Abstract: A road system includes a road surface along which vehicles travel, with the vehicles traveling along the road surface including electric vehicles. A plurality of electrical charging elements is disposed along the road surface. Batteries of electric vehicles traveling along the road surface are electrically charged as the electric vehicles travel along the electrical charging elements disposed along the road surface. A plurality of communication devices along the road surface. The communication devices are operable to wirelessly communicate with vehicles traveling along the road surface. At least some of the communication devices along the road wirelessly communicate lane information to a vehicle traveling along a lane of the road surface. Responsive to the wirelessly communicated lane information, the vehicle maintains its path of travel in the lane traveled along by the vehicle as the vehicle travels along the road surface.

Abstract: A robot system includes a robot including a hand for holding a workpiece; a sensor for measuring a work area in which the workpiece exists to obtain a three-dimensional shape in the work area as measurement data; a measurement data processing device including a model data storage unit, a measurement data correction unit, a position and orientation calculation unit; and a robot control unit for control the robot based on an output from the position and orientation calculation unit, wherein the measurement data correction unit in a learning stage, creates teacher data by arranging the model data in the position and the orientation calculated by the position and orientation calculation unit and adjusts a parameter for correcting the measurement data based on the measurement data and the teacher data, and in a picking stage, outputs corrected measurement data obtained by correcting the measurement data using the adjusted parameter.

Abstract: The present disclosure provides a general purpose operating system (GPROS) that shows particular usefulness in the robotics and automation fields. The operating system provides individual services and the combination and interconnections of such services using built-in service extensions, built-in completely configurable generic services, and ways to plug in additional service extensions to yield a comprehensive and cohesive framework for developing, configuring, assembling, constructing, deploying, and managing robotics and/or automation applications. The disclosure includes GPROS extensions and features directed to use as an autonomous vehicle operating system. The vehicle controlled by appropriate versions of the GPROS can include unmanned ground vehicle (UGV) applications such as a driverless or self-driving car. The vehicle can likewise or instead include an unmanned aerial vehicle (UAV) such as a helicopter or drone.

Abstract: A system and method of breakaway clutching in a computer-assisted medical device includes an articulated arm having one or more first joints and a control unit coupled to the articulated arm and having one or more processors. The control unit operates each of the first joints in multiple states. The multiple states include a locked state, wherein movement of respective first joints is restricted, and a float state, wherein movement of the respective first joints is permitted. The control unit further switches one or more second joints selected from the first joints from the locked state to the float state when a stimulus on the second joints exceeds one or more unlock thresholds and switches the second joints from the float state to the locked state when a velocity of each of the second joints is below one or more lock thresholds.

Abstract: In an optical components automatic alignment robot, a motorized target moves closer or further from a digital camera being tested or assembled. A light sensor is used to automatically calibrate an ultraviolet (UV) or other light source used for curing adhesive. An automatic surface finder is used to accurately and repeatably find a surface on which adhesive is to be dispensed.

Abstract: Systems and methods are presented for sequencing locations and events and determining routing and itineraries for the sequence. In some embodiments the system may receive a starting location, a first location, and a second location in a default order. The system may determine a sequence from the starting location for the first location and the second location. The system may generate a route for the sequence with the route having transportation directions between the starting location, the second location, and the first location indicative of the sequence. The system may display the route in a graphical user interface of an application.

Abstract: A method and apparatus for predicting traffic on a transportation network where real time data points are missing. In one embodiment, the missing data is estimated using a calibration model comprised of historical data that can be periodically updated, from select links constituting a relationship vector. The missing data can be estimated off-line whereafter it can be used to predict traffic for at least a part of the network, the traffic prediction being calculated by using a deviation from a historical traffic on the network. The invention further discloses a method for in-vehicle navigation; and a method for traffic prediction for a single lane.

Abstract: A computing device can identify, for a placement of a label, a first and second character of the label that have a shortest distance from one another. The placement for the label can define a position at which the label is to be placed in an interactive geographic map and a formatting for that label. The computing device can determine that the first and second identified characters do not overlap. In response to determining that the first and second characters do not overlap, the computing device can select the placement of the label for display in the interactive geographic map.

