Abstract: A method, system and computer program product are provided for implementing route generation with augmented reality. A crowd or event is analyzed and escape routes are intelligently distributed by attendee profile type or ability. Augmented Reality (AR) projections are used representing different subsets of an event population to convey the profile-specific escape routes for people to follow. The AR behavior is changed as an event situation changes.

Abstract: A system is applied for calibrating a map data configured for a mobile platform to generate a calibration map after an impact, and includes a map-generating module, a positioning module, an impact-detecting module, an image-analyzing module, a coordinate-reconstructing module and a map data-calibrating module. The map-generating module generates a global map with a first coordinate system. The positioning module positions a mobile platform before the impact. The impact detecting module generates a reconstructing signal after the impact upon the mobile platform is detected. The image-analyzing module searches and analyzes an image of a feature object. The coordinate-reconstructing module re-establishes a second coordinate system, and the map data-calibrating module calibrates the global map to generate the calibration map after the impact.

Abstract: According to some embodiments, a system receives a first control command and a speed measurement of the ADV. The system determines an expected acceleration of the ADV based on the speed measurement and the first control command. The system receives an acceleration measurement of the ADV. The system determines a feedback error based on the acceleration measurement and the expected acceleration. The system updates a portion of the calibration table based on the determined feedback error. The system generates a second control command to control the ADV based on the calibration table having the updated portion to control the ADV autonomously according to the second control command.

Abstract: An embodiment includes a combine having a feeder housing for receiving harvested crop, a separating system for threshing the harvested crop to separate grain from residue, a grain bin for storing the separated grain, a bin level sensor for detecting grain in the grain bin; and a controller that controls the combine. The controller is configured to generate a usable operating range by discarding a selected range of values from an operating range of the bin level sensor, generate a shifted operating range by shifting the usable operating range by a shift value, receive a first value indicating a level of grain in the grain bin, generate a second value by shifting the first value by the shift value, and present the second value to an operator of the combine.

Abstract: There is provided a robot hand that grips and positions a work with a certain gripping force, and that rapidly conveys the work to execute assembling after gripping the work.

Abstract: Exemplary embodiments relate to user-assisted robotic control systems, user interfaces for remote control of robotic systems, vision systems in robotic control systems, and modular grippers for use by robotic systems. Systems, methods, apparatuses and computer-readable media instructions are disclosed for interactions with and control of robotic systems, in particular, pick and place systems using soft robotic actuators to grasp, move and release target objects.

Abstract: A teaching device for performing teaching operations of a robot includes a selection unit which, during a teaching operation or after a teaching operation of the robot, moves among a plurality of lines of a program of the robot and selects a single line, an error calculation unit which calculates, after the robot has been moved by hand-guiding or jog-feeding to a teaching point which has already been taught in the selected single line, a position error between the teaching point and a position of the robot after movement, and an instruction unit which instructs to re-teach the teaching point when the position error is within a predetermined range.

Abstract: An autonomous machine and a method for operating the autonomous machine are disclosed. In an embodiment, the method includes receiving first sensor data from a first plurality of sensors supported by the machine, the first sensors covering a scene in a vicinity of the machine, generating a virtual map frame comprising a plurality of gravity patches and mapping the gravity patches and the first sensor data.

Abstract: Systems and methods for determining teleoperating user intent via eye tracking are provided. A method includes outputting, to a display of a gaze-tracking device utilized by a user, a representation of an environment of a robot. The method further includes receiving, from the gaze-tracking device, user gaze data corresponding to a gaze area subject to a gaze of the user within the representation. The method also includes determining a context based upon an object within the gaze area, an object type, and characteristics of the object. The method further includes receiving, via a user interface, a user input. The method also includes outputting, to the robot, a contextual command corresponding to the context and the user input.

Abstract: In various embodiments, a tool plate configured to receive a robotic end effector is removably matable with a robot appendage via a quick-release mechanism.

Abstract: A system for calibration of a robot includes an imaging system (136) including two or more cameras (132). A registration device (120) is configured to align positions of a light spot (140) on a reference platform as detected by the two or more cameras with robot positions corresponding with the light spot positions to register an imaging system coordinate system (156) with a robot coordinate system (150).

Abstract: There is provided a robot hand that grips and positions a work with a certain gripping force, and that rapidly conveys the work to execute assembling after gripping the work.

