Abstract: A robot picking system includes a robot including a gripper that picks up a target work in a first stocker accommodating a plurality of works, a control device that controls an operation of the robot, and an image acquiring device that acquires image data including information related to the target work. The control device includes a trajectory calculating unit that sets a first trajectory including a first zone in which a posture of the gripper is changed and a second zone in which the gripper having the changed posture approaches the target work that is a picking-up target.

Abstract: The present disclosure relates to a system, method and article which may be configured to autonomously dispense a medium onto a relatively large surface relatively accurately.

Abstract: A mobile robot operable to move on a surface in a room is provided. The mobile robot includes a shell and a chassis including at least two wheels. At least one motor is connected to the wheels for moving the mobile robot on the surface. A cleaner is operable to clean the surface as the mobile robot moves on the surface. A wall sensor is operable to detect a wall in the room as the mobile robot moves on the surface. A controller is operable to control the motor to move the mobile robot on the surface in accordance with a wall following mode and a bounce mode. In the wall following mode, the mobile robot moves generally adjacent to and along the wall in response to detection of the wall by the wall sensor. In the bounce mode, the mobile robot moves away from the wall.

Abstract: In accordance with aspects of the present invention, a service robot, such as a robotic cleaner, can be configured to more effectively service an environment. The service robot can include one or more sensors that sense its location, the location of objects, or both, and can also include noise reduction elements. The service robot can determine that it is under a “furnishing” and implement a different servicing pattern.

Abstract: A robot and a method for controlling the same are provided. The robot includes a first control unit to control the overall operation of the robot and a second control unit to supplement the function of the control unit in preparation for the malfunction of the first control unit such that the second control unit controls the robot to perform a predetermined safety-considered motion when the first control unit malfunctions.

Abstract: A robotic mapping method includes scanning a robot across a surface to be mapped. Locations of a plurality of points on the surface are sensed during the scanning. A first of the sensed point locations is selected. A preceding subset of the sensed point locations is determined. The preceding subset is disposed before the first sensed point location along a path of the scanning. A following subset of the sensed point locations is determined. The following subset is disposed after the first sensed point location along the path of the scanning. The first sensed point location is represented in a map of the surface by an adjusted first sensed point location. The adjusted first sensed point location is closer to each of the preceding and following subsets of the sensed point locations than is the first sensed point location.

Abstract: The invention is related to methods and apparatus that use a visual sensor and dead reckoning sensors to process Simultaneous Localization and Mapping (SLAM). These techniques can be used in robot navigation. Advantageously, such visual techniques can be used to autonomously generate and update a map. Unlike with laser rangefinders, the visual techniques are economically practical in a wide range of applications and can be used in relatively dynamic environments, such as environments in which people move. One embodiment further advantageously uses multiple particles to maintain multiple hypotheses with respect to localization and mapping. Further advantageously, one embodiment maintains the particles in a relatively computationally-efficient manner, thereby permitting the SLAM processes to be performed in software using relatively inexpensive microprocessor-based computer systems.

Abstract: The present invention provides an automated steering wheel leveling system and method. Particularly, the automated steering wheel leveling system includes a machine vision, a plurality of motor cylinders, a motor, and a robot, each operated by a process PC. The machine vision photographs a steering wheel to obtain position information of the steering wheel and determines a stroke of a motor cylinder and a grip position of a gripper using the position information. The plurality of motor cylinders move a plurality of grippers to steering wheel to secure the steering wheel. The motor rotates the steering wheel in order to adjust a zero-point of the steering wheel. The robot then moves the machine vision, the motor cylinder, and the motor to the steering wheel to align a shaft of the servo motor with a shaft of the steering wheel.

Abstract: A control system for and methods of controlling a product delivery system are provided.

Abstract: The invention is related to methods and apparatus that use a visual sensor and dead reckoning sensors to process Simultaneous Localization and Mapping (SLAM). These techniques can be used in robot navigation. Advantageously, such visual techniques can be used to autonomously generate and update a map. Unlike with laser rangefinders, the visual techniques are economically practical in a wide range of applications and can be used in relatively dynamic environments, such as environments in which people move. One embodiment further advantageously uses multiple particles to maintain multiple hypotheses with respect to localization and mapping. Further advantageously, one embodiment maintains the particles in a relatively computationally-efficient manner, thereby permitting the SLAM processes to be performed in software using relatively inexpensive microprocessor-based computer systems.

