected command position between the current position and the command position is set. After the arm of the robot is moved to the corrected command position, a new corrected command position reset between the corrected command position serving as a new current position and the command position. Reconfiguration of a corrected command position is iterated until a current position of the robot arm becomes equal to the command position so that movement of the robot arm is achieved from the current position to the command position.

A robot includes a wrist unit including a plurality of wrist joints; and a plurality of basic joints configured to determine the position of the wrist unit in a three-dimensional space. Only the basic joints, and are provided with torque sensors configured to detect torque of the basic joints about axis lines.

The inventive technology eliminates the need for force sensors on a robotic manipulator while also improving feel by incorporating force sensors on the corresponding robotic input device. Position of the manipulator is used to determine positioning of the input device; therefore, rather than manipulator position lagging the input device position (as in conventional robotic systems), the opposite is true, so that input device position lags manipulator position. Through a combination of input device force control and manipulator position feedback, a sense of feel is achieved through use of an effort sensor mounted at a control point on the input device and use of a position feedback force control scheme.

The inventive technology eliminates the need for force sensors on a robotic manipulator while also improving feel by incorporating force sensors on the corresponding robotic input device. Position of the manipulator is used to determine positioning of the input device; therefore, rather than manipulator position lagging the input device position (as in conventional robotic systems), the opposite is true, so that input device position lags manipulator position. Through a combination of input device force control and manipulator position feedback, a sense of feel is achieved through use of an effort sensor mounted at a control point on the input device and use of a position feedback force control scheme.

A robot instructing apparatus includes a teaching pendant having a display and an inclination device. The inclination device outputs an inclination of the teaching pendant based on the inclination of the teaching pendant about at least one horizontal axis. The robot instructing apparatus also includes at least one processor that generates movement instructions to change a posture of the robot based on the inclination of the teaching pendant output by the inclination device during a teaching operation in which the movement instructions are generated.

In robot teaching programming, a robot teaching programming method, apparatus and system, and a computer-readable medium, can realize the programming of a robot simply, and are not restricted in terms of robot types. A robot teaching programming system includes a movable apparatus for imitating movement of an end effector of a robot in a working space of the robot; a robot teaching programming apparatus for recording first movement information of the movable apparatus in a first coordinate system and converting the same to second movement information in a second coordinate system of the robot, and then programming the robot according to the second movement information. Using a movable apparatus to simulate an end effector of a robot has the advantages of ease of operation, and no restrictions in terms of robot types. Teaching programming is accomplished through simple coordinate transformation, and there is no need for advanced programming skills.

Systems and methods for simultaneously and economically providing high speed and precision robotic operations with operational safety include directly performing training movements of a desired task on a collaborative robot, recording data corresponding to the training movements, and transmitting the recorded data to a conventional robot to cause the conventional robot to autonomously execute the training movements in accordance with the received data.

Systems and methods for simultaneously and economically providing high speed and precision robotic operations with operational safety include directly performing training movements of a desired task on a collaborative robot, recording data corresponding to the training movements, and transmitting the recorded data to a conventional robot to cause the conventional robot to autonomously execute the training movements in accordance with the received data.