Abstract: A finite state machine (FSM)-based biped robot, to which a limit cycle is applied to balance the robot right and left on a two-dimensional space, and a method of controlling balance of the robot. In order to balance an FSM-based biped robot right and left on a two-dimensional space, control angles to balance the robot according to states of the FSM-based biped robot are set. The range of the control angles is restricted to reduce the maximum right and left moving distance of the biped robot and thus to reduce the maximum right and left moving velocity of the biped robot, thereby reducing the sum total of the moments of the biped robot and thus allowing the ankles of the biped robot to balance the biped robot to be controlled, and causing the soles of the feet of the biped robot to parallel contact the ground.

Abstract: An finite state machine (FSM)-based biped walking robot, to which a limit cycle is applied to balance the robot right and left on a two-dimensional space, and a method of controlling balance of the robot. In order to balance an FSM-based biped walking robot right and left on a two-dimensional space, control angles to balance the robot according to states of the FSM-based biped walking robot are set, and the control angles are controlled using a sinusoidal function to allow relations between the control angles and control angular velocities to form a stable closed loop within a limit cycle, thereby allowing the biped walking robot to balance itself while changing its supporting foot and thus to safely walk without falling down.

Abstract: An autonomous mobile robot device, comprises an obstacle detecting unit, which is configured to detect an obstacle, a path producing unit, which is configured to produce a path for reaching to a goal while avoiding the obstacle, which is detected by the obstacle detecting unit, upon basis of a predetermined avoidance method, and a moving unit, which is configured to move while mounting the obstacle detecting unit and the path producing unit thereon, and further comprises an avoidance method noticing unit, which is configured to notice information relating to an avoidance method of the autonomous mobile robot device itself to the obstacle, which is detected by the obstacle detecting unit, an other's avoidance method obtaining unit, which is configured to obtain information relating to the avoidance method of the obstacle from the obstacle, which is detected by the obstacle detecting unit, an avoidance method memorizing unit, which is configured to memorize one or more of the avoidance method(s) determined, to

Abstract: A process for working a contour on at least one workpiece using a robot includes positioning the workpiece relative to the robot; acquiring an actual position of the workpiece; acquiring a real course of the contour on the workpiece at predefined points using at least one sensor; and actuating the robot according to individual vectors so as to correct a robot motion during the working of the contour.

Abstract: A robot and method to recognize and handle abnormal situations includes a sensing unit to sense internal and external information of the robot, a storage unit to store the information sensed by the sensing unit, an inference model, a learning model, services providable by the robot, subtasks to provide the services, and handling tasks to handle abnormal situations, and a controller to determine whether an abnormal situation has occurred while the subtasks to provide the selected service are being performed through the learning model in the storage unit and to select a handling task to handle the abnormal situation through the inference model in the storage unit if it is determined that the abnormal situation occur. The robot may recognize and handle abnormal situations even though data other than that defined by a designer of the robot is input thereto due to noises or operational environment.

Abstract: Disclosed are a mobile robot and a controlling method thereof. The mobile robot comprises: a case; and a sensor unit having two or more sending portions and two or more receiving portions arranged on an outer surface of the case separately and alternately. The plurality of sending portions and receiving portions are arranged in an alternating manner, thereby having a directivity. Also, since signals received through the receiving portions are judged based on a reference value, an area unallowable to be detected for an obstacle sensing is minimized, which allows an obstacle to be detected more accurately. When the obstacle corresponds to a side wall on the basis of a moving path of the mobile robot, a distance between the side wall and the mobile robot is calculated based on signals received by the receiving portion closest to the side wall. Accordingly, the mobile robot can move with maintaining a constant distance from the side wall.

Abstract: A transfer system according to an embodiment includes a plurality of robot hands, a storage unit, and an instructing part. The robot hands are operable to hold a thin sheet-like workpiece. The storage unit stores therein speed information that represents a temperature of the workpiece associated with a specified speed of a robot hand that holds the workpiece. The instructing part extracts the specified speed for each robot hand from the speed information and instructs to move all of the robot hands at or lower than a representative speed determined based on a set of extracted specified speed data.