Abstract: A computer-implemented method includes a first controller configured to receive and record operational data associated with operation of a locomotive, process, via a processor, the operational data, and determine, using the processor, a data storage plan for the operational data. The data storage plan can dynamically change based on the operational data. The system may be further configured to store the operational data with a second controller associated with a second locomotive according to the data storage plan.

Abstract: In an example embodiment, apparatus for detecting position drift in a machine operation using a robot arm, the robot arm being for operation on a semiconductor substrate, the robot arm and the semiconductor substrate being configured for relative movement therebetween, the apparatus includes an input for receiving an input signal from a sensor mounted on the robot arm; a detector for detecting, from the input signal, a detection of there being a predefined distance between the robot arm and the semiconductor substrate; wherein the apparatus is configured to determine, from the detection, whether there has been position drift.

Abstract: The present invention provides a method of selecting and implementing a shift schedule for a transmission in a vehicle that includes an output speed sensor and a controller. The method includes measuring output speed with the output speed sensor and comparing the measured output speed to an output speed threshold. The controller receives throttle percentage and compares the throttle percentage to a throttle threshold. The method also includes calculating output acceleration and transmission gear ratio with the controller. The shift schedule is selected based on the measured output speed, calculated output acceleration, calculated transmission gear ratio, and throttle percentage.

Abstract: A method of transporting inventory items includes receiving a route request from a mobile drive unit. The route request identifies a destination location within a workspace. The workspace includes at least one cell associated with a first cell attribute and at least one cell that is not associated with the first cell attribute. The method includes determining a state of the mobile drive unit. The method also includes generating a path to the destination location for the mobile drive unit that traverses cells associated with the first cell attribute, in response to determining that the mobile drive unit is associated with a first state. The method includes generating a path to the destination location for the mobile drive unit that does not traverse cells associated with the first cell attribute, in response to determining the mobile drive unit is not associated with the first state. The method further includes transmitting the path to the mobile drive unit.

Abstract: Assessing the accuracy of location estimation systems. A mobile computing device provides location information including a device location (e.g., via GPS) and one or more wireless network beacons accessible by the computing device at the device location. The wireless network beacons accessible by the computing device are compared to stored post information including a plurality of beacon lists. An estimated device location is determined based on the comparison. The estimated device location is compared to the known device location. A difference between the estimated device location and the received device location is determined based on the comparison. An analysis of the determined difference is performed to generate accuracy maps and other insight into the relationship between accuracy and geographic area for the location estimation systems.

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: 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: A hybrid system control apparatus is provided in which an intercooler is disposed upstream of the motor cooling radiator in a flow path of the ambient air flowing in an engine compartment, and/or is disposed such that at least a portion of the intercooler and a portion of the motor cooling radiator contact each other. The hybrid system control apparatus includes a warm-up portion that increases temperature of the boost air by controlling a load of the engine in cold start of a hybrid system such that the boost pressure from the forced air induction device is equal to or higher than a target boost pressure.

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 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 system is capable of controlling the movements of a hand so as to ensure a further stable grasp of an object. In a state wherein an object is in contact with a plurality of finger mechanisms and a palm portion by being grasped by the hand, the load to be applied to the object from each of the plurality of finger mechanisms can be adjusted. Thus, the position of the load center on the palm portion can be displaced so as to be included in a target palm area. Further, the load to be applied to the palm portion can be adjusted so as to fall within a target load range.

Abstract: In one embodiment, a surgical instrument includes a housing linkable with a manipulator arm of a robotic surgical system, a shaft operably coupled to the housing, a force transducer on a distal end of the shaft, and a plurality of fiber optic strain gauges on the force transducer. In one example, the plurality of strain gauges are operably coupled to a fiber optic splitter or an arrayed waveguide grating (AWG) multiplexer. A fiber optic connector is operably coupled to the fiber optic splitter or the AWG multiplexer. A wrist joint is operably coupled to a distal end of the force transducer, and an end effector is operably coupled to the wrist joint. In another embodiment, a robotic surgical manipulator includes a base link operably coupled to a distal end of a manipulator positioning system, and a distal link movably coupled to the base link, wherein the distal link includes an instrument interface and a fiber optic connector optically linkable to a surgical instrument.