Provided is a control device capable of controlling the operation of a control target according to a detected external force. A control device (200) includes a control unit (210-1) that compares a first external force detected by a force sensor provided in a control target and a second external force estimated on the basis of a torque detected by a torque sensor provided in an a movable portion of the control target, the movable portion enabling the force sensor to be movable, and controls the operation of the control target by correcting a torque command value on the basis of a result of the comparison.

A robot system including a master device configured to receive a manipulating instruction from an operator and transmit the received manipulating instruction as a manipulating input signal, a plurality of slave robots configured to operate according to the manipulating input signal transmitted from the master device, a management control device configured to manage operations of the plurality of slave robots, respectively, and an output device configured to output information transmitted from the management control device. The management control device determines a priority of transmitting the manipulating input signal from the master device to the slave robot among the plurality of slave robots that are in a standby state of the manipulating input signal, and transmits information related to the determined priority to the output device. Thus, the operator is able to efficiently transmit the manipulating input signal to the plurality of slave robots through the master device.

Systems and methods presented herein include a robotic wearable device testing system with a track drive system that includes one or more tracks having a plurality of attachment pads configured to attach to one or more wearable devices. Each track of the one or more tracks is configured to move along a path defined by the track. In addition, the robotic wearable device testing system includes a tap point drive system that includes one or more tap point sliders configured to slide laterally with respect to the track drive system. Each tap point slider of the one or more tap point sliders includes a tap point configured to wirelessly communicate with the one or more wearable devices when the one or more wearable devices are in close proximity with the tap point. Each tap point slider of the one or more tap point sliders also includes an electronic interference door configured to block wireless signals between the one or more wearable devices and the tap point. The robotic wearable device testing system also includes control circuitry configured to control relative movement of the one or more tracks and the one or more tap point sliders to position one or more wearable devices attached to respective attachment pads of the plurality of attachment pads in close proximity with a tap point of the one or more tap point sliders, and to control movement of the electronic interference door to allow or block the wireless signals between the one or more wearable devices and the tap point of the one or more tap point sliders.

The present invention relates to a system (100) for active motion displacement control of a robot, the system comprising: In a DCL device (110), which is configured to set a desired position of a portion of a kinematic chain; a MDB device (120), which is configured to generate a motion profile for at least one actor device (130) coupled to the portion of the kinematic chain based on the set in desired position of the portion of the kinematic chain; the actor device (130), which is configured to move the portion of the kinematic chain to an actual position based on the generated motion profile; a sensor device (140), which is configured to measure the actual position of the portion of the kinematic chain and, thereon based, provide position data of the portion of the kinematic chain; wherein the MDB device (120) is further configured to determine an estimated offset and provide a feedback path to a control loop used by the MDB device (120) based on the provided position data of the portion, the desired position of the portion, and the estimated offset.

Plurality of robot main bodies a remote control device including contactless action detecting part configured to detect contactless action including at least one given operation instructing action by operator, and control device communicably connected to remote control device and configured to control operations of plurality of robot main bodies, are provided. Control device includes memory part configured to store operational instruction content data defining operation mode of robot main body corresponding to the at least one operation instructing action, operational instruction content identifying module configured to identify operation mode of robot main body corresponding to one of operation instructing action detected by contactless action detecting part based on operational instruction content data, and motion controlling module configured to control operation of at least one given robot main body among plurality of robot main bodies based on operation mode identified by operational instruction content identifying module.

A robot system which is capable of reducing an operator's workload and easily correcting preset operation of a robot. The robot system includes a robot main body having a plurality of joints, a control device configured to control operation of the robot main body and an operating device including a teaching device configured to teach the control device one of positional information on the robot main body and angular information on the plurality of joints so as to execute an automatic operation of the robot main body and a manipulator configured to receive a manipulating instruction from an operator to manually operate the robot main body or correct the operation of the robot main body under the automatic operation.

One aspect of the present invention provides a robot controller for end portion control of a multi-degree-of-freedom robot. The robot controller comprises: a first control interface, which is positioned at a first position around the robot end portion and receives a first control input for at least for directions; a second control interface, which is positioned at a second position around the robot end portion and receives a second control input for at least four directions; and an encoder, which interprets the combination of the first and second control inputs as a third control input about the robot end portion and provides the robot with a signal according to the third control input.

Apparatus and methods for carpet drift estimation are disclosed. In certain implementations, a robotic device includes an actuator system to move the body across a surface. A first set of sensors can sense an actuation characteristic of the actuator system. For example, the first set of sensors can include odometry sensors for sensing wheel rotations of the actuator system. A second set of sensors can sense a motion characteristic of the body. The first set of sensors may be a different type of sensor than the second set of sensors. A controller can estimate carpet drift based at least on the actuation characteristic sensed by the first set of sensors and the motion characteristic sensed by the second set of sensors.

Methods for characterizing living plants, wherein one or more beams of penetrating radiation such as x-rays are scanned across the plant under field conditions. Compton scatter is detected from the living plant and processed to derive characteristics of the living plant such as water content, root structure, branch structure, xylem size, fruit size, fruit shape, fruit aggregate volume, cluster size and shape, fruit maturity and an image of a part of the plant. Ground water content is measured using the same technique. Compton backscatter is used to guide a robotic gripper to grasp a portion of the plant such as for harvesting a fruit.

A robot system which includes a manipulator configured to receive a manipulating instruction from an operator, a slave arm having a plurality of joints, and a control device configured to control operation of the slave arm. The control device is configured, while the slave arm is operating at a speed equal to or higher than a first given the threshold, even when an operational instruction value for correcting the operation of the slave arm is inputted from the manipulator during an automatic operation of the slave arm, to prevent the correction of the operation of the slave arm.