Abstract: A robotic system includes a robot adapted for moving a payload in proportional response to an input force from an operator, sensors adapted for measuring a predetermined set of operator input values, including the input force, and a controller. The controller determines a changing stiffness value of the operator using set of operator input values, and automatically adjusts a level of control sensitivity over the robot using the stiffness value. The input values include the input force, a muscle activation level of the operator, and a position of the operator. A method of controlling the robot includes measuring the operator input values using the plurality of sensors, processing the input values using the controller to thereby calculate the stiffness value, and automatically adjusting the level of control sensitivity over the robot using the stiffness value. A specific operator may be identified, with control sensitivity being adjusted based on the identity.

Abstract: An exemplary embodiment of portable electronic device with guide function includes a housing, a processing unit, a command unit, and a guiding unit. The processing unit and the guiding unit are positioned inside the housing, and the command unit is positioned at least partially outside of the housing. The processing unit is electrically connected to the command unit and the guiding unit. Operating the command unit, the portable electronic device with guide function is actuated into guiding mode controlled by the processing unit. The guiding unit sends detection signals to detect obstacles, receives feedback signals from the obstacles, the processing unit receives the feedback signal from the guiding unit to generate corresponding obstacle types and distance according to the feedback signal.

Abstract: An instructed position, which includes an instruction area for receiving a predetermined instruction and is displayable two-dimensionally and three-dimensionally, on a display means where an instruction image is displayed is detected. Upon setting on the display means a control range corresponding to the instruction area displayed on the display means such that the control range is changed between during the two-dimensional display and during the three-dimensional display, information of a tentative instructed position is obtained by receiving an instruction directed to the instruction area during the three-dimensional display. A horizontal shift on the display means of the tentative instructed position during the three-dimensional display relative to a position of the instruction area during the two-dimensional display is calculated.

Abstract: A multi-function robotic device may have utility in various applications. In accordance with one aspect, a multi-function robotic device may be selectively configurable to perform a desired function in accordance with the capabilities of a selectively removable functional cartridge operably coupled with a robot body. Localization and mapping techniques may employ partial maps associated with portions of an operating environment, data compression, or both.

Abstract: The present invention provides a robot system including a robot having a plurality of move axes and a safeguard apparatus provided independently of a control system of the robot and adapted for limiting a movable range of the robot. The safeguard apparatus includes at least two individual-axis-detection external sensors configured to be respectively turned ON/OFF in response to a rotational position or a transfer position of respective at least two move axes among the plurality of move axes of the robot, and an apparatus body configured to limit a move of the robot based on a combination of ON/OFF conditions of at least two output signals obtained from the at least two individual-axis-detection external sensors.

Abstract: A coordinated action robotic system may include a plurality of robotic vehicles, each including a platform and at least one manipulator movable relative thereto. The robotic system may also include a remote operator control station that may include a respective controller for each manipulator. The remote operator control station may also include a mapping module to map movement of each manipulator relative to its platform. Operation of the controllers for manipulator movement in a given direction produces corresponding movement of the respective manipulators in the given direction such that the robotic vehicles may be controlled as if they were one robotic vehicle. The coordinated movement may result in increased operational efficiency, increased operational dexterity, and increased ease of controlling the robotic vehicles.

Abstract: A robot controller in accordance with the present invention is a robot controller that makes a robot including a plurality of legs walk by driving joints of the robot, the robot controller being configured to determine a permissible range for a trunk vertical position of the robot based on measured environmental parameters, the measured environmental parameters being information of an environment around the robot, and to make the robot walk based on measured posture parameters representing a posture of the robot so that the trunk vertical position remains within the permissible range. In this way, a legged robot with high robustness as well as its controller and control method can be provided.