Abstract: A robot system including a master device configured to receive a manipulating instruction from an operator and transmit the received manipulating instruction as a manipulating input signal, a plurality of slave robots configured to operate according to the manipulating input signal transmitted from the master device, a management control device configured to manage operations of the plurality of slave robots, respectively, and an output device configured to output information transmitted from the management control device. The management control device determines a priority of transmitting the manipulating input signal from the master device to the slave robot among the plurality of slave robots that are in a standby state of the manipulating input signal, and transmits information related to the determined priority to the output device. Thus, the operator is able to efficiently transmit the manipulating input signal to the plurality of slave robots through the master device.

Abstract: An intelligent lawn mower includes a cutting blade for cutting grass, a deck for supporting the cutting blade, at least one wheel rotatably supporting the deck, a first drive motor to provide torque to the at least one wheel, a mowing path generation module to set multiple target positions on a first virtual boundary and a second virtual boundary of a mowable area boundary according to a preset path and generate a mowing path from the target positions, and a controller electrically connected to or communicated with a display interface and the mowing path generation module to control the intelligent lawn mower to perform mowing tasks along the mowing path generated by the mowing path generation module.

Abstract: A remote air conditioning start system includes a terminal of a user, a center server, and a vehicle that includes an air conditioner and is configured to communicate with the center server. The remote air conditioning start system includes first and second transmission units, first and second reception units, a start controller provided in the vehicle and configured to, when the second reception unit receives a start request, start the air conditioner, a determination unit provided in one of the terminal, the center server, and the vehicle and configured to determine necessity of defrosting of a window of the vehicle, and a notification unit provided in the terminal and configured to, when the determination unit determines that defrosting of the window is needed, notify the user that defrosting of the window is needed.

Abstract: A control device adapted to control a robot including a robot arm provided with a force detector includes a processor that is configured to execute computer-executable instructions so as to control the robot, wherein the processor is configured to: operate the robot arm to move a screw gauge which is disposed on a tip side of the force detector of the robot arm, used for an inspection of a screw hole, and provided with an external thread, to make the external thread have contact with the screw hole; then detect force applied to the screw gauge using the force detector to perform force control in a direction perpendicular to a direction of an axis of the screw hole based on detection information of the force detector; and operate the robot arm to move the screw gauge based on the force control.

Abstract: A system and method of displaying graphic information including a plurality of unmanned aerial vehicles that together form a display screen. Light elements are provided on each vehicle. A computer wirelessly connects to and controls the vehicles and is activated to deploy the vehicles and arrange them in a pattern in the air. The light elements become pixels on the display screen. The light elements may be on opposing regions of the unmanned aerial vehicles, thereby making it possible to view the display screen from more than one direction. Wireless signals are transmitted from the computer to the light elements. Light elements are selectively switched on and off in a manner that causes the light emitted therefrom to form textual or graphic images on one side and/or the other side of the display screen. When not in use, the vehicles are stored in a storage facility having charging stations.

Abstract: In an example, a method of generating flight paths for navigating an aircraft is provided. The method includes hovering the aircraft at a predetermined hover point. The predetermined hover point corresponds to a first takeoff waypoint of a first trajectory of the aircraft. The method includes scanning at least a portion of a first flight path of the first trajectory. The method includes determining that an obstacle obstructs the first flight path of the first trajectory. The first flight path begins at the first takeoff waypoint. The method includes determining a second takeoff waypoint. Determining the second takeoff waypoint includes assigning the first flight path to begin at the second takeoff waypoint. The method includes changing the first flight path of the first trajectory in accordance with the second takeoff waypoint, thereby forming a second flight path of a second trajectory.

Abstract: Provided is a robot system including: a robot including a hand; a unit job storage section configured to store a unit job; a linking job generation section configured to generate a linking job being a command to move the hand from an end position at which a first unit job has ended to a start position at which a second unit job to be executed subsequently after the first unit job is started; an action command generation section configured to generate an action command for the robot by connecting the unit jobs and the linking job in series, based on arrangement of a plurality of processing symbols; and a required time calculation section configured to calculate a required time of the action command by adding required times of the unit jobs and a required time of the linking job.

Abstract: A surveillance system may comprise a control device and at least one robotic device. The control device is associated with a user and configured to request to connect to the at least one robotic device and in response to being connected, communicate a characteristic of the user to the at least one robotic device. The at least one robotic device comprises a platform to carry the user, and may be configured to in response to the request of the control device, verify identity of the control device of the user; in response to the identity of the control device of the user being verified, connect to the control device; define parameters of the at least one robotic device based on the characteristic of the user; and adjust the parameters of the at least one robotic device according to a riding pattern of the user.