A hydraulic forceps system includes: robotic forceps whose gripper is opened and closed by utilizing hydraulic pressure of a hydraulic fluid; a pressure sensor that detects a pressure of the hydraulic fluid; and a control device that calculates a current gripping force of the gripper based on the pressure of the hydraulic fluid detected by the pressure sensor; and a monitor that displays the current gripping force.

A data generation device generates at least a part of data used for a generation of an image displayed on a display unit. The display unit displays a workspace model modeled after an actual workspace, as a video. The workspace model includes a robot model modeled after an actual robot, and a peripheral object model modeled after a given peripheral object around the actual robot. The robot model is created so as to operate according to operation of an operator to a manipulator. The data generation device includes a state information acquiring module configured to acquire state information indicative of a state of the peripheral object, and an estimating module configured to estimate, based on the state information, a state of the peripheral object after a given period of time from the current time point, and generate a result of the estimation as peripheral-object model data used for a creation of the peripheral object model displayed on the display unit.

A robot manipulating system includes a game terminal having a game computer, a game controller, and a display configured to display a virtual space, a robot configured to perform a work in a real space based on robot control data, and an information processing device configured to mediate between the game terminal and the robot. The information processing device supplies game data associated with a content of work to the game terminal, acquires game manipulation data including a history of an input of manipulation accepted by the game controller while a game program to which the game data is reflected is executed, converts the game manipulation data into the robot control data based on a given conversion rule, and supplies the robot control data to the robot.

A remote control robot system includes a slave arm configured to perform a given work, a master arm having a motor configured to drive a joint, and configured to receive from an operator an operation to manipulate the slave arm, an instruction generating module configured to generate an instruction to apply to the master arm an imaginary external force in a given direction that is independent from a force received by the slave arm from the exterior, and a motor controller configured to supply, to the motor, drive current corresponding to the instruction sent from the instruction generating module.

A control device comprising a processor that is configured to execute computer-executable instructions so as to control a robot, wherein the processor is configured to: control a robot with force control on the basis of a force detected by a force detecting device, determine pass/fail of a result of fitting work in which the robot holds an object and fits the object in an object to be fit, control the robot with the force control in the fitting work, and determine the pass/fail on the basis of whether a portion where the force detected by the force detecting device decreases by a first value or more is present in the fitting work.

A gripper provides for gripping labware having a variety of diameters and shapes. The gripper includes a support structure having a center axis, a motor, and a gripper stage. The gripper stage includes a plurality of blades, each of the blades having a) a first end through which a blade rotation axis extends, the blade rotation axis being fixed relative to the support structure and offset from the center axis, b) a second end that is circumferentially and radially moveable to rotate the blade about the blade rotation axis, and c) a center portion. The gripper stage also includes a ring structure coupled to the motor to rotate the ring structure around the center axis. The ring structure, as it rotates, moves the second end of each blade to rotate the blade about the blade rotation axis of the blade to shift the center portion towards the center axis to contact an outer portion of a vessel extending along the center axis.

A robot arm assembly for detecting a pose and force associated with an object is provided. The robot arm assembly includes an end effector having a plurality of fingers, and a deformable sensor provided on each finger. The deformable sensor includes a housing, a deformable membrane coupled to the housing, an enclosure filled with a medium, and an internal sensor disposed within the housing having a field of view directed through the medium and toward an internal surface of the deformable membrane. A processor is configured to receive an output from each internal sensor, the output including a contact region of the deformable membrane as a result of contact with the object. The processor determines an amount of displacement of the contact region based on the output from each internal sensor, and determines the pose and the force associated with the object based on the amount of displacement.

Provided is a tele-operated forceps-driver variable stiffness master device including a master member to generate an input displacement signal generated by pressing with a user's finger, and a slave member to operate based on the input displacement signal, measure operation information, calculate a gripping force based on the operation information, and provide the master member with at least one of a stiffness change command signal or a force feedback based on the calculated gripping force.

A handling apparatus has an arm having a joint; a holding portion attached to the arm and configured to hold an object; a sensor configured to detect a plurality of the objects; and a control apparatus configured to control the arm and the holding portion, wherein the control apparatus is configured to calculate an ease of holding the object by the holding portion as a score based on information acquired by the sensor with respect to each object and each holding method, select the object to hold and the holding method according to the score, and calculate a position for holding the selected object and an orientation of the arm.

An information processing device converts first information for manipulating a robot model inputted into a manipulation terminal connected with a simulation device configured to execute a simulation for causing the robot model to perform a simulated operation and operated by a remote user of the simulation device, into second information for manipulating the robot model of the simulation device, operates the simulation device according to the second information, and causes the manipulation terminal to present information on the operation of the robot model of the simulation device configured to operate according to the second information.