Abstract: A robot system that includes a remote station and a robot face. The robot face includes a camera that is coupled to a monitor of the remote station and a monitor that is coupled to a camera of the remote station. The robot face and remote station also have speakers and microphones that are coupled together. The robot face may be coupled to a boom. The boom can extend from the ceiling of a medical facility. Alternatively, the robot face may be attached to a medical table with an attachment mechanism. The robot face and remote station allows medical personnel to provide medical consultation through the system.

Abstract: A robotic cleaning device and a method for operating the robotic cleaning device to detect a structure of a surface over which the robotic cleaning device moves. The method includes illuminating the surface with structured vertical light, capturing an image of the surface, detecting at least one luminous section in the captured image, and determining, from an appearance of the at least one luminous section, the structure of the surface.

Abstract: A robotic actuator comprises a mass manufactured bellows, wherein the mass manufactured bellows allows a volume change by localized bending, and wherein the mass manufactured bellows is formed from a material that has a higher strength in at least two axes relative to at most one other axis, and an end effector, wherein the end effector is coupled to the manufactured bellows.

Abstract: A control device and a machine learning device enable control for gripping an object having small reaction force. The machine learning device included in the control device includes a state observation unit that observes gripping object shape data related to a shape of the gripping object as a state variable representing a current state of an environment, a label data acquisition unit that acquires gripping width data, which represents a width of the hand of the robot in gripping the gripping object, as label data, and a learning unit that performs learning by using the state variable and the label data in a manner to associate the gripping object shape data with the gripping width data.

Abstract: Embodiments of a method and system for sharing toy robot programs enabling toy robots to interact with physical surroundings can include receiving a robot program; automatically processing a token for the robot program; and processing a program request for the robot program based on the token. The embodiments can additionally or alternatively include controlling a toy robot based on a robot program; recommending a robot program; publishing a robot program; processing modifications of robot programs S160; and/or any other suitable functionality.

Abstract: A method for a robot to autonomously interact with elevator controls comprising: while physically traversing a route to a target location within an environment, determining that the route includes navigating to a particular floor that is different than a current floor of the robot; navigating to a set of one or more elevators along the route; identifying a location of an elevator call button corresponding to the set of one or more elevators; navigating to the location of the elevator call button and pressing the elevator call button, wherein pressing the elevator call button comprises: rotating the robot in place until a vertical structure faces the elevator call button; extending or retracting the vertical structure until a button pushing element is aligned with the elevator call button; moving towards the elevator call button and causing the button pushing element to press the elevator call button.

Abstract: A robot system includes a robot including a tactile sensor and a hand having the tactile sensor, a tactile information generator configured to generate tactile information defined by a pressure distribution based on pressures detected by a plurality of pressure sensors and spatial positions of the plurality of pressure sensors, and output the tactile information, a manipulator configured to make an operator sense the pressure distribution according to the tactile information outputted from the tactile information generator, and when the operator manipulates the manipulator, output manipulating information according to the manipulation, and a robot controller configured to control operation of the hand of the robot according to the manipulating information outputted from the manipulator.

Abstract: The invention relates to a robotic system with at least one robotic arm and a control unit, which is designed so that it can preset at least one predefined operation that can be carried out by the robotic system. In addition, the robotic system comprises at least one input device attached to the robotic arm which is designed so that the predefined operations of the robotic system can be parameterized by means of the input device. In this case, the input device is designed so that it can provide a user-directed feedback to a user of the robotic system when setting the execution of operations, the logical sequence of the operations and/or parameterizing the predefined operations for the robotic system.

Abstract: A method for identifying redundantly received information in which the information is contained in vehicle-to-X messages, one vehicle-to-X message comprising at least one item of information, a plurality of vehicle-to-X messages being received by a receiver, and at least one portion of a total number of items of information being received redundantly. The received items of information are entered into an information table and matched with one another before the received information is processed.

Abstract: The present application provides a vehicle-carried system and a control method for vehicle facilities. The vehicle-carried system includes a characteristic information acquisition unit configured to acquire human body characteristic information; a storage unit configured to store pieces of human body characteristic information and pieces of identity information corresponding to the pieces of human body characteristic information; a matching unit configured to match the human body characteristic information acquired by the characteristic information acquisition unit with the pieces of human body characteristic information stored in the storage unit, and determine identity information corresponding to the human body characteristic information acquired by the characteristic information acquisition unit according to a result of the matching; and a control unit configured to control facilities in a vehicle according to the determined identity information.

Abstract: A fuel control regulator system for a vehicle is disclosed in which a restraint control module registers an acceleration/deceleration that falls outside of predetermined limits. In one embodiment, the fuel control regulator system includes a vehicle including steering, an accelerator, brakes, one or more audio devices in proximity to one or more front crash sensors recording sensor data, a processor, and memory. The restraint control module is coupled to the processor and configured to dynamically adjust a threshold to lie outside of an amplitude of the sensor data of the one or more front crash sensors compromised by sound from the one or more audio devices. In another embodiment, the fuel control regulator system adjusts the sensor data of an affected front crash sensor to lie within an existing threshold. In yet another embodiment, the fuel control regulator system ignores the sensor data of an affected front crash sensor.

