Abstract: People and packages are delivered to and picked up from delivery locations by autonomous vehicles that also carry autonomous robots. When a package needs to be picked up or delivered at a particular location, an autonomous robot is deployed from the delivery vehicle and takes the package to the doorstep or other predetermined location or picks up the package from that location and brings it back to the delivery vehicle. After this pickup or delivery, the autonomous robot stows itself back in the delivery vehicle.

Abstract: Methods and systems are described herein for determining three-dimensional locations of objects within a video stream and linking those objects with known objects. An image processing system may receive an image and image metadata and detect an object and a location of the object within the image. The estimated location of each object is then determined within the three-dimensional space. In addition, the image processing system may retrieve, for a plurality of known objects, a plurality of known locations within the three-dimensional space and determine, based on estimated location and the known location data, which of the known objects matches the detected object in the image. An indicator for the object is then generated at the location of the object within the image.

Abstract: The present invention discloses a wirelessly controlled vehicle that is configured to travel in air, on liquid and under liquid with an ability to communicate with a remote operator through wireless communication.

Abstract: A system generates, by a first source microcontroller, a first data packet comprising a payload and a first error code, the payload indicating a safety state of a robot. The first source microcontroller transmits the data packet from the first source microcontroller to a second source microcontroller. The second source microcontroller generates a second data packet that includes the payload, the first error code and a second error code. The second source microcontroller transmits the second data packet to a sink microcontroller, wherein the sink microcontroller recovers the payload based on at least one of the first error code and the second error code.

Abstract: A method for controlling a serving robot is provided. The method includes the steps of: acquiring at least one of weight information on a support coupled to the serving robot and image information on the support; recognizing at least one serving object placed on or removed from the support on the basis of at least one of the weight information and the image information; and determining at least one destination of the serving robot on the basis of a result of the recognition and order information of at least one customer in a serving place.

Abstract: Spatial regions potentially occupied by a robot (or other machinery) or portion thereof and a human operator during performance of all or a defined portion of a task or an application are computationally estimated. These “potential occupancy envelopes” (POEs) may be based on the states (e.g., the current and expected positions, velocities, accelerations, geometry and/or kinematics) of the robot and the human operator. Once the POEs of human operators in the workspace are established, they can be used to guide or revise motion planning for task execution.

Abstract: An actuator system includes an actuator with a deformable shell defining a pouch, a fluid dielectric contained within the pouch, and first and second electrodes disposed over opposing sides of the pouch, each electrode having two long edges and two short edges. The system also includes a power source for providing a voltage between the electrodes. The electrodes cover 50 to 90% of the first and second sides, respectively, of the pouch, and a gap is defined between long edges of the pouch and the electrodes such that, upon application of the voltage at one of the short edges of the electrodes, respectively, the electrodes selectively zip together from the one of the short edges toward an opposing one of the short edges. The system may also include a support structure for enabling the actuator to maintain its shape regardless of the voltage provided by the power source.

Abstract: A mobility platform is configured to execute one or more tasks in a worksite including a first passive landmark and a second passive landmark. The mobility platform may include a chassis, a drive system supporting the chassis, a first laser rangefinder disposed on the chassis at a first location, a second laser rangefinder disposed on the chassis at a second location, and at least one processor. The at least one processor may be configured to determine a position and orientation of the chassis based on a first distance measured by the first laser rangefinder between the first location and a first known landmark position, a second distance measured by the second laser rangefinder between the second location and a second known landmark position, and yaw angle information from at least one of the first and second laser rangefinders.

Abstract: Bridge construction method for a bridge formed by a series of beams placed between slabs, supported by angular profiles affixed to the beams. The method includes the steps of: fixing clips to edges of the upper surface of the beams, placing the beams on their supports, calculating the correct position of the angular profiles according to the shape or position of the beams; joining fasteners on the angular profiles, at an individual height determined according to the calculated positions; affixing the fasteners to the clips, so the angular profiles hang at the edges of the beams placing the slab on the angular profiles and casting concrete on the structure. The slabs are supported by angular profiles joined to the upper surface of the beams through a series of threaded protrusion carrying clips in said upper surface. Fasteners are joined to the clips and affixed to the angular profiles.

Abstract: Robot includes a propulsion system configured to transport the robot and a controller in communication with the propulsion system. A material handler is carried by the robot and configured for depositing articles into one or more destination containers. The material handler has a tilt tray having sections that are configured for tilting in any number of directions relative to a vertical of the robot. Each section of the tilt tray may include a respective conveyor that moves articles at variable speed.

Abstract: A method for controlling a robot is provided. The method includes the steps of: acquiring information on status of communication connections between a plurality of robots located in a serving place, wherein the status of communication connections between the plurality of robots is specified with respect to at least one relay robot among the plurality of robots; and determining a communication scheme to be used between the plurality of robots, with reference to the information on the status of communication connections between the plurality of robots.