Abstract: The present disclosure generally relates to a method for performing industrial automation control in an industrial automation system. As such, the method may include detecting, via a sensor system, positions and/or motions of a human. The method may then include determining a possible automation command corresponding to the detected positions and/or motions. After determining the possible automation command, the method may implement a control and/or notification action based upon the detected positions and/or motions.

Abstract: The present disclosure generally relates to a method for performing industrial automation control in an industrial automation system may include detecting, via a sensor system, positions and/or motions of one or more humans and/or one or more objects in an industrial automation system and distinguishing, via a programmed computer system, between one or more humans and one or more objects based upon the detected positions and/or motions. The method may then include implementing a control and/or notification action based upon the distinction.

Abstract: An apparatus, method and computer-readable medium planning a path of a robot by planning an optimal path while satisfying a dynamic constraint. In a process of searching for a motion path from a start point to a goal point while extending a tree from a start point of a configuration space to generate a path, along which a manipulator of the robot is moved in order to perform a task, an optimal path is generated responsive to the dynamic constraint of the manipulator of the robot to generate stable motion satisfying momentum and Zero Moment Position (ZMP) constraint. Accordingly, path planning performance is improved and a path satisfying a kinematic constraint and a dynamic constraint is rapidly obtained.

Abstract: A methodology for using cortical signals to control a multi jointed prosthetic device for direct real-time interaction with the physical environment, including improved methods for calibration and training.

Abstract: Methods for controlling at least two robots having respective working spaces, including at least one region in common are disclosed. The working space of each robot is modelled by defining one or more interference regions each constituted by an elementary geometrical figure. The interference regions are classified as: prohibited interference regions, defined as regions of space where the presence of the robot must without fail always be inhibited; monitored interference regions, defined as regions of space where the presence of the robot is accepted, but controlled, the robot being pre-arranged for sending a signal to the central control unit whenever it enters a monitored region and whenever it exits from a monitored region; and hybrid interference regions that are able to change between a status of monitored region and a status of prohibited region as a function of an input signal to the robot sent by said central control unit.

Abstract: The subject disclosure is directed towards a robot device including a model that controls a robot's task-related operations to perform tasks and user-engagement operations to interact with the robot. The model controls the operating states, including transitioning from an autonomous task state to an engaged state based on current context determined from various stimuli, e.g., information received via sensors of the robot and/or learned data. The robot may seek to engage the user, the user may seek to engage the robot, or the user and robot may meet by chance in which either may attempt to initiate the engagement.

Abstract: A robot comprises an arm having at least one joint comprising a joint driving means, the joint driving means having a plurality of actuation lanes; and a fault detection and isolation (FDI) system adapted to detect a fault in any one of the actuation lanes. The fault detection and isolation system in some embodiments is operable to isolate the or each actuation lane exhibiting the fault, and/or the robot is provided with a local control system connected to the fault detection and isolation system, the control system being operable to control the operation of the joint and to maintain, at least partially, operation of the joint when a fault is detected.

Abstract: Provided is a method including receiving information on a surrounding situation detected by the mobile robot; detecting birds from the received surrounding situation information; allocating a birds control mission to the mobile robot by extracting a birds control pattern corresponding to the surrounding situation; and verifying a result in accordance with performing the allocated birds control mission from the mobile robot. By controlling the birds so as to, in advance, prevent a loss of lives and economical loss which may be caused when the birds collide with airplanes at the airport, it is possible to improve productivity and efficiency of a birds repelling job in an airport and provide construction of a new type of aviation maintenance business model by activating an air traffic control industry through providing a safer airplane operating model while saving operating personnel costs for preventing collision of birds.

Abstract: A process includes defining, in a memory, arm-occupied regions including robot arms and a workpiece and tool attached to a robot wrist, a virtual safety protection barrier with which the arms are not allowed to come into contact, and movable ranges of robot axes; estimating the coasting angle of each robot axis for which the axis will coast when the robot is stopped due to an emergency stop while moving to a next target position, from an actually measured amount of coasting and the like; determining a post-coasting predicted position of the robot by adding the estimated coasting angles to the next target position; checking whether or not the arm-occupied regions at the post-coasting predicted position will come into contact with the virtual safety protection barrier, or whether or not the robot axes are within the movable ranges; and performing control to stop the robot immediately upon detection of abnormality.

