A method for controlling an ambulatory exoskeleton (1) linked to a user (100), comprising the following steps: —measuring only the vertical component (Z.sub.Ng, Z.sub.Nd) of the pressure (R.sub.d, R.sub.g) under each foot (123, 133) of the user (1); —controlling actuators (40, 41, 42, 43) such that the vertical component (Z.sub.Ed, Z.sub.Eg) of the resultant of the balancing forces (R.sub.Eg, R.sub.Ed) applied to the exoskeleton (1) and exerted by each foot (23, 33) of the exoskeleton (1) on the ground is a function of the vertical component (Z.sub.Ng, Z.sub.Nd) of the pressure (R.sub.d, R.sub.g) measured under the corresponding foot (123, 133) of the user (100).

A robotic system for presenting a payload within a workspace includes a pair of serial robots configured to connect to the payload, a parallel robot coupled to a distal end of one of the serial robots such that the parallel robot is disposed between the distal end and the payload, a sensor situated within a kinematic chain extending between the distal end and the payload, and a robot control system (RCS). The sensor outputs a sensor signal indicative of a measured property of the payload. The RCS includes a coordinated motion controller configured to control the serial robots, and a corrective motion controller configured to control the parallel robot. Parallel robot control occurs in response to the sensor signal concurrently with control of the serial robots in order to thereby modify the property of the payload in real-time.

Techniques are disclosed to use a robotic arm to palletize or depalletize diverse items. In various embodiments, data associated with a plurality of items to be stacked on or in a destination location is received. A plan to stack the items on or in the destination location is generated based at least in part on the received data. The plan is implemented at least in part by controlling a robotic arm of the robot to pick up the items and stack them on or in the receptacle according to the plan, including by for each item: using one or more first order sensors to move the item to a first approximation of a destination position for that item at the destination location; and using one or more second order sensors to snug the item into a final position.

Methods, systems, and apparatus, including computer programs encoded on computer storage media, for performing automated safety procedures for a robot. One of the methods includes receiving, by a robotic control system for a robot, a request to execute an automated safety procedure by a safety control subsystem for the robot. Each step of the automated safety procedure is iterated until an end of the automated safety procedure is reached, including if a step requires a new safety configuration, a respective safety configuration for the step is obtained and activated before performing one or more automatic actions for the step.

A robotic system and methods are disclosed. A common axis is defined for an instrument and an energy applicator extending from the instrument. A manipulator has a plurality of links and actuators configured to move the links to position the instrument and energy applicator. A force/torque sensor coupled to the manipulator generates an output in response to forces/torques applied to the instrument. Controller(s) defines a centering point that intersects the common axis. Controller(s) model the instrument and the energy applicator as a virtual rigid body and determine forces/torques to apply to the virtual rigid body, which are determined, in part, based on the output of the force/torque sensor. Controller(s) control the manipulator to advance the energy applicator based on the determined forces/torques applied to the virtual rigid body and reorient the instrument such that the common axis pivots about the centering point during advancement of the energy applicator.

A method and arrangement for testing and/or correction of a weld (34, 36, 38) of a test object (26, 102), including alignment of an ultrasonic probe (16, 128) guided by a robot (100) on a target position of the weld (28, 30, 32), determination of the actual position (34, 36, 38) of the weld by means of an optical sensor (22, 130) and alignment of the ultrasonic probe (16) on the actual position, and measurement of the weld, where CAD data of the target position of the weld (28, 30, 32) is made available, on the basis of the CAD data of the weld the ultrasonic probe (16, 128) is aligned on the target position of the weld, and the ultrasonic probe is placed on the weld with controlled force after determination of the actual position (34, 36, 38) of the weld by means of the optical sensor (22, 130).

A method of controlling an industrial robot, the method including visualizing a nominal path of the industrial robot, the nominal path being associated with a nominal trajectory of the industrial robot; visualizing indications of values of at least one parameter of the industrial robot as when executing the nominal trajectory, for evaluating a risk potential of a physical contact between the industrial robot and a human; receiving a user input related to the nominal trajectory; modifying the nominal trajectory based on the user input to provide a modified trajectory; and executing the modified trajectory by the industrial robot. A control system and an industrial robot are also provided.

When performing work on a workpiece with a tool of a robot while the robot and the workpiece are moved relative to each other by an additional axis mechanism, the tool is to be pressed against the workpiece from an appropriate direction. A control device includes an additional axis movement amount acquisition section that acquires an additional axis movement amount, a command generation section that generates a movement command for a robot based on operation plan data of the robot and the additional axis movement amount, a vector acquisition section that, based on the operation plan data or the additional axis movement amount, acquires a vector in a direction along a work target portion of a workpiece, and a pressing direction determination section that determines a pressing direction in which the robot is to press the tool against the workpiece during work, using the vector acquired by the vector acquisition section.

A robot includes a plurality of joints including a first joint and a second joint, wherein each of the first joint and the second joint including a first support member, a second support member facing the first support member and configured to be displaceable relative to the first support member, an elastic member configured to connect the first support member and the second support member, and a torque sensor including a detection unit configured to detect a relative displacement amount between the first support member and the second support member, and wherein a number of the elastic members of the torque sensor in the first joint is different from a number of the elastic members of the torque sensor in the second joint.

A robot system for human-robot collaboration is disclosed that includes one or more proximity sensing elements disposed on the movable parts of the robot, joint position sensing sensors, and a safety control module connects the proximity sensing element and joint position sensing sensors and monitors the speed of the robot and the proximity distance to the objects and stop the robot safely when speed exceed the set limit. The safety control module switches the safety status of the robot when a set proximity distance threshold is triggered. Then, multiple embodiments of the safety status triggered by proximity sensing are introduced for different processes of the human-robot collaboration, includes separation monitoring, force limiting for bumping, and manipulation of the robot. Furthermore, embodiments of utilizing different types of sensors to implement the proximity sensing elements are also disclosed.