A robot system includes a robot main body, memory part configured to store information for causing robot main body to perform given operation, as saved operational information, motion controller configured to control operation of robot main body by using saved operational information as automatic operational information for causing robot main body to operate, and an operation correcting device configured to generate, by being operated, manipulating information for correcting operation of robot main body during operation. Motion controller controls robot main body to perform an operation corrected from operation related to automatic operational information in response to a reception of the manipulating information while robot main body is operating by using automatic operational information. Memory part is configured to be storable of corrected operational information for causing robot main body to perform corrected operation as saved operational information, when robot main body performs corrected operation.

A robot system is provided, which includes a robot body including, robot arm and an end effector attached to robot arm, and operating device, having operating part and configured to output, when operating part is operated, operational information according to operation, a motion controller configured to control operation of robot body according to the operational information outputted from the operating device, a velocity detector configured to detect a velocity at a tip end of the end effector, a virtual reaction-force information generating module configured to output force information containing a first force component having a positive correlation to the velocity at the tip end of the end effector, as virtual reaction-force information, and a force applying device configured to give a force to the operating part in order to make an operator perceive a force according to the virtual reaction-force information outputted from the virtual reaction-force information generating module.

An articulated arm system is disclosed that includes an articulated arm including an end effector, and a robotic arm control systems including at least one sensor for sensing at least one of the position, movement or acceleration of the articulated arm, and a main controller for providing computational control of the articulated arm, and an on-board controller for providing, responsive to the at least one sensor, a motion signal that directly controls at least a portion of the articulated arm.

Robot system which includes a master device configured to receive an operating instruction from an operator, slave arm, storage device configured to store operating sequence information that defines processing carried out by slave arm, and control device configured to control operation of slave arm. Control device includes a receiver configured to receive an input signal, motion controller configured to determine whether operating mode of slave arm is to be automatic, manual or correctable automatic mode and control operation of slave arm in determined operating mode, and continuation determinator configured to determine whether continuation of automatic mode is permitted. In a process at which slave arm is scheduled to operate in automatic mode, after motion controller suspends operation of slave arm in automatic mode at a given step of process, continuation determinator determines whether continuation of automatic mode is permitted based on input signal received by receiver when operation is suspended.

A robot main body having a robotic arm, a remote control device which includes a robotic arm operational instruction input part installed outside of a working area and by which an operational instruction for the robotic arm is inputted, and a contactless action detecting part configured to detect a contactless action including at least one given operating condition parameter change instructing action by an operator, a control device communicably connected to the remote control device and configured to control operation of the robot main body.

A multimodal sensing architecture utilizes an array of single sensor or multi-sensor groups (superpixels) to facilitate advanced object-manipulation and recognition tasks performed by mechanical end effectors in robotic systems. The single-sensors/superpixels are spatially arrayed over contact surfaces of the end effector fingers and include, e.g., pressure sensors and vibration sensors that facilitate the simultaneous detection of both static and dynamic events occurring on the end effector, and optionally include proximity sensors and/or temperature sensors. A readout circuit receives the sensor data from the superpixels and transmits the sensor data onto a shared sensor data bus. An optional multimodal control generator receives and processes the sensor data and generates multimodal control signals that cause the robot system's control circuit to adjust control operations performed by the end effector or other portions of the robot mechanism and when the sensor data indicates non-standard operating conditions.

The present technology relates to an information processing apparatus, an information processing method, and a program that allow stable grasping of an object.

An information processing apparatus according to the present technology includes a detection unit that detects a slip generated on an object grasped by a grasping part, and a coordinative control unit that controls, according to the slip of the object, movement of a whole body of a robot in coordination, the robot including the grasping part. The coordinative control unit controls movement of each of configurations that constitute the whole body of the robot, the configurations including at least a manipulator part to which the grasping part is attached, and a mobile mechanism of the robot. The present technology can be applied to a mobile manipulator that grasps an object.

A robot capable of performing precise work is provided.

The robot includes an actuator unit and an end effector provided at a tip of the actuator unit.

The end effector includes a first sensor capable of detecting a pressure distribution in a contact region coming into contact with a workpiece, and a second sensor capable of detecting position information of the contact region.

A robot capable of performing precise work is provided.

The robot includes an actuator unit and an end effector provided at a tip of the actuator unit.

The end effector includes a first sensor capable of detecting a pressure distribution in a contact region coming into contact with a workpiece, and a second sensor capable of detecting position information of the contact region.

A robot system is provided, which includes a robot body including, robot arm and an end effector attached to robot arm, and operating device, having operating part and configured to output, when operating part is operated, operational information according to operation, a motion controller configured to control operation of robot body according to the operational information outputted from the operating device, a velocity detector configured to detect a velocity at a tip end of the end effector, a virtual reaction-force information generating module configured to output force information containing a first force component having a positive correlation to the velocity at the tip end of the end effector, as virtual reaction-force information, and a force applying device configured to give a force to the operating part in order to make an operator perceive a force according to the virtual reaction-force information outputted from the virtual reaction-force information generating module.