Abstract: A robot, which performs natural walking similar to a human with high energy efficiency through optimization of actuated dynamic walking, and a control method thereof. The robot includes an input unit to which a walking command of the robot is input, and a control unit to control walking of the robot by calculating torque input values through control variables, obtaining a resultant motion of the robot through calculation of forward dynamics using the torque input values, and minimizing a value of an objective function set to consist of the sum total of a plurality of performance indices through adjustment of the control variables.

Abstract: A method for calibrating a force-controlled, biped humanoid robot. The method includes selecting a kinematic constraint for the humanoid robot such as maintain the two feet in flat contact with the floor. The method includes moving the humanoid robot into a plurality of poses while enforcing the kinematic constraint. The method includes, during the moving or posing step, collecting angle measurements for a set of joints of the humanoid robot and then, with a processor, running a kinematic calibration module to determine angular offsets for the robot joints to allow determination of joint torques by a robot controller with truer angular orientations. The method includes, during the moving step, collecting relative orientation data from an inertial movement unit (IMU) mounted on the pelvis link, and the angular offsets are determined using relative orientation data. All data is collected from devices on the robot, and no external data collection is required.

Abstract: A method of controlling a machine with redundant parallel actuation includes a frame and a mobile element driven by a plurality of mechanical transmissions parallel to one another and each being activated by an actuator (2) including a body fixed to the frame, an actuating member and a position sensor, in which an error signal is produced by comparing the position of each actuator with a setpoint signal, characterized in that the error signals are converted into a mobile element position error signal by applying data representative of the kinematics of the mechanical transmissions, the mobile element error signal is processed by a processing module which produces an effort signal to be applied to the mobile element, the effort signal is converted into signals controlling the actuators by applying data representative of the kinematics of the mechanical transmissions.

Abstract: A grasp assist device includes a glove with first and second tendon-driven fingers, a tendon, and a sleeve with a shared tendon actuator assembly. Tendon ends are connected to the respective first and second fingers. The actuator assembly includes a drive assembly having a drive axis and a tendon hook. The tendon hook, which defines an arcuate surface slot, is linearly translatable along the drive axis via the drive assembly, e.g., a servo motor thereof. The flexible tendon is routed through the surface slot such that the surface slot divides the flexible tendon into two portions each terminating in a respective one of the first and second ends. The drive assembly may include a ball screw and nut. An end cap of the actuator assembly may define two channels through which the respective tendon portions pass. The servo motor may be positioned off-axis with respect to the drive axis.

Abstract: A method for controlling a robot cleaner includes: detecting a cleaning target space, setting a cleaning region within the detected cleaning space and cleaning the set cleaning region; if the set cleaning region is completely cleaned, moving to a not-yet-cleaned region adjacent to a cleaning completion spot of the cleaning region; and setting a new cleaning region in the not-yet-cleaned region and performing cleaning. Without repeating a cleaning region in the cleaning target space, the robot cleaner can extend its cleaning region, so the cleaning efficiency of the robot cleaner can be improved. Also, the robot cleaner can be smoothly enter a new cleaning target space or released therefrom. In particular, even when the entrance of the new cleaning target space is narrow, the robot cleaner can smoothly enter the new cleaning target space and gets out thereof.

Abstract: An apparatus for detecting a contact position where a robot makes contact with an object includes a probe, a probe-position calculating unit, a contact detecting unit, and a contact-position calculating unit. The probe is attached to the robot and is configured to make a displacement in a direction of making contact with the object in an elastic manner. The probe-position calculating unit calculates a position of the probe of the robot in operation. The contact detecting unit detects a contact state of the probe with the object. When the contact state of the probe is detected, the contact-position calculating unit derives the contact position based on a calculated position of the probe.

Abstract: An object is highly precisely moved by an industrial robot to an end position by the following steps, which are repeated until the end position is reached within a specified tolerance: Recording a three-dimensional image by means of a 3-D image recording device. Determining the present position of the object in the spatial coordinate system from the position of the 3-D image recording device the angular orientation of the 3-D image recording device detected by an angle measuring unit, the three-dimensional image, and the knowledge of features on the object. Calculating the position difference between the present position of the object and the end position. Calculating a new target position of the industrial robot while taking into consideration the compensation value from the present position of the industrial robot and a value linked to the position difference. Moving the industrial robot to the new target position.

