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.

The present disclosure relates to a low mass system for releasably securing a robotic arm to a spacecraft and also securing various payloads to the robotic arm and to each other, permitting the robotic arm to be both moved from one location to another suitably equipped location on a spacecraft to another and to allow the free end of the robotic arm to be secured to any payload also similarly equipped such that this payload may be manipulated by the robotic arm.

A kinematic model arithmetic portion calculates a coordinate value (z.sub.e1 (θ.sub.e)) as distance information indicating the distance between a member that serves as a reference surface for the curve shape of a curvable portion and a member in the curvable portion that is closest to the reference surface. A switch determination unit determines based on the coordinate value whether to drive a wire for driving the curvable portion by a drive displacement calculated for the wire along with the coordinate value by the kinematic model arithmetic portion.

A kinematic model arithmetic portion calculates a coordinate value (z.sub.e1 (θ.sub.e)) as distance information indicating the distance between a member that serves as a reference surface for the curve shape of a curvable portion and a member in the curvable portion that is closest to the reference surface. A switch determination unit determines based on the coordinate value whether to drive a wire for driving the curvable portion by a drive displacement calculated for the wire along with the coordinate value by the kinematic model arithmetic portion.

Remote control robot system includes a master device, slave arm having plurality of control modes including automatic and manual mode, control device configured to operate slave arm, an entering-person sensing device configured to detect entering person into operational area of slave arm, entering-person identifying information acquisition device configured to acquire entering-person identifying information for identifying whether entering person is operator who carries master device, and operation regulating device configured to regulate operation of slave arm based on information acquired from entering-person sensing device and information acquisition device. In automatic mode, operation regulating device regulates operation of slave arm when entering person is detected. In manual mode, operation regulating device allows operation of slave arm to continue when entering person is detected and entering person is operator, and regulates operation of the slave arm when entering person is other than operator.

An apparatus including at least one drive; a first robot arm having a first upper arm, a first forearm and a first end effector. The first upper arm is connected to the at least one drive at a first axis of rotation. A second robot arm has a second upper arm, a second forearm and a second end effector. The second upper arm is connected to the at least one drive at a second axis of rotation which is spaced from the first axis of rotation. The first and second robot arms are configured to locate the end effectors in first retracted positions for stacking substrates located on the end effectors at least partially one above the another. The first and second robot arms are configured to extend the end effectors from the first retracted positions in a first direction along parallel first paths located at least partially directly one above the other. The first and second robot arms are configured to extend the end effectors in at least one second direction along second paths spaced from one another which are not located above one another. The first upper arm and the first forearm have different effective lengths. The second upper arm and the second forearm have different effective lengths.

A transport apparatus including a robot drive; an arm having a first end connected to the robot drive; and at least one end effector connected to a second end of the arm. The arm includes at least three links connected in series to form the arm. The arm is configured to be moved by the robot drive to move the at least one end effector among load locks and two or more sets of opposing process modules.

A remote control robot system includes a slave arm, a master main body imitating the shape of an object handled by the slave arm, a manipulation receiving device configured to receive manipulation of an operator based on the position and posture of the master main body, and a control device configured to control operation of the slave arm based on the manipulation received by the manipulation receiving device so that behavior of the object corresponds to behavior of the master main body.

A remote-control manipulator system includes a manipulator configured to receive a manipulating instruction from an operator, a slave arm configured to perform a series of works comprised of a plurality of processes, a camera configured to image operation of the slave arm, a display device configured to display an image captured by the camera, a storage device configured to store information related to environment in a workspace as an environment model, and a control device. The control device is configured, while operating the slave arm manually or hybridly, to acquire circumference information that is information related to a circumference area of an area imaged by the camera based on the environment model stored in the storage device, and display on the display device so that the image captured by the camera and the circumference information are interlocked.

The present disclosure relates to a low mass system for releasably securing a robotic arm to a spacecraft and also securing various payloads to the robotic arm and to each other, permitting the robotic arm to be both moved from one location to another suitably equipped location on a spacecraft to another and to allow the free end of the robotic arm to be secured to any payload also similarly equipped such that this payload may be manipulated by the robotic arm.