An off-line programming apparatus includes a model creation unit that creates three-dimensional models of a robot and a load, a storage unit that stores a dynamic parameter of the load, a graphic creation unit that creates a three-dimensional graphic representing the dynamic parameter based on the dynamic parameter, and a display unit that displays the three-dimensional models of the robot and the load and the three-dimensional graphic. The dynamic parameter includes inertia around three axes that are orthogonal to one another at a centroid of the load. The three-dimensional graphic is a solid defined by dimensions in three directions orthogonal to one another. The graphic creation unit sets a ratio of the dimensions in the three directions of the three-dimensional graphic to a ratio corresponding to a ratio of the inertia around the three axes.

A control apparatus of an insertion apparatus in which a state specifying unit specifies a state of an insertion member to carry out vibration control depending on the state, thereby removing getting-stuck of a tip of the insertion member with a vibration having such a proper magnitude as not to cause an overload in a case where the tip of the insertion member is gotten stuck.

A control apparatus of an insertion apparatus in which a state specifying unit specifies a state of an insertion member to carry out vibration control depending on the state, thereby removing getting-stuck of a tip of the insertion member with a vibration having such a proper magnitude as not to cause an overload in a case where the tip of the insertion member is gotten stuck.

The present invention relates to a robot teaching system based on image segmentation and surface electromyography and robot teaching method thereof, comprising a RGB-D camera, a surface electromyography sensor, a robot and a computer, wherein the RGB-D camera collects video information of robot teaching scenes and sends to the computer; the surface electromyography sensor acquires surface electromyography signals and inertial acceleration signals of the robot teacher, and sends to the computer; the computer recognizes a articulated arm and a human joint, detects a contact position between the articulated arm and the human joint, and further calculates strength and direction of forces rendered from a human contact position after the human joint contacts the articulated arm, and sends a signal controlling the contacted articulated arm to move along with such a strength and direction of forces and robot teaching is done.

A robot system with a hand-guiding function is disclosed. The robot system selects the hand-guiding function or non-hand-guiding function of an enable device by a mode option mechanism during the operation of a teach mode or an automatic mode. When selecting the hand-guiding function, the enable device has both the enabling and the hand-guiding function to easily hand-guiding the robot to operate.

A device for robotic direct lead-through teaching includes a robot, a replacing member and a lead-through teaching member. The robot has an operation member coupled with the replacing member. The lead-through teaching member mounted replaceably at the replacing member has a force sensor. The force sensor has six-axis load information. A path teaching is executed manually upon the operation member of the robot so as to store coordinate information. In additional, a method for robotic direct lead-through teaching is also provided.

Methods and systems for teaching positions to components of devices are described. An example method includes providing instructions to a robotic device or robotic manipulator to place the robotic manipulator into a fine-tuning teach mode, in which the robotic manipulator is in a given position and is configured to move based on application of a manual contact in one or more step movements having a preset amount of distance. The method also includes determining that a given manual contact is applied to the robotic manipulator, and causing the robotic manipulator to incrementally move in the one or more step movements having the preset amount of distance.

The articulated-arm robot has a robot arm with an arm element movable via a joint and a sensor for continuously measuring a status parameter of the joint. The articulated-arm robot also has an optical signaling device arranged on the robot arm in spatial assignment to the joint and an assessment device for continuously assessing the measured status parameter in a joint-specific manner and for controlling the signaling device on the basis of the assessment result.

The articulated-arm robot has a robot arm with an arm element movable via a joint and a sensor for continuously measuring a status parameter of the joint. The articulated-arm robot also has an optical signaling device arranged on the robot arm in spatial assignment to the joint and an assessment device for continuously assessing the measured status parameter in a joint-specific manner and for controlling the signaling device on the basis of the assessment result.

A robot system capable of reliably detecting contact between a robot or a workpiece and an external object. The robot system includes: a robot including a handling part; a handling force-detection part that detects a handling force applied to the handling part; an operation controller that causes the robot to operate in accordance with the handling force; an external force-detection part that detects an external force acting on the robot; and a contact force-calculation part that calculates a contact force by subtracting the handling force from the detected external force.