Abstract: Disclosed is a humanoid robot apparatus, method and computer-readable medium thereof related to lifting and holding a heavy object having a weight unknown to the robot, by measuring an external force acting on the robot. Linear momentum and rotational momentum are compensated for stepwise according to the degree of stability of the robot which is determined based on the measured external force. Accordingly, the robot stably lifts and holds the object without losing its balance.

Abstract: A robot has an operation mode setting unit that sets an operation mode of the robot. The operation mode setting unit changes a correction factor multiplied by the maximum acceleration and the maximum deceleration of an arm and the servo gain of a servo circuit, and thereby selectively sets the operation mode to one of a first operation mode, a second operation mode in which the arm operates faster than in the first operation mode, and a third operation mode in which the arm vibrates less than in the first operation mode.

Abstract: In a legged mobile robot 1 having legs 2, a first landing permissible region and a second landing permissible region for a desired landing position of a distal end portion (a foot 22) of a free leg are determined, and the desired landing position of the free leg foot is determined in a region where the first and second landing permissible regions overlap each other, to thereby generate a desired gait of the robot. The first landing permissible region is determined so as to satisfy a geometric leg motion requisite condition. The second landing permissible region is determined such that a motion continuity requisite condition and a floor reaction force element permissible range requisite condition that are related to a prescribed floor reaction force element as a constituent element of the floor reaction force can be satisfied.

Abstract: The present invention provides an object recognition system for an autonomous mobile body. The object recognition system includes a sensor unit for detecting an obstacle in a target field of view and measuring the position of the obstacle, and an electronic control unit for controlling movement of the autonomous mobile body.

Abstract: A navigational control system for altering movement activity of a robotic device operating in a defined working area, comprising a transmitting subsystem integrated in combination with the robotic device, the transmitting subsystem comprising means for emitting a number of directed beams, each directed beam having a predetermined emission pattern, and a receiving subsystem functioning as a base station that includes a navigation control algorithm that defines a predetermined triggering event for the navigational control system and a set of detection units positioned within the defined working area in a known spaced-apart relationship, the set of detection units being configured and operative to detect one or more of the directed beams emitted by the transmitting system.

Abstract: A robot apparatus includes an arm that includes an outer skin and a detector that detects the deformation of the outer skin. The detector includes a sending unit that sends a signal, a receiving unit that receives the signal, and a transmission route that is provided along the outer skin so as to lead the signal. The detector detects the deformation of the outer skin based on whether a signal reaches the receiving unit.

Abstract: A unloading system for unloading a first workpiece and a second workpiece hanged on different sides of a rack from the rack, the unloading system includes a transferring mechanism, a sliding rod, a rotating assembly, at least two robot arms, at least two unloading mechanisms, and a controller. The transferring mechanism includes a worktable, a transferring assembly mounted on the worktable; and a clamping assembly movably mounted on the transferring assembly. The sliding rod is arranged parallel to a transferring direction of the transferring assembly. The rotating assembly is slidably hanged on the sliding rod and connected to the rack. The at least two robot arms are separately arranged adjacent to the worktable and equipped with sensors. The at least two unloading mechanisms are respectively assembled to the at least two robot arms.

Abstract: A method of operating a mobile robot includes grasping a feature of a door of a doorway with an end effector of a manipulator arm mounted on the robot and driving the robot while grasping the door feature to move the door to an open position. The method also includes driving the robot to maneuver the robot to contact the door and chock the door in the open position, releasing the door feature from the end effector after chocking the door, and driving the robot through the doorway.

Abstract: A torque-based walking robot and a control method thereof which stably controls walking of the robot. In the control method, in which high rigidity, equal to that achieved through a position-based control method, is achieved using a torque-based control method without switching between the position-based control method and the torque-based control method while the robot is in motion, a difference between a target torque and a measured torque is forcibly generated by limiting a torque range measurable by each torque sensor, thereby increasing voltage applied to each actuator, and thus achieving high rigidity, equal to that achieved through the position-based control method, using the torque-based control method without switching between the position-based control method and the torque-based control method.

