Apparatus and methods for providing a surgical table base with sufficient stiffness and adjustable support members with force feedback are described herein. In some embodiments, a base for a surgical table includes a base body to which other components of a surgical table can be coupled. A surgical table, and optionally a patient supportable by the surgical table, and any equipment to be carried by the surgical table, collectively representing a table load to be carried by the base body to support the surgical table on a surface. The base further includes a support assembly coupled to the base body to support the base body on the surface. The support assembly includes at least four support members. Each support member has a surface-engaging end and can transmit a portion of a total load represented by the weight of the base and the table load through the surface-engaging end to the surface. The surface-engaging ends of any three of the four support members define a plane. One of the support members is adjustable to move the one support member relative to a plane defined by the three of the other support members and thereby to change the portion of the total load carried by one of the support members. The base further includes a load sensor operably coupled to the support assembly and disposed to detect the portion of the total load carried by one of the support members.

A substation containing a switch-gear or control-gear system, in particular a switch-gear or control-gear system includes at least one low voltage switch-gear or control-gear, with unmanned operation and maintenance. The inner room, where the switch-gear or control-gear are located in, is hermetically enclosed by an outer housing, the switch-gear or control-gear system is provided for unmanned operation and maintenance with a robotic system or manipulator, and/or the robotic system or manipulator is provided with a camera system, and/or an image recognition system and/or the inner room is locked against the outer housing by an inner, automatically operated door, and/or the robot system is implemented in such, that the robot systems acting area is extended from the inner room, partly in the area outside the inner room, but inside the outer housing, where spare parts are stored in a spare parts hand over area.

A method includes controlling a robot body performed by a controller. The robot body includes a finger, a driving unit, and a detection unit. The driving unit is configured to move the finger. The detection unit is configured to output a signal corresponding to a state of the finger moved by the driving unit. The method includes causing the finger to hold a workpiece, causing the robot body to start a predetermined operation while causing the finger to keep holding the workpiece, if a detected value based on the signal outputted from the detection unit is within a first range, and causing the robot body to continue to perform the predetermined operation until completion of the predetermined operation, if the detected value is within a second range in the predetermined operation. The second range is different from the first range.

Example implementations may relate to a robotic system configured to provide feedback. In particular, the robotic system may determine a model of an environment in which the robotic system is operating. Based on this model, the robotic system may then determine one or more of a state or intended operation of the robotic system. Then, based one or more of the state or the intended operation, the robotic system may select one of one or more of the following to represent one or more of the state or the intended operation: visual feedback, auditory feedback, and one or more movements. Based on the selection, the robotic system may then engage in one or more of the visual feedback, the auditory feedback, and the one or more movements.

A controller for controlling a plurality of robots includes a failure prediction section configured to predict a failure time for each of the robots; and a load adjustment section configured to perform adjustment of a work load of each of the robots according to each of the predicted failure times, so that each of the robots operates until a maintenance time determined in common to each of the robots.

A transport device has a position detection portion, a holding portion attached to an arm, a driving portion to drive the holding portion and the arm, and a control portion. A control portion controls the position detection portion and the driving portion to perform, as one cycle, a procedure to detect a position of a parcel, select parcels based on a predetermined condition, and set priority for the selected parcels, and a procedure to refer to a result of the detection, and cause the holding portion to take out one or more parcels from the accumulation portion in accordance with the priority to transport the parcels to a predetermined location, and excludes, from parcels to be taken out, a second parcel that is present within a predetermined distance from a first parcel and has priority lower than the priority of the first parcel, during the one cycle.

Example implementations may relate to a robotic system configured to provide feedback. In particular, the robotic system may determine a model of an environment in which the robotic system is operating. Based on this model, the robotic system may then determine one or more of a state or intended operation of the robotic system. Then, based one or more of the state or the intended operation, the robotic system may select one of one or more of the following to represent one or more of the state or the intended operation: visual feedback, auditory feedback, and one or more movements. Based on the selection, the robotic system may then engage in one or more of the visual feedback, the auditory feedback, and the one or more movements.

A system includes a controller to provide at least one control output to an automated system in response to a control command received at a control input of the controller. The control output controls the operation of the automated system based on the control command. A signature analyzer generates the control command to the controller and receives an impedance signature related to a property of a material or object encountered by the automated system. The signature analyzer compares the impedance signature to at least one comparison signature to determine the property of the material or object. The signature analyzer adjusts the control command to the controller to control the operation of the automated system based on the determined property.

A controller for a parallel link mechanism includes a drive control unit that controls driving of a parallel link mechanism and a command section that gives a command for controlling an actuator to the drive control unit. The command section includes a natural frequency prediction unit that calculates a predicted value string of a natural frequency changing depending on the position of an end effector for each interpolation position of the end effector by using a dynamic model that simulates a mechanical system from a base to a link joint of the parallel link mechanism with a translational spring and simulates a mechanical system from the link joint to the end effector with one rigid body. The drive control unit includes a filter that changes a frequency component to be suppressed for each interpolation positions according to a predicted value string at each interpolation position of the end effector.

A controller for controlling a plurality of robots includes a failure prediction section configured to predict a failure time for each of the robots; and a load adjustment section configured to perform adjustment of a work load of each of the robots according to each of the predicted failure times, so that each of the robots operates until a maintenance time determined in common to each of the robots.