Abstract: A method and apparatus for estimating the pose of a mobile robot using a particle filter is provided. The apparatus includes an odometer which detects a variation in the pose of a mobile robot, a feature-processing module which extracts at least one feature from an upward image captured by the mobile robot, and a particle filter module which determines current poses and weights of a plurality of particles by applying the mobile robot pose variation detected by the odometer and the feature extracted by the feature-processing module to previous poses and weights of the particles.

Abstract: Provided is an apparatus, method, and medium for allowing a mobile robot to simultaneously perform a cleaning process and a map-creating process. The apparatus includes a feature-map-creating unit creating a feature map for recognizing the position of a mobile robot; a path-map-creating unit creating a path map including a plurality of cells, each having information about whether an obstacle exists and path information, on the basis of information on the pose of the mobile robot that is obtained from the feature map; and a motion-control unit moving the mobile robot on the basis of the information about whether the obstacle exists and the path information.

Abstract: A robot includes: an arm; a driving source that pivots the arm; an angle sensor that detects a pivot angle and outputs pivot angle information; an inertia sensor that is attached to the arm and outputs inertial force information; a control command generating unit that outputs a control command defining rotational operation of the arm; a control conversion determining unit that determines whether the inertial force information is used when the driving source is controlled; and an arm operation control unit that performs a first control based on the control command, the pivot angle information, and the inertial force information, if the control conversion determining unit determines that the inertial force information should be used, and performs a second control based on the control command and the pivot angle information, if the control conversion determining unit determines that the inertial force information should not be used.

Abstract: A robot that is capable of traveling while moving an object such that the object and the robot itself will not step out of a predetermined area is provided. If a traveling requirement that the robot and the object remain within a pathway area is not met, then an action scheme of the robot is corrected so as to meet the traveling requirement. Then, the robot travels while moving the object according to the corrected action scheme, thus enabling the robot to travel while moving the object such that both the object and the robot do not step out of the pathway area.

Abstract: A control system for a mobile robot (10) is provided to effectively cover a given area by operating in a plurality of modes, including an obstacle following mode (51) and a random bounce mode (49). In other embodiments, spot coverage, such as spiraling (45), or other modes are also used to increase effectiveness. In addition, a behavior based architecture is used to implement the control system, and various escape behaviors are used to ensure full coverage.

Abstract: A method of classifying and collecting feature information of an area according to a robot's moving path, a robot controlled by area features, and a method and apparatus for composing a user interface using the area features are disclosed. The robot includes a plurality of sensor modules to collect feature information of a predetermined area along a moving path of the robot, and an analyzer to analyze the collected feature information of the predetermined area according to a predetermined reference range and to classify the collected feature information into a plurality of groups.

Abstract: There is provided a control system which controls a link structure constructed by connecting a plurality of rigid body links and driven by making a joint actuator generate an actuator force. The control system includes a mechanical model including geometric parameters and dynamical parameters of the link structure, a virtual external force calculating means for calculating a virtual force acting on the mechanical model of the link structure, a contact part detecting means for detecting contact parts between the link structure and the outside, and an actual force converting means for converting the virtual force calculated by the virtual external force calculating means into an external force capable of existing actually and the actuator force of the joint actuator, using contact information detected by the contact part detecting means. The joint actuator is made to generate the actuator force output by the actual force converting means.

Abstract: A robot cleaner that cleans a cleaning region while traveling the cleaning region and a method to control the same are provided. The robot cleaner can uniformly clean a cleaning region based on a wall-following technique which allows the robot cleaner to travel along the outline of the cleaning region. The method selects, as a reference wall, a wall at a left or right side of the robot cleaner at a start position of the robot cleaner based on a left or right-based travel algorithm, which allows the robot cleaner to travel along a left or right wall, and controls the robot cleaner to travel the cleaning region in a zigzag travel pattern in which the robot cleaner moves a predetermined distance in a direction perpendicular to the reference wall at specific intervals along the selected reference wall while following the selected reference wall.

Abstract: A piezoelectric debris sensor and associated signal processor responsive to debris strikes enable an autonomous or non-autonomous cleaning device to detect the presence of debris and in response, to select a behavioral mode, operational condition or pattern of movement, such as spot coverage or the like. Multiple sensor channels (e.g., left and right) can be used to enable the detection or generation of differential left/right debris signals and thereby enable an autonomous device to steer in the direction of debris.