Abstract: An autonomous cleaning apparatus includes a chassis, a drive system disposed on the chassis and operable to enable movement of the cleaning apparatus, and a controller in communication with the drive system. The controller includes a processor operable to control the drive system to steer movement of the cleaning apparatus. The autonomous cleaning apparatus includes a cleaning head system disposed on the chassis and a sensor system in communication with the controller. The sensor system includes a debris sensor for generating a debris signal, a bump sensor for generating a bump signal, and an obstacle following sensor disposed on a side of the autonomous cleaning apparatus for generating an obstacle signal. The processor executes a prioritized arbitration scheme to identify and implement one or more dominant behavioral modes based upon at least one signal received from the sensor system.

Abstract: A programmable robot system includes a robot provided with a number of individual arm sections, where adjacent sections are interconnected by a joint. The system furthermore includes a controllable drive mechanism provided in at least some of the joints and a control system for controlling the drive mechanism. The robot system is furthermore provided with user a interface mechanism including a mechanism for programming the robot system, the user interface mechanism being either provided externally to the robot, as an integral part of the robot or as a combination hereof, and a storage mechanism co-operating with the user interface mechanism and the control system for storing information related to the movement and further operations of the robot and optionally for storing information relating to the surroundings.

Abstract: A cleaning robot is disclosed. A first sensing unit generates a sensing signal to a transmittal line according to an external wireless signal. When the external wireless signal is sensed by the first sensing unit, a state of the transmittal line does not match with a pre-determined state. When the external wireless signal is not sensed by the first sensing unit, the state of the transmittal line matches with the pre-determined state. A control unit generates a movement signal when the state of the transmittal line matches with the pre-determined state. A plurality of wheels rotate according to the movement signal. A second sensing unit generates a second sensing signal according to the external environment of the cleaning robot. When the state of the transmittal line does not match with the pre-determined state, the control unit adjusts the movement signal according to the second sensing signal.

Abstract: A safety monitoring means for a robot assembly with at least one robot includes a configuration means for configuring a linking function arrangement with at least one first linking function including a fixed and predetermined number of monitoring functions of a monitoring function arrangement. The monitoring functions are logically linked to one another such that the first linking function has a reaction state whenever none of the monitoring functions indicates a not-violated state. The configuration means may further include at least one second linking function including a fixed and predetermined number of monitoring functions that are logically linked to one another such that the second linking function does not have a reaction state whenever all monitoring functions indicate a violated state.

Abstract: A floor cleaning device that is manually trainable for subsequent automatic operation. Prior to automatic operation, a user trains the cleaning device by manually manipulating the device through one or more desired cleaning paths. After training of the device, the device is configured to automatically initiate subsequent cleaning operations in accordance with the trained routine(s). Preferably, the training routine includes user specification of one of a number of cleaning modalities that are supported by the flooring cleaning device. In addition to automatic navigation, the floor cleaning device is configured to initiate a desired cleaning modality as a function of the device's position with respect to one or more of the trained routine(s).

Abstract: A robot and a control method thereof. The control method includes generating and storing plural grasping motions corresponding to data of a target object, selecting a grasping motion corresponding to a grasping purpose of the target object among the plural grasping motions, generating a path of arms corresponding to the selected grasping motion, calculating torques to track the path of the arms, and outputting the torques toward the arms so as to perform movement of the arms and grasping of the target object. The grasping motion path corresponding to the grasping purpose is generated and the path of arms is generated, thereby reducing overall calculation time during grasping of the target object to increase calculating efficiency, minimizing generation of the path of the arms, and allowing an arm path calculating process to be performed at the late stage of a grasping control process to improve grasping performance.

Abstract: An object searching method includes: capturing an image in front of a cleaning robot by a camera. Comparing the image with a number of reference images to determine whether the image is the same as one of the reference images. Storing a position of the cleaning robot and the image when the image is the same as one of the reference images, adjusting the path of the cleaning robot to stop the cleaning robot from cleaning the object; and emitting an alarm.

