A robotic platform for traversing and manipulating a modular 3D lattice structure is described. The robot is designed specifically for its tasks within a structured environment, and is simplified in terms of its numbers of degrees of freedom (DOF). This allows for simpler controls and a reduction of mass and cost. Designing the robot relative to the environment in which it operates results in a specific type of robot called a “relative robot”. Depending on the task and environment, there can be a number of relative robots. This invention describes a bipedal robot which can locomote across a periodic lattice structure made of building block parts. The robot is able to handle, manipulate, and transport these blocks when there is more than one robot. Based on a general inchworm design, the robot has added functionality while retaining minimal complexity, and can perform numerous maneuvers for increased speed, reach, and placement.

The present disclosure relates to a brick making system, a production control method, a production control device, a production system, a production equipment, and a computer-readable record medium. The brick making system includes: a brick making machine; a bottom material distribution device connected to one side of the brick making machine to feed bottom material to the brick making machine in a first direction; and a surface material distribution device connected to the other side of the brick making machine adjacent to the one side, to feed surface material to the brick making machine in a second direction. The bottom material distribution device and the surface material distribution device are arranged at adjacent two sides of brick making machine, respectively, so that the occupied space of the brick making system can be reduced.

One embodiment can provide an apparatus. The apparatus can include a robotic arm, a pair of jaws coupled to the robotic arm configured to grip a fabric piece at a pair of predetermined locations, a force sensor coupled to the jaws and configured to measure a tension force applied to the fabric piece by the jaws, and a control module configured to control movements of at least one jaw based on the measured tension force, thereby allowing the fabric piece to be stretched.

A cooking system includes a grill, a first arm assembly and a second arm assembly. An electronic hardware controller is in signal communication with the at least one grill, the first arm assembly and the second arm assembly. The controller operates the first arm assembly to transfer a prepared product to the grill, and operates the second arm assembly to transfer a cooked product from the grill.

A welding assembly for welding a plurality of workpieces includes a positioner assembly including a base assembly and a workpiece holding assembly that is mounted to the base assembly. The workpiece holding assembly includes a beam having a longitudinal axis and a plurality of holding elements that are each mounted to the beam and adapted for holding and positioning a workpiece for welding. The beam is rotatable about a primary axis that is substantially horizontal. The plurality of holding elements are each rotatable about an auxiliary axis that is transverse to the longitudinal axis of the beam.

A method for automatically predetermining an intended movement of a manipulator arrangement of a medical system having a medical instrument and a recording means for generating images, wherein the recording means and/or the instrument is guided by the manipulator arrangement. The method includes establishing an intended transformation between a reference stationary in relation to the recording means and a reference stationary in relation to the instrument; monitoring a deviation between the intended transformation and a current transformation between the reference stationary in relation to the recording means and the reference stationary in relation to the instrument; and determining a reset movement of the manipulator arrangement for returning the current transformation to the intended transformation when the deviation satisfies a predetermined condition.

A multiple hydraulic robot system for precisely installing a girder according to the present disclosure may comprise: four hydraulic robots connected to both sides of two connection plates which are coupled to both ends of the top surface of a girder installed between bridge piers and to which cables of a crane are connected, wherein the robots move the girder horizontally and vertically; a hydraulic system for operating actuators of the four hydraulic robots; and a controller which controls the remotely operated four hydraulic robots by means of a synchronization control algorithm to precisely adjust the installing position of the girder.

A control system for a compliant robotic system including at least two compliant robots having actuator packs, the control system including: an individual local control system associated with each actuator pack, the local control system providing control signals to the actuator causing movement within the robots, an overall control system controlling the overall motion of robots when proximate within a workspace, the overall control signal providing signals to the actuators associated with the robots, so as to cause linked movement of the continuum arm robots, and wherein each individual control system is provided with a clock synchronized with the other, and wherein the overall control system is provided with a redundancy control system that limits the motion of the compliant robots within certain degrees of freedom, so that the motion of the at least two complaint robots does not conflict when operating under the overall control system.

Multi-target libraries, projects, and activities for robotic process automation (RPA) are disclosed. Some embodiments multiple target platforms can be handled in the same project. The target platform(s) can be specified at the automation and/or activity level in order to provide the supported functionality for each. This may also allow previously built automations to be applied to new target frameworks without starting from scratch.

A robot system control method includes a first step through a fifth step. Particularly in the second step, a second transformation matrix that represents the positional relation between a first slave robot and a second slave robot is generated and stored in a master robot. In the fourth step, based on a second command obtained using a first transformation matrix and the second transformation matrix, the master robot instructs the second slave robot to operate. In the fifth step, the first slave robot and the second slave robot perform a cooperative operation with the master robot. Thus, in the state where a working robot that can perform TCP matching with only part of the other robots is set to a master robot, all of the robots can perform a cooperative operation.