Robotic systems with griping mechanisms, and related systems and methods are disclosed herein. In some embodiments, the robotic system includes a robotic arm and an end-of-arm tool coupled to the robotic arm. The end-of-arm tool can include a housing, a vacuum-gripping component, and a clamping component. The vacuum-gripping component can be operably coupled to a lower surface of the housing to apply a suction force to an upper surface of a target object. The clamping component can include first and second clamping elements. The first clamping element projects at least partially beneath the lower surface of the housing and is movable along a lateral axis to engage a first side surface of the target object. Similarly, the second clamping element projects at least partially beneath the lower surface of the frame and is movable along the lateral axis to engage with a second side surface of the target object.

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.

A robot hand includes a motor, claws configured to grip a workpiece in accordance with rotation of the motor, an encoder configured to detect a rotational position of the motor, and a control device configured to control a torque of the motor such that the claws grip the workpiece in accordance with the rotational position.

A robotic system comprising a master robotic system, and a first robotic system comprising a first mobile platform operable to move about a surface, and comprising a first manipulator. The robotic system can comprise a second robotic system comprising a second mobile platform operable to move about the surface, and comprising a second manipulator. A control module can be associated with the master robotic system and the first and second robotic systems, and can be operable in a paired control mode to facilitate paired control of the first and second robotic systems to move about the ground surface, and operable in an unpaired control mode to facilitate non-paired control of a selected one of the first or second robotic systems.

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.

A gripper with at least one gripping jaw is provided. The at least one gripping jaw includes a base, a gripping portion configured to contact an object, a flexible member connecting the base and the gripping portion, and a sensor assembly located between the base and the gripping portion. The flexible member is configured to enable the gripping portion to deflect with respect to the base when the gripping portion is subjected to a force in a first direction from the object. The sensor assembly is configured to generate a signal in response to the deflection of the gripping portion.

A system is provided for determining a loading location of a workpiece relative to a holding fixture, comprising: a robot including a sensor; and a controller coupled to the robot and configured to activate the robot to grip the workpiece; enable a free-drive mode to permit an operator to move the gripped workpiece to a starting location; execute a center location routine including causing the robot to: move in a first direction until the sensor senses contact with a first surface of the holding fixture; move in a second direction until the sensor senses contact with a second surface; move in a third direction until the sensor senses contact with a third surface; and compute a three-dimensional center point of the holding fixture representing the loading location of the workpiece using the first, second and third sensed positions of contact.

A controller of a robot system performs first control of controlling a robot arm in accordance with an operation with an operator to thereby cause an end effector to apply a treatment to an object and of recording trajectory data and second control of controlling the robot arm based on the trajectory data recorded in the first control to thereby move the end effector such that the end effector reproduces a moving trajectory and applies a treatment to the object. In the second control, in controlling the robot arm based on the trajectory data, the controller controls a pressing force of the end effector against the object.

A gripper system having tentacles including a control system configured to receive operator data and sensor data. Compare stored object configurations associated with grips to identify a corresponding set of object configurations using a target object shape and a pose via sensor data and select an object configuration. Compare stored commands to identify sets of commands corresponding to the object configuration and select sets of commands. If a set of pickup actions are received, compare to the corresponding object configuration to identify a set of pickup actions using the received set of pickup actions, and select a set of pickup actions. Compare the sets of commands to identify a corresponding first set of commands corresponding to a set of pickup actions using the set of pickup actions and select the first set of commands. If the received set of pickup actions are absent, then select a second set of commands.

[Object] To provide a control apparatus, a robot apparatus, a control method and a program for a robot apparatus that can detect and grip an end portion of a piece of cloth not spread.

[Solving Means] A control apparatus according to an embodiment of the present technology includes an acquisition unit, an operation command generation unit, and a determination unit. The acquisition unit acquires an output of a first pressure distribution sensor arranged on a gripping surface of a first hand and an output of a second pressure distribution sensor arranged on a gripping surface of a second hand. The operation command generation unit generates a first gripping command for causing the second hand to grip a first predetermined portion of the flexible thin object gripped by the first hand and a first movement command for moving the second hand relative to the flexible thin object in a predetermined direction from the first predetermined portion while keeping a gripping operation of the flexible thin object by the second hand. The determination unit determines whether or not the second hand reaches an end portion of the flexible thin object on the basis of the output of the second pressure distribution sensor.