Abstract: Presented is a method and apparatus comprising one or more robotic members which are curvaceous or snake-like; having movable shapers through which may pass an articulable column having successive joints formed of alternating ball and socket members. The shapers can be directed up and down the articulable column, to create virtually any radius of curvature, in any direction. The robotic member may also include discrete microelectronic mechanical devices (MEMS) shapers with embedded addressable controllers. Thus the device, with computerized control is capable of negotiating a tortuous path to access the site of a given operation and to retreat along the same path, without injury to the body in which the arm is directed. Once at the work site, the articulating columns, or parts of them, may be put in compression, causing them to become rigid.

Abstract: A teaching line correcting apparatus defines a first plane, which is determined by a first reference position of a preset first reference region, a second reference position of a preset second reference region, and a third reference position of a preset third reference region, defines a second plane, which is determined by a detected position of the first reference region, a detected position of the second reference region, and a detected position of the third reference region, calculates a corrective value for equalizing the first reference region to an origin, equalizing the first reference position of the first reference region as the origin to the detected position of the first reference region as the origin, and equalizing the first plane to the second plane, and correcting reference coordinates where operating points are taught based on the calculated corrective value.

Abstract: A method and apparatus for monitoring food consumption by an individual from a food compartment wherein the food compartment may contain or hold solids or liquids. For example, the method includes a sensor to determine the quantity of the solid or liquids located in the food compartment or container. The method contemplates having multiple containers or food compartments wherein a container holds liquids and a food compartment holds solids or semi-solids. By determining the quantity of the food in the food compartment prior to and after the individual has ceased consuming food from the food compartment the amount or quantity of the food can be determined. Knowing the amount or quantity of the food removed from the container the nutritional value of the food may be determined. In addition, a sensor may also monitor the individual removing the food from the food compartment that is monitoring the individual while eating or drinking.

Abstract: A robot obstacle detection system including a robot housing which navigates with respect to a surface and a sensor subsystem aimed at the surface for detecting the surface. The sensor subsystem includes an emitter which emits a signal having a field of emission and a photon detector having a field of view which intersects the field of emission at a region. The subsystem detects the presence of an object proximate the mobile robot and determines a value of a signal corresponding to the object. It compares the value to a predetermined value, moves the mobile robot in response to the comparison, and updates the predetermined value upon the occurrence of an event.

Abstract: A sensor system for use with an automated guided vehicle (AGV) includes a plurality of sensor units electronically coupled to a sensor control module via parallel communications. Each sensor unit may include a sensor array having a plurality of sensor elements, a conditioning circuit having one or more filter/amplifiers, and a conversion circuit. The sensor control module may be configured to communicate with other AGV components via serial communications. The sensor system is capable of obtaining and storing sensor readings with or without associated offset values and can use the sensor readings to determine the center of a magnetic field using methods that require relatively little processing power. A method of calibrating the sensor system may include determining and storing offset values for a plurality of sensor elements and may be performed with the sensor system installed or uninstalled to the AGV.

Abstract: A self-propelled device determines an orientation for its movement based on a pre-determined reference frame. A controller device is operable by a user to control the self-propelled device. The controller device includes a user interface for controlling at least a direction of movement of the self-propelled device. The self-propelled device is configured to signal the controller device information that indicates the orientation of the self-propelled device. The controller device is configured to orient the user interface, based on the information signaled from the self-propelled device, to reflect the orientation of the self-propelled device.

Abstract: Embodiments disclose a vibration-controlled robot apparatus. The apparatus includes a robot having an end effector operable to transport a substrate, a sensor coupled to the robot, the sensor operable to sense vibration as the robot transports the substrate, and operating the robot to reduce vibration of the end effector supporting the substrate. In some embodiments, a filter is provided in the motor drive circuit to filter one or more frequencies causing unwanted vibration of the end effector. Vibration control systems and methods of operating the same are provided, as are other aspects.

Abstract: A cleaning robot and a control method thereof include a main body traveling on a floor, and a first sub-cleaning tool and a second sub-cleaning tool mounted at left and right sides of the main body so as to be protruded from the inside to the outside of the main body and selectively performing cleaning Insertion of at least one of the first sub-cleaning tool and the second sub-cleaning tool is controlled when the main body is rotated under the condition that an obstacle is detected. Side brushes of the sub-cleaning tools are inserted into the main body according to the rotation direction of the main body when the main body is rotated during traveling, thus preventing collision with the obstacle.