Abstract: Vector Field SLAM is a method for localizing a mobile robot in an unknown environment from continuous signals such as WiFi or active beacons. Disclosed is a technique for localizing a robot in relatively large and/or disparate areas. This is achieved by using and managing more signal sources for covering the larger area. One feature analyzes the complexity of Vector Field SLAM with respect to area size and number of signals and then describe an approximation that decouples the localization map in order to keep memory and run-time requirements low. A tracking method for re-localizing the robot in the areas already mapped is also disclosed. This allows to resume the robot after is has been paused or kidnapped, such as picked up and moved by a user. Embodiments of the invention can comprise commercial low-cost products including robots for the autonomous cleaning of floors.

Abstract: Vector Field SLAM is a method for localizing a mobile robot in an unknown environment from continuous signals such as WiFi or active beacons. Disclosed is a technique for localizing a robot in relatively large and/or disparate areas. This is achieved by using and managing more signal sources for covering the larger area. One feature analyzes the complexity of Vector Field SLAM with respect to area size and number of signals and then describe an approximation that decouples the localization map in order to keep memory and run-time requirements low. A tracking method for re-localizing the robot in the areas already mapped is also disclosed. This allows to resume the robot after is has been paused or kidnapped, such as picked up and moved by a user. Embodiments of the invention can comprise commercial low-cost products including robots for the autonomous cleaning of floors.

Abstract: A method of controlling a robot includes running multiple applications on a processor, where each application has a robot controller and an action selection engine. Each application is in communication with at least one behavior and at least one action model of at least part of the robot. The method includes running periodic action selection cycles on each action selection engine. Each action selection cycle includes selecting a command for each action space of each action model, generating a single overall command based on the accumulated commands for each action model, and sending the overall command to the robot controller for execution on the robot.

Abstract: A position control method for controlling a position of a movable portion, includes: performing control of allowing the movable portion to approach a predetermined position by moving the movable portion; and performing control of moving the movable portion to the predetermined position by moving the movable portion and detecting a relative position of the movable portion with respect to the predetermined position by using an imaging unit.

Abstract: A light projection device, includes a movable projector section which illuminates or display information by projecting light while moving a projection position; a position detecting section which detects a position of a lost article instructed by a user; a view field detecting section which detects a view field of the user, and a controller section which controls said movable projection section based on the lost article detected by the position detecting section and the view field of the user detected by the view field detecting section, and either directly illuminates the lost article or projects guide information for guiding the user to the lost article within a view field of the user.

Abstract: An object handling method for determining the positions of the arm of a handling system with the aid of a location method which is based on a reference system predetermined by an associated location system. A handling system having a moveable arm. The arm is operational within a fixed reference system using a location system.

Abstract: An apparatus and method for assuring effective backup for sensor failure in robots, by utilizing a single extra sensor attached between the end actuator and the base. The single extra sensor provides absolute back-up for any single encoder failure that may occur in the system, and statistically significant back-up for any double encoder failure. A single additional sensor effectively provides the robotic system with one redundant information input to the robot control algorithm, which can be used in order to determine whether any of the other control sensors, or even the additional sensor itself, has failed and is delivering an erroneous reading, and hence to warn the operator of the failure. A single additional sensor also provides useful warning of the simultaneous failure of two sensors, since the likelihood that two sensors fail simultaneously in a mode that makes the failures undetectable, can be regarded as statistically insignificant.

Abstract: An autonomous mobile device has its movement controlled by a control device and includes a first sensing unit for sensing an obstacle. The control device includes a first storage unit for storing information as to a temporary positional fluctuation of the obstacle and sets as a virtual obstacle region a region where it is predicted that the obstacle sensed by the first sensing unit travels following a predetermined time passage based on the information as to the temporary positional fluctuation of the obstacle stored in the first storage unit.

