Abstract: A robotic order fulfilment system for picking inventory. The system includes a piece picking robot configured to pick inventory from a plurality of containers arranged on shelving. The robot includes a base moveable relative to the shelving in a horizontal direction, a vertical post extending from the base, a platform linearly moveable along the vertical post, a suction system arranged to secure and move a select one of the containers from the shelving to expose an open top of the select one of the containers, and a picking arm configured to pick an item from the select one of the containers after the open top has been exposed. An order fulfilment method using the piece picking robot is also provided.

Abstract: Disclosed is an adjustment mechanism for an electric power-driven shoe, the mechanism comprising a shoe sole (1), wherein a plurality of rolling wheels (2) are arranged below the shoe sole (1); a foot-positioning mechanism is arranged above the shoe sole (1) and is provided with an angle-adjusting mechanism for adjusting an angle between the foot-positioning mechanism and a lengthwise direction of the shoe sole (1).

Abstract: This description provides an autonomous or semi-autonomous excavation vehicle that is capable determining a route between a start point and an end point in a site and navigating over the route. The sensors collect any or more of spatial, imaging, measurement, and location data to detect an obstacle between two locations within the site. Based on the collected data and identified obstacles, the excavation vehicle generates unobstructed routes circumventing the obstacles, obstructed routes traveling through the obstacles, and instructions for removing certain modifiable obstacles. The excavation vehicle determines and selects the shortest route of the unobstructed and obstructed route and navigates over the selected path to move within the site.

Abstract: Systems and methods for safety-enabled control by: establishing a wireless communication channel with a plurality of remote control units via the wireless interface device; in response to establishing the wireless communication channels, operating a system-under-control in a supervised mode based on input received from at least one of the plurality of remote control units; in response to a mode switch command received from a first remote control unit of the plurality of remote control units, providing the other remote control units with a request for a mode switch confirmation; and, in response to confirming receipt of a safety-rated input from an autonomous control system and receipt of a mode switch confirmation from each of the other remote control units, operating the system-under-control in an autonomous mode based on input received from the autonomous control system.

Abstract: An apparatus for supporting a ceiling mounted unmanned aerial vehicle docking station for a premises including a ceiling grid and a support structure disposed above the ceiling grid is provided. The apparatus includes an unmanned aerial vehicle docking station mounting bracket including a top surface and a bottom surface which is configured to be affixed to an exposed surface of a ceiling element in the ceiling grid by a first plurality of fastening elements. The bottom surface of the bracket is configured to be affixed to the ceiling mounted unmanned aerial vehicle docking station. The apparatus further includes a panel including a top surface and a bottom surface which is configured to be affixed to a concealed surface of the ceiling element by the first plurality of fastening elements. The top surface of the panel includes at least one anchoring element physically coupling the panel to the support structure.

Abstract: A method for controlling a robot is provided. The method includes the steps of: acquiring information on a sound associated with a robot call in a serving place; determining a call target robot associated with the sound, among a plurality of robots in the serving place, on the basis of the acquired information; and providing feedback associated with the sound by the call target robot.

Abstract: This description provides an autonomous or semi-autonomous excavation vehicle that is capable of navigating through a dig site and carrying an excavation routine using a system of sensors physically mounted to the excavation vehicle. The sensors collect one or more of spatial, imaging, measurement, and location data representing the status of the excavation vehicle and its surrounding environment. Based on the collected data, the excavation vehicle executes instructions to perform an excavation routine by excavating earth from a hole using an excavation tool positioned at a single location within the site. The excavation vehicle is also able to carry out numerous other tasks, such as checking the volume of excavated earth in an excavation tool, navigating the excavation vehicle over a distance while continuously excavating earth from a below surface depth, and preparing a digital terrain model of the site as part of a process for creating the excavation routine.

Abstract: A method of operating an exoskeleton system that includes obtaining a first set of sensor data from one or more sensors associated with one or more leg actuator units of an exoskeleton system during a user activity, the first set of sensor data indicating a first configuration state of the one or more actuator units; determining, based at least in part on the first set of obtained sensor data, to change configuration of the one or more leg actuator units to a second configuration state to support a user during the user activity; and introducing fluid to one or more fluidic actuators of the one or more leg actuator units to generate the second configuration state by causing the one or more fluidic actuators to apply force at the one or more actuator units.

Abstract: A mobile inventory transportation unit (MITU) in a communication network is disclosed. The communication network may comprise the MITU, a transportation system, a first and a second central system, in communication with each other, the MITU comprising a housing, an inventory storage device, a power device, a drive device, a navigation device, a sensing device, and a control device. The MITU may be configured to receive inventory demands and handle them based on analyzing its own inventory, the transportation system may be configured to physically receive and transport the MITU, the second central system may be configured to determine an inventory demand at a second or more location and transmit the same to the first central system or the MITU, and the first central system or the MITU may be configured to schedule the movement of the MITU and control the delivery of the MITU to a final destination.

Abstract: A mobile manipulator robot having a pneumatic charging system. The mobile robot includes an energy source and a charging system to charge the energy source. The charging system includes a coupler having a mating end configured to mate with an external pneumatic supply system to access a pneumatic supply and a pneumatic actuator disposed downstream of the coupler. The pneumatic actuator is configured to convert energy from the pneumatic supply to charge the energy source. The pneumatic actuator may be an air motor or a piezo.

Abstract: Each of a plurality of co-located inspection camera modules captures raw images of objects passing in front of the co-located inspection camera modules which form part of a quality assurance inspection system. The inspection camera modules have either a different image sensor or lens focal properties and generate different feeds of raw images. The co-located inspection camera modules can be selectively switched amongst to activate the corresponding feed of raw images. The activated feed of raw images is provided to a consuming application or process for quality assurance analysis.

Abstract: Systems and methods are provided for providing redundant pulse-width modulation (PWM) throttle control. The system includes a manual throttle controller configured to generate a manual PWM throttle control signal, and an automated throttle control system. The automated throttle control system includes a plurality of automated throttle controllers, each of which being configured to independently control a throttle of a vehicle, and each including a processor configured to generate and output an automated PWM throttle control signal, a first double pole double throw (DPDT) relay that, when engaged, is configured to receive and output the manual PWM throttle control signal, and a second DPDT relay, configured to receive and output the automated PWM throttle control signal to an engine, when the second DPDT relay is engaged; and receive and output the manual PWM throttle control signal to the engine, when the DPDT relay is disengaged.

Abstract: Provided is a robotic retrieval system that adapts robot operations to different densities with which containers are stored. The system determines a position of a particular container in a slot. The system selects a first side of the slot from which to gain access to the particular container based on the particular container being blocked from the first side by a first number of containers and from an opposite second side by a larger second number of containers. The system uses robots to advance the particular container to the frontmost position at the first side of the particular slot by removing the first number of containers from the first side, and by inserting the first number of containers into the second side, and to transfer the particular container to a target destination after advancing the particular container to the frontmost position at the first side.

Abstract: The system, devices and methods disclosed herein enable autonomous operation of robots around known and unknown obstacles on a property. A robot includes an optical marker disposed to be visible in a top-view image of the robot, a receiver configured to receive a top-down image of an area of interest surrounding the robot within a property, and a processor configured to distinguish the robot from structural features on the property based on an image of the optical marker. A position and an orientation of the robot and the structural features relative to the property is determined based on the top-down image. Among the structural features, a subset of features classified as obstacles inhibiting an operation of the robot as the robot moves within the area of interest is determined. An operating path for the robot within the area of interest so as to avoid the obstacles is then determined.

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: The present specification provides a device and method for controlling a winch parcel delivery system through an uncrewed aerial vehicle (UAV) or drone. The example apparatus contemplates the use of a winch that will attach to a hook with active and passive release mechanisms through a winch line. The apparatus is enabled to attach to a parachute recovery system. The apparatus can detect when the ground has been reached to enable safe delivery of parcels. The apparatus can removably attach to various types of drones.

Abstract: Systems for reprogrammable inspection robots are described. An example system may include an inspection robot having a housing, a payload interface, a drive module interface, and a tether interface. The system may further include a first electronic board having a primary functionality circuit communicatively coupled to a base station and a second electronic board operationally coupled to the payload interface, the second electronic board having a payload functionality circuit coupled to a selected payload through the payload interface. The example system may further include a third electronic board operationally coupled to the drive module interface, the third electronic board having a drive module functionality circuit communicatively coupled to a selected drive module through the drive module interface.

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 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.