Abstract: A device and method for electrical testing of a component, the component including a contact point, wherein the device includes: an interface to provide the component; a robot manipulator having an effector configured to pick up, handle, and release the component; a receiving interface into which the component is insertable; a contacting device having a counter contact, the contacting device positioned in a first state so that the robot manipulator is able to insert/remove the component into/from the receiving interface, and positioned in a second state so that the counter contact is connected to the contact point of the component inserted into the receiving interface; an analysis unit connected to the counter contact and configured to perform electrical testing of the component using connection of the counter contact and the contact point in the second state; and a control unit to control the robot manipulator and the contacting device.

Abstract: A device to detect medical status of a person, including a robot manipulator to receive and handle effectors, each effector enabling a selected activity; a first unit to determine a current state ZRM(t) of the robot manipulator and a current state of an effector; a second unit to determine a current position LKT,AKTk(t) of a person's body part related to the selected activity in a working region of the robot manipulator; a third unit to determine a wrench KW(t) acting on the robot manipulator; a fourth unit to specify target data and permissible deviations for the selected activity; and a control unit to control the robot manipulator upon specification of the selected activity as a function of: ZRM(t), LKT,AKTk(t), KW(t), target data, and permissible deviations, such that when a permissible deviation is exceeded, the robot manipulator and the effector are placed into a safe state based on the selected activity.

Abstract: A screwing device including: a container for screws; a manipulator having an effector to pick up a screw; an isolating unit connected to the container to provide the screw from the container at an interface such that a head of the screw is accessible to the effector; and a control unit to control the manipulator in executing a control program to perform operations including: guiding the effector along a trajectory having an orientation to the screw head at the interface, wherein the orientation is defined for locations along the trajectory; and executing force-regulated, impedance-regulated, and/or admittance-regulated periodic and closed tilting movements of the effector in relation to its orientation until a condition for a torque, a force, or a time for carrying out the tilting movements is reached or exceeded, and/or a force/torque and/or a position/speed signature at the effector is reached or exceeded, indicating successful pick-up of the screw.

Abstract: A system for performing an input on a robotic manipulator, wherein the system includes: a robotic manipulator having a plurality of limbs connected to one another by articulations and having actuators; a sensor unit configured to record an input variable, applied by a user by manually guiding the robotic manipulator, on the robotic manipulator, wherein the input variable is a kinematic variable or a force and/or a moment, and wherein the sensor unit is configured to transmit the input variable; and a computing unit connected to the robotic manipulator and to the sensor unit, the computing unit configured to transform the input variable received from the sensor unit via a predefined input variable mapping, wherein the input variable mapping defines a mathematical mapping of the input variable onto a coordinate of a graphical user interface or onto a setting of a virtual control element.

Abstract: A method of specifying an input value on a robotic manipulator, wherein the method includes: selecting a particular predefined input device to be emulated, wherein the input device to be emulated is assigned at least one degree of freedom of the robotic manipulator and local limits in the at least one degree of freedom, and a transfer function of a coordinate of the robotic manipulator in the at least one degree of freedom is assigned onto the input value; actuating the robotic manipulator such that at least one part of the robotic manipulator is manually movable in the at least one degree of freedom and within the local limits; recording a respective coordinate in the at least one degree of freedom during or after completion of an input on the robotic manipulator via a sensor unit; and applying the transfer function to assign the respective coordinate to the input value.

Abstract: A robot including a manipulator driven by actuators, and configured to determine external forces and/or external torques acting upon the manipulator, the robot configured to: regulate the actuators for a sub-space T1 of a working space AR such that, upon application of an external force and/or external torque upon the manipulator, the manipulator recedes into T1, wherein following applies: T1?AR and T1?AR, and AR specifies all permitted translations and/or rotations of the manipulator; and determine, for a space TK1 that is complementary to T1, a projection {right arrow over (P)}TK1 of the external force and/or external torque into TK1, wherein following applies: T1?TK1={0}, TK1?AR, and T1?TK1=AR, classify {right arrow over (P)}TK1 into one of several predefined classes with respect to amount and/or direction and/or time curve of {right arrow over (P)}TK1, store a command and/or rule for each predefined class, and regulate the actuators as a function of classification of {right arrow over (P)}TK1 based on res