Abstract: There is disclosed a system and method for forecasting the positions of marine vessels. In an aspect, the present system is adapted to execute a forecasting algorithm to forecast the positions of one or a great many marine vessel(s) based on one or more position reporting systems including coastal and satellite AIS (S-AIS) signals or LRIT received from the vessel. The forecasting algorithm utilizes location and direction information for the vessel, and estimates one or more possible positions based on previous paths taken by vessels from that location, and heading in substantially the same direction. Thus, a body of water can be divided into “bins” of location and direction information, and a spatial index can be built based on the previous paths taken by other vessels after passing through that bin. Other types of information may also be taken into account, such as ship-specific data, nearby weather, ocean currents, the time of year, and other spatial variables specific to that bin.

Abstract: A human-cooperative industrial robot having a base unit and a movable unit movably provided on or above the base unit. The robot includes a protection member composed of a material with a rigidity lower than rigidities of the base unit and the movable unit, the protection member covering a circumference of at least the movable unit of the base unit and the movable unit; and a detector provided on at least either the base unit or the movable unit to detect an external force input through the protection member.

Abstract: Methods, apparatus, systems, and articles of manufacture are disclosed for robot control. An example apparatus includes a command generator to instruct a robot to move an end effector from a staging position to an estimated pre-task position to perform a first task based on a first pose of the robot, the first pose based on a model, adjust the robot to a first actual pre-task position to perform the first task when the robot is to move to a second actual pre-task position, the first actual pre-task position proximate the estimated pre-task position, and direct the robot to perform a second task based on a correction factor, the correction factor is to be determined by determining a second pose of the robot, the second pose corresponding to position information associated with a post-task position, and calculating the correction factor based on the first pose and the second pose.

Abstract: A parsing system includes an imaging device and one or more processors. The imaging device may capture visual instructions displayed on a monitor. The one or more processors may be configured to receive, from the imaging device, the captured visual instructions, generate functions for a robot to perform based on the captured visual instructions, and transmit, to a robot, the functions to perform.

Abstract: Provided are a substrate transfer apparatus and a control method thereof. The substrate transfer apparatus includes a body having a gate through which a substrate passes; a substrate transfer robot provided inside the body and including an end effector that includes a first seating portion and a second seating portion horizontally spaced apart from each other; a sensing portion including a light emitting portion and a light receiving portion spaced apart from each other in a diagonal direction with respect to a longitudinal direction of the first and second seating portions with reference to the end effector, and detecting the position of at least one of the first seating portion and the second seating portion when the end effector moves; and a control unit for determining whether the end effector is misaligned or sagged by using a measured value measured by the sensing portion and a predetermined reference value.

Abstract: A mobile robotic device and a method for controlling the mobile robotic device to move are provided. The mobile robotic device includes: a body; a rotatable portion connected to the body and configured to support the body in a rotatable manner; and an operational portion which comprises at least two arms connected to the body and configured to support the body in a walkable manner. In operation, the mobile robotic device is switchable between a manipulation mode in which the rotatable portion supports the body in the rotatable manner and a locomotion mode in which the at least two arms support the body in the walkable manner.

Abstract: A robot system includes a robot, a moving body, a determination circuit, a calculation circuit, and a control circuit. The robot includes a mount and a first arm. The determination circuit is configured to determine a lastly moved part of the robot which is lastly moved to make the robot take an operation posture. The calculation circuit is configured to calculate, based on the lastly moved part, an angle between a travel direction of the moving body and an orientation axis of the first arm when the robot in the operation posture is viewed along a height axis of the robot. The control circuit is configured to control the robot to work on a workpiece keeping the robot in the operation posture with the calculated angle while controlling the moving body to move in the travel direction.

Abstract: Methods and systems for enabling human-machine collaborations include a generalizable framework that supports dynamic adaptation and reuse of robotic capability representations and human-machine collaborative behaviors. Specifically, a method of feedback-enabled user-robot collaboration includes obtaining a robot capability that models a robot's functionality for performing task actions, specializing the robot capability with an information kernel that encapsulates task-related parameters associated with the task actions, and providing an instance of the specialized robot capability as a robot capability element that controls the robot's functionality based on the task-related parameters.

Abstract: A method is provided for tracking a hand-guided robot including a control unit and at least one manipulator coupled to an end effector, in which the manipulator includes a plurality of joints and links and the end effector is manually displaceable within an operational volume. In the method, the control unit determines at least one movement information of each joint during and/or after a manual or partially manual displacement of the end effector, and a position and orientation information of the end effector inside the operational volume during and/or after the displacement of the end effector using the determined movement information of each joint and a software-based kinematic and dynamic model of the manipulator stored in a memory of the control unit.