A robotic navigation system includes a handheld navigation unit associated with a frame of reference. The handheld navigation unit is moveable with respect to a plurality of axes and is configured to send movement signals based on movement of the handheld navigation unit. A controller is configured to receive the movement signals from the handheld navigation unit and determine control signals for the robot. The control signals are configured to incrementally move the robot with respect to a point of interest removed from the robot. The point of interest is removed from a fixed point on the robot as defined by assigned coordinates. The controller is further configured to reassign the assigned coordinates following each incremental movement of the robot.

An apparatus for providing haptic feedback to a teach pendant including a teach pendant having a housing and a processor disposed therein. The processor is in signal communication with a robot controller and is configured to monitor and control a robot. At least one haptic device is disposed on the teach pendant. The haptic device is in signal communication with the processor and configured for providing haptic feedback through the teach pendant to a user upon the occurrence of a haptic event.

A machine learning device, which learns shocks to a teaching device, includes a state observation unit which observes data based on an inclination of the teaching device or a present position of the teaching device; a label obtaining unit which obtains a label based on a shock received by the teaching device; and a learning unit which generates a learning model based on an output of the state observation unit and an output of the label obtaining unit.

In a robot operation apparatus, a motion command generator selects one of combinations of driving axes as an operation object from among preset combinations of the driving axes including at least one of: a driving axis associated with drag operation in a first direction for a touch panel; or a driving axis associated with drag operation in a second direction intersecting with the first direction. If touch operation detected by a touch operation detector is the drag operation, the motion command generator determines whether drag operation is in the first direction or the second direction. The motion command generator generates a motion command to drive the driving axis associated with drag operation in the first direction, if drag operation is in the first direction, and generates a motion command to drive the driving axis associated with drag operation in the second direction, if drag operation is in the second direction.

A manual pulse generating device includes a rotatable dial, a pulse generating unit configured to generate drive pulses for commanding axial movement in accordance with an amount of rotation of the dial, an enable switch configured to switch between enablement and disablement of axial movement in accordance with the drive pulses, and a casing having the dial and the enable switch disposed on a surface thereof, and accommodating the pulse generating unit in the interior thereof. The dial is mounted on one end side in a longitudinal direction of the casing, and on a front surface of the casing, and the enable switch is mounted on another end side, i.e., a side in the positive X direction, in the longitudinal direction of the casing, and on the front surface of the casing, or on a side surface of the casing that extends along a lateral direction of the casing.

A manual pulse generating device is equipped with a rotatable dial, a pulse generating unit configured to generate drive pulses for commanding axial movement in accordance with an amount of rotation of the dial, an enable switch configured to switch between enablement and disablement of axial movement in accordance with the drive pulses, and a casing having the dial and the enable switch disposed on a surface thereof, and configured to accommodate the pulse generating unit in the interior thereof. The guard configured to cover at least a portion of an outer circumferential surface of the dial is attached to the casing.

A robot system includes a robot, a control apparatus that controls the robot, a teaching apparatus having a first operation part that makes an emergency stop of a motion of the robot and teaching the motion of the robot, and an emergency stop processing apparatus having a second operation part that continues the motion of the robot after the first operation part is operated, wherein the second operation part is separately provided from the control apparatus.

A robot operation apparatus comprising: a touch panel that receives input of a touch operation and a movement operation from a user; an operation detector that detects the touch operation and the movement operation to the touch panel; and a behavior command generator that generates a behavior command operating a robot based on a detection result of the operation detector. The behavior command generator performs a behavior speed determination process that determines a behavior speed of the robot based on an operation speed of the movement operation, when the operation detector detects the movement operation to an operation graphic provided on the touch panel.

A non-transitory computer-readable storage medium stores a computer program that controls a processor to execute (a) processing of displaying an operation window for operation of a position and an attitude of a control point for a robot arm, (b) processing of storing the position and the attitude of the control point as a teaching point according to an instruction of a user, and (c) processing of associating and storing the operation window when the instruction is received in the processing (b) with the teaching point.

A robotic navigation system is configured to move a robotic arm of a robot relative to a surface. The robotic navigation system includes a sensor, a handheld navigation unit, and a controller. The sensor is associated with the robotic arm. The sensor is configured to determine a status parameter of the robotic arm relative to the surface and provide sensor signals indicative of the status parameter. The handheld navigation unit is moveable with respect to one or more of a plurality of axes to indicate a commanded movement for the robot. The handheld navigation unit is configured to provide movement signals based on the commanded movement for the robot. The controller is configured to provide control signals for the robot based on the movement signals provided by the handheld navigation unit and the sensor signals provided by the sensor, wherein the control signals are configured to move the robot. The resulting robotic motion may dynamically track a desired feature or a component by correction and overriding a portion of the hand guided motion vector.