Abstract: Device for plugging a plug-in region of an expansion board into a plug-in coupling including: a first interface providing the coupling; a second interface providing the board; a robot manipulator having an effector; and a controller controlling the robot manipulator to plug the region into the coupling, the controller configured to execute a program for the robot manipulator to perform operations including: picking up the board at the second interface using the effector; guiding the board along a trajectory and target orientation of the region to the coupling; carrying out tilting motions of the region until reaching or exceeding a limit value condition G1 for a torque acting on the effector and/or a limit value condition G2 of a force acting on the effector, and/or reaching or exceeding a force/torque signature and/or a position/velocity/acceleration signature at the effector, indicating completion of plugging the region into the coupling within predefined tolerances.

Abstract: A device and method for monitoring a motion of a robot manipulator, including operations of: defining a forbidden position for the robot manipulator, defining a curve running along the robot manipulator with a one-dimensional running coordinate s, wherein at least a subset of all locations of the curve is moved together with a current pose of the robot manipulator, and determining a distance d between a location of a current curve and/or a predicted curve and the forbidden position.

Abstract: The invention relates to a device for plugging a plug-in region of an expansion board into a plug-in coupling, the plug-in coupling having a slot, which has a depth T along a depth axis TA and a length L along a longitudinal axis LA, and wherein the depth axis TA and the longitudinal axis LA define a plug-in plane, the device including: a first interface for providing the plug-in coupling; a second interface for providing the expansion board; a first robot manipulator having an effector; and a control unit for the open-loop/closed-loop control of the first robot manipulator, wherein the control unit is configured and designed to execute a control program having the following steps: the first robot manipulator picks up the expansion board at/from the second interface using the effector and guides the expansion board along the specified trajectory T with a specified target orientation Otarget(RT) of the plug-in region to the plug-in coupling provided at the first interface, wherein Otarget(RT) defines the targe

Abstract: The invention relates to a screwing device, including a storage container for screws having a screw head, a screw head drive, and a threaded pin, a robot manipulator having an effector, which is adapted to the screw head and the screw head drive, and is embodied and configured to pick up and handle such a screw, an isolating unit connected to the storage container, which provides screws from the storage container isolated at an interface at a known position in such a way that a respective screw head is accessible to the effector, a control unit for controlling/regulating the robot manipulator, wherein the control unit is embodied and configured to execute the following first control program: the effector is guided by the robot manipulator along a predetermined trajectory T1 having a target orientation Otarget,T1(RT1) to the screw head of a screw provided at the interface, wherein along the trajectory T1 for locations RT1 of the trajectory T1, the target orientation Otarget,T1(RT1) of the effector is defined,

Abstract: The invention relates to a device for the electrical testing of an electrical component (BT), which has a first electromechanical interface (S1), wherein the electrical component (BT) is provided with the first electromechanical interface (S1) thereof at a target position (POSS1) and a target orientation (OS1), the device including: a force-regulated and/or impedance-regulated and/or admittance-regulated first robot manipulator having a first effector, a control unit for controlling/regulating the first robot manipulator, the control unit being designed and constructed to execute the following first control program: controlling the first robot manipulator in such a manner that the first robot manipulator guides the second electromechanical interface (S2) along a predefined trajectory m with a predefined target orientation (Otarget,S2(RT)) to the first electromechanical interface (S1) of the electrical component (BT) provided at the position (POSS1), wherein, upon the mechanical connection of the first electro

Abstract: The invention relates to a device and method for electrical testing of an electrical component, the component including at least one electrical contact point.

Abstract: The invention relates to a robot having: a moving manipulator driven by means of actuators, a first unit for determining external forces and/or external torques acting upon the manipulator, and a second unit for controlling or regulating the actuators as a function of the determined external forces and/or external torques acting upon the manipulator, wherein the second unit is designed to control/regulate the actuators for a predefined sub-space T1 of a working space AR of the manipulator such that the manipulator recedes flexibly into the sub-space T1 upon the application of a determined external force and/or of a determined external torque onto the manipulator along a projection {right arrow over (P)}T1 of the force and/or of the torque, wherein the following applies: T1?AR and T1?AR, and the working space AR specifies all permitted translations and/or rotations of the manipulator, and to determine, for a space TK1 complementary to the sub-space T1, a projection {right arrow over (P)}TK1 of the determined e