Abstract: A method for controlling a patrolling robot is provided. The method includes the steps of: acquiring, as first situation information on the patrolling robot, at least one of weight information on a support coupled to the patrolling robot and image information on the support and information on a location of the patrolling robot in a patrolling place; and determining a task and a travel route of the patrolling robot on the basis of the first situation information.

Abstract: A method for providing a service using a robot is provided. The method includes the steps of: acquiring information associated with a serving place of the robot and information on a customer visiting the serving place; determining service guide information including information on at least one of a travel route to a table to be provided to the customer, among a plurality of tables in the serving place, and a conversation scenario to be provided to the customer during travel to the table to be provided to the customer, with reference to the information associated with the serving place and the information on the customer; and providing the customer with a service associated with the serving place by the robot with reference to the service guide information.

Abstract: A method for operating an actuator system includes providing an actuator with a deformable shell defining an enclosed internal cavity, a fluid dielectric, and first and second electrodes disposed over opposing sides of the enclosed internal cavity, and providing a power source such that the actuator system exhibits a first operational performance. Further, the method includes modifying at least one of length, width, diameter, and shape of the deformable shell and/or the first and second electrodes, a volume of the fluid dielectric, permittivity, thickness, and material of the deformable shell, and a partition within the deformable shell such that the actuator so modified exhibits a second operational performance. The operational performance includes force as a function of stroke, actuator breakdown strength, direction of actuation, uniformity of deformation of the deformable shell, actuator flexibility, and stroke as a function of actuator system volume.

Abstract: Embodiments may be used to evaluate completed inspection jobs using updated pipe segment data obtained by inspecting a rehabilitated pipe after completion of a project. One embodiment provides a method of generating an infrastructure project summary, including: collecting, using one or more sensors of an inspection robot, pipe segment data relating to the one or more pipe segments; the second pipe segment data comprising one or more of laser condition assessment data and sonar condition assessment data; generating infrastructure summary data for at least a part of the network using the pipe segment data, comparing, using a processor, first and second infrastructure summary data; generating, using the processor, a parameter of the infrastructure project summary based on the comparing; and including the parameter of the infrastructure project summary in a project summary report. Other embodiments are disclosed and claimed.

Abstract: Spatiotemporal robotic navigation may include providing a set of robots non-conflicting access to the same shared resources at different times so that the robots may operate without continually accounting for the locations of the other robots and workers operating in the particular site, without continually planning or updating paths after determining an initial path, and without continuously adjusting movements as the robots near one another. The spatiotemporal robotic navigation involves generating spatiotemporal plans. Each plan has a set of objectives that a robot is to execute by different time intervals. Each plan is generated so as to not conflict with the resources being accessed by other robots at time intervals set in the plans of other robots.

Abstract: Disclosed are systems and methods for automatic infusion of concentrate and distillate material into cigarettes or other containers. In one embodiment, a thermally-controlled infusion system is provided. The system can maintain a selected temperature of the concentrate material throughout the infusion process, using a two-stage approach. In a first stage, the concentrate material is pressure-fed to a dosing chamber. In the second stage, the concentrate material is pumped into an insertion cannula and into a cigarette or container. A revolver houses the cigarettes or containers and vertically transitions them to an insertion position, where the insertion cannula can infuse the cigarettes or containers.

Abstract: Inspection robots with center encoders are described. An example inspection robot may have a housing, and a drive module, where the drive module has a wheel and a motor and is operatively coupled to the housing. The example inspection robot may also have an encoder to provide a movement value, where the encoder is positioned within a footprint of the housing. The example inspection robot may also have a controller with an encoder conversion circuit to calculate a distance value in response to the movement value, a location circuit to determine at least one of a robot location value or a robot speed value, and a position command circuit to provide a position action command in response to the robot location value or the robot speed value. The drive module may be responsive to the position action command to move the inspection robot.

Abstract: High precision end effectors for robots and adapters that provide attachment of the end effectors to a variety of robotic arms are disclosed. The combination provides for harmless break-away of the end effector on collision, and autonomous tool changer capability for mobile robots.

Abstract: Systems, apparatus, and methods are described for robotic learning and execution of skills. A robotic apparatus can include a memory, a processor, sensors, and one or more movable components (e.g., a manipulating element and/or a transport element). The processor can be operatively coupled to the memory, the movable elements, and the sensors, and configured to obtain information of an environment, including one or more objects located within the environment. In some embodiments, the processor can be configured to learn skills through demonstration, exploration, user inputs, etc. In some embodiments, the processor can be configured to execute skills and/or arbitrate between different behaviors and/or actions. In some embodiments, the processor can be configured to execute skills and/or behaviors using cached trajectories or plans. In some embodiments, the processor can be configured to execute skills requiring navigation and manipulation behaviors.