Abstract: The illustrative embodiments provide a method and apparatus for controlling and coordinating multiple vehicles. In one illustrative embodiment, machine behaviors are assigned to multiple vehicles performing a task. The vehicles are coordinated to perform the task using the assigned behaviors and a number of signals received from other vehicles and the environment during performance of the task. In another illustrative embodiment, a role is identified for each vehicle in a group of vehicles. A number of machine behaviors are assigned to each vehicle depending upon the identified role for the vehicle. The machine behaviors are selected from coordinating machine behaviors stored in a behavior library. Each vehicle is then coordinated to perform the task according to the role and machine behaviors assigned.

Abstract: A robotic mower home finding system includes a charging station connected to an outer boundary wire loop, and a vehicle control unit on the robotic mower that directs a traction drive system to drive the robotic mower along a path offset a specified distance from an outer boundary wire loop toward the charging station. The vehicle control unit changes the specified distance randomly or incrementally so that the robotic mower does not take the same path to the charging station each time.

Abstract: The invention relates to a player humanoid robot, a method and computer programs associated therewith. The prior art does not disclose any humanoid robot able to move on its lower limbs, to perform gestures, to communicate visual and/or audible signs, to receive same and interpret them so as to deduce therefrom appropriate behaviors for participating in a game in time as compere, questioner, questioned, investigator or mobile stake for the game. The hardware architectures, internal software and software for programming the robot of the invention make it possible to carry out these functions and to create new game experiences in which the boundaries between virtual world and real world are shifted once again.

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 robot controlling device includes: a position error calculator calculating a position error between an endpoint position of a robot and a position commanded value for the endpoint position; an external force calculator calculating an external force applied to the endpoint position; a force commanded value generator generating a force commanded value for the endpoint position; a force error calculator calculating a force error between the external force and the force commanded value; a storage storing the compliance model for the endpoint position; a first correction amount calculator calculating a first correction amount for the position commanded value, according to the force error, using the compliance model; and a second correction amount calculator calculating a second correction amount for the position commanded value, on the basis of the first order lag compensation for the first correction amount. The position error calculator calculates the position error, using the second correction amount.

Abstract: A minimally-invasive surgical system includes a slave surgical instrument having a slave surgical instrument tip and a master grip. The slave surgical instrument tip has an alignment in a common frame of reference and the master grip, which is coupled to the slave surgical instrument, has an alignment in the common frame of reference. An alignment error, in the common frame of reference, is a difference in alignment between the alignment of the slave surgical instrument tip and the alignment of the master grip. A ratcheting system (i) coupled to the master grip to receive the alignment of the master grip and (ii) coupled to the slave surgical instrument, to control motion of the slave by continuously reducing the alignment error, as the master grip moves, without autonomous motion of the slave surgical instrument tip and without autonomous motion of the master grip.

Abstract: After switching a control method for a robot arm based upon characteristic information containing pieces of information relating to a grabbed position of the robot arm by a person and a presence/absence of detection of a force as well as to presence/absence of influences from a drag, during an operation of the robot arm, by a control method switching unit, information relating to the force of operation information is corrected by an operation correcting unit in response to a manipulation of the person.

Abstract: A desired motion determiner of a control unit of a legged mobile robot determines a leg motion parameter specifying the motion trajectory of a distal end of a leg of the robot on the basis of the information on a floor geometry of an environment in which the robot travels and a requirement related to a travel route of the robot, thereby sequentially determining the desired motion of the robot. A floor geometry information output unit which outputs floor geometry information to the desired motion determiner outputs floor geometry information in which a rising surface of a stepped portion of a predetermined type, the contact thereof with a leg of the robot should be avoided, has been shaped into a surface having a gentler slope than an actual rising surface. The desired motion determiner determines the leg motion parameter such that the leg will not come in contact with the stepped portion having the shaped rising surface.

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 laser welding system includes a robot control unit that acquires movement amount measurement values from encoders provided on axes of the robot and calculates the current position of a laser processing head based on the measurement values. Based on the calculated current position of the laser processing head, the robot control unit calculates a laser beam emission direction specifying the direction in which the laser beam should be aimed in order to strike a predetermined laser irradiation position. The robot control unit sends a command indicative of the laser beam emission direction to a processing head control unit which changes the direction of a reflecting mirror provided inside the laser processing head such that the laser beam is emitted in the specified direction.

Abstract: A system and method of detecting clutch engagement of a manual transmission of a motor vehicle is disclosed. The system and method include a clutch switch for detecting clutch engagement and a backup method for detecting clutch engagement. The backup method includes varying a target speed of an engine drive shaft of the motor vehicle and comparing the speed of the engine drive shaft with the speed of a mainshaft of the motor vehicle.

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 method for calibrating tension sensors on tendons in a tendon-driven manipulator without disassembling the manipulator and without external force references. The method calibrates the tensions against each other to produce results that are kinematically consistent. The results might not be absolutely accurate, however, they are optimized with respect to an initial or nominal calibration. The method includes causing the tendons to be slack and recording the sensor values from sensors that measure the tension on the tendons. The method further includes tensioning the tendons with the manipulator positioned so that it is not in contact with any obstacle or joint limit and again recording the sensor values. The method then performs a regression process to determine the sensor parameters that both satisfy a zero-torque constraint on the manipulator and minimize the error with respect to nominal calibration values.

Abstract: A control system for a mobile robot (10) is provided to effectively cover a given area by operating in a plurality of modes, including an obstacle following mode (51) and a random bounce mode (49). In other embodiments, spot coverage, such as spiraling (45), or other modes are also used to increase effectiveness. In addition, a behavior based architecture is used to implement the control system, and various escape behaviors are used to ensure full coverage.

Abstract: It is well known that tunnels in many cases have been proven as an efficient means to overcome counter trespassing means and enable hostile entities to infiltrate a boarder or other restricted area. There is provided a method and system for efficiently detecting and locating underground tunnels.

Abstract: A robot is provided with a multi-joint robot arm, an external force detection unit that is installed in the arm, and detects an external force, a joint movable-state calculation unit that calculates a movable state of a joint of the arm, an external force conversion unit which, based on the movable state calculated by the joint movable-state calculation unit, converts the external force detected by the external force detection unit to a converted external force, and a control unit that controls the arm based on the converted external force so as to regulate the operation of the arm.

Abstract: A gait generating device of a legged mobile robot uses virtual surfaces to approximate a plurality of surfaces to be contacted in an operating environment of a robot, and determines the provisional values of the required virtual surface translational forces to be applied from the virtual surfaces to the robot in order to implement a translational motion of a desired motion of the entire robot. Further, to implement a rotational motion of the desired motion of the entire robot, the gait generating device determines moment compensation amounts to be combined with the provisional values of the required virtual surface translational forces and then determines the desired external forces to be applied from the surfaces to be contacted to the robot and the desired external force action points on the basis of the combinations of the provisional values of the required virtual surface translational forces and the moment compensation amounts.

Abstract: The different illustrative embodiments provide an apparatus that includes a computer system, a number of structured light generators, and a number of mobile robotic devices. The computer system is configured to generate a path plan. The number of structured light generators is configured to project the path plan. The number of mobile robotic devices is configured to detect and follow the path plan.

Abstract: There is provided a legged robot that performs motion by changing a joint angle, which includes a trajectory generating section to calculate a center-of-gravity trajectory in designated stepping motion from the stepping motion including at least one of walking motion, running motion and stopping motion, and generate a center-of-gravity trajectory by superimposing a designated travel velocity onto a travel velocity of a center of gravity in the calculated center-of-gravity trajectory in stepping motion, and a trajectory updating section to store the generated center-of-gravity trajectory and update all the stored center-of-gravity trajectories so as to be continuous, and a trajectory reproducing section to calculate time-varying data of a target value of the joint angle based on the updated center-of-gravity trajectory, and a joint driving section to rotate a joint of the legged robot based on the calculated time-varying data of a target value of the joint angle.