Abstract: A drape adapter assembly for a robotic medical system can include an outer housing configured to connect to the robotic medical system such that a drape is positioned between the outer housing and a portion of the robotic medical system, and an inner housing disposed at least partially within the outer housing and configured to carry one or more moveable actuation elements therein. The inner housing can include a first inner housing portion and a second inner housing portion fastened to the first inner housing portion such that the first inner housing portion and the second inner housing portion are axially retained to the outer housing.

Abstract: Methods and systems are described herein for enabling aerial vehicle navigation in GPS-denied areas. The system may use a camera to record images of terrain as the aerial vehicle is flying to a target location. The system may then detect (e.g., using a machine learning model) objects within those images and compare those objects with objects within an electronic map that was loaded onto the aerial vehicle. When the system finds one or more objects within the electronic map that match the objects detected within the recorded images, the system may retrieve locations (e.g., GPS coordinates) of the objects within the electronic map and calculate, based on the coordinates, the location of the aerial vehicle. Once the location of the aerial vehicle is determined, the system may navigate to a target location or otherwise adjust a flight path of the aerial vehicle.

Abstract: Disclosed herein are methods and systems to provide intelligent display for vehicles including a method that comprises determining, by a processor, that a current trajectory of an autonomous vehicle includes a revised road condition having at least one attribute; retrieving, by the processor using the at least one attribute, a graphical overlay corresponding to the revised road condition; and displaying, by the processor on an electronic device associated with the autonomous vehicle, the graphical overlay while the electronic device is presenting an image of a surrounding of the autonomous vehicle.

Abstract: A system and method include operation of a device coupled to a base to hold a catheter to the base, the catheter defining a lumen in which a portion of an elongated medical device is disposed, and a portion of the catheter being disposed in a hemostasis valve, movement of the base relative to the hemostasis valve along a first path while the catheter is held to the base such that the catheter moves relative to the hemostasis valve, and operation of a mechanism coupled to the base to maintain a position of the elongated medical device within the lumen relative to the hemostasis valve while the base and the mechanism are moved along the first path and the catheter is held to the base.

Abstract: Disclosed is a robot for performing three-dimensional (“3D”) or multi-plane sortation and/or order fulfillment. The robot may include a motorized base to move about a first plane, a lift that raises and lowers a dispensing receptacle atop the lift about a second plane, and one or more actuators that modify a position of the dispensing receptacle from an upright position to a first tilted position in which the dispensing receptacle is tilted towards a first side of the robot and to a second tilted position in which the dispensing receptacle is tilted towards an opposite second side of the robot. The robot may receive and carry items when the dispensing receptacle is in the upright position, and may dispense the items to a destination on either side of the robot by tilting the dispensing receptacle to the first tilted position or the second tilted position.

Abstract: There is described a building automation system comprising a mobile tag, sensor devices, and a sensor hub. The mobile tag transmits a broadcast beacon based on RF technology. The sensor devices are co-located with light fixtures and include antennas for receiving a broadcast beacon. The sensor devices generate signals associated with the broadcast beacon received by the antennas. The sensor hub receives the signals from each sensor device and determines a location of the mobile tag based on the signals.

Abstract: Methods and systems are described herein for navigating a vehicle. A target location may be received, and based on the target location and vehicle parameters, an acceleration profile for the vehicle may be generated. The acceleration profile may include a first duration for accelerating the vehicle and a second duration for not accelerating the vehicle. When the acceleration profile is generated, a trajectory profile for travelling to the target location may be generated using the acceleration profile. The trajectory profile may include multiple instances of the acceleration profile. When the trajectory profile is being executed, a distance travelled by the vehicle after each instance of the acceleration profile is executed may be calculated. Based on the distance travelled after each instance of the acceleration profile is executed, an instance of when the target location is reached may be determined.

Abstract: Systems and methods for implementing sensory configurations in accordance with certain embodiments of the invention are illustrated. One embodiment includes an imaging system that includes cameras, wherein each camera includes image sensor(s). The imaging system includes video links, wherein each of the video links is configured to: connect a particular camera to a central processor, and carry power, from the central processor to the particular camera. The imaging system includes a memory that stores instructions for processing image data obtained from the cameras. The central processor is configured to execute the instructions to perform a method. The method aggregates the image data for each camera of the plurality of cameras to produce aggregated image data, using at least one mobile industry processor interface (MIPI) aggregator. The method processes the aggregated image data to produce a set of at least one environmental image.

Abstract: Method of transporting an article with a computer controlled transport vehicle to a destination includes transporting an article carried by a computer controlled transport vehicle to a destination, wherein a tray, belt, or carrier attached to the computer controlled transport vehicle engages the article. The method further includes determining a characteristic for the article. The method furthermore includes manipulating the tray, belt, or carrier from a first position to a second position to deposit the article at the destination, wherein the manipulation of the tray, belt, or carrier is adjusted based on the characteristic determined for the article to adjust a deposit characteristic of the article.

Abstract: A vehicle comprises a sensor configured to capture images and one or more processors. The one or more processors can be configured to receive a single image from the sensor, the single image captured by the sensor as the autonomous vehicle was moving; execute a machine learning model using the single image as input to generate a change in pose of the autonomous vehicle, the machine learning model trained to output changes in pose of autonomous vehicles based on blurring in individual images; determine a global position of the autonomous vehicle based on the generated change in pose of the autonomous vehicle; and transmit the global position to an autonomous vehicle controller configured to control the autonomous vehicle.

Abstract: A robot includes: a base having a plurality of wheels; a body having a bottom portion coupled above the base, and a top portion above the bottom portion, the top portion configured to support food and/or drink; a first camera at the bottom portion, wherein the first camera is oriented to view upward; and a second camera at the top portion, wherein the second camera is configured to view upward.

Abstract: A lawn mower blade sharpening and task robot that autonomously drives under a lawn mower including a body, at least one motor, and a microprocessor. The robot also includes at least one a camera for object recognition and visualization of at least one of the lawn mower, a lawn mower deck, a lawn mower blade, and a lawn mower blade cutting edge, and at least one a sensor to sense the lawn mower, the lawn mower deck, the lawn mower blade, and lawn mower cutting edge. The robot may also include at least one of a task tool, a task arm, a task tip, and a task element in order to complete tasks such as sharping lawn mower blades and cleaning lawn mower blades.

Abstract: Wearable actuator systems are disclosed herein. The wearable actuator system may include an active layer comprising a plurality of actuators, each actuator having a deformable shell that defines an enclosed internal cavity, a fluid dielectric contained within the enclosed internal cavity, a first electrode disposed over a first side of the enclosed internal cavity, and a second electrode disposed over a second side of the enclosed internal cavity. The system further includes an interface layer and a fastener, wherein the active layer and the fastener form an enclosed shape having an internal area, and wherein a size of the internal area of the enclosed shape is adjustable using the fastener.

Abstract: In variants, a system management platform can include a set of system representations and a set of platform-standard element models. Each system representation can include a set of component representations related by a set of constraint representations 140, which can represent the sensing components of a system and the relationships therebetween, respectively, and store component-specific and constraint-specific calibration parameter values, respectively. The component representations 120 can optionally reference the element models.

Abstract: In some examples, a method for determining feasible portions of a seam includes receiving a representation of a part including the seam. The method also includes discretizing a representation of the seam into a plurality of waypoints. The method also includes evaluating each waypoint for feasibility of welding. The method further includes modifying at least one constraint on at least a first waypoint of the plurality of waypoints and generating a weld path through the plurality of waypoints.

Abstract: Techniques and architectures for controlling movement of a system along a desired path in an efficient manner are discussed herein. For example, an autonomous lawn mower can be configured to determine a target state for the autonomous lawn mower indicating a target position, orientation, linear velocity, rotational velocity, etc. The autonomous lawn mower can determine a difference between a current state of the autonomous lawn mower and the target state. Based on the difference, the autonomous lawn mower can determine an amount of force/torque and control the autonomous lawn mower to move based on the amount of force/torque, which can cause the autonomous lawn mower to realign with a target state.

Abstract: The present disclosure is for systems and methods for adjusting operational configurations of robots in real-time. The invention pertains to overriding or replacing one operational configuration of a robot with another when appropriate circumstances arise and certain conditions have been met. In one aspect, the invention is applicable to robotic picking operations and serves to allow for unique robotic picking operations outside of the normal or standard limitations typically imposed on a robotic picking system. The invention provides the ability to remotely adjust robotic operational configurations in real-time, on-demand, in order to address various circumstances that may arise without requiring interruption of a picking session or requiring on-site human intervention.

Abstract: A warehouse equipped with systems for automated order fulfilment includes a storage and retrieval system and a sealing machine. The storage and retrieval system includes a storage structure designed to house storage bins in stacks and one or more robots. The storage structure having pillars supporting a first set of rails and a second set of rails collectively forming a grid defining a plurality of grid spaces such that each of the stacks are housed within a footprint of a respective grid space. The one or more robots being operational on the grid and including a body coupled to a wheel assembly, the wheel assembly including a plurality of wheels and a drive mechanism arranged to move the body along the first and/or second sets of rails and a picking arm for placing the inventory items directly into a vessel for outbound shipment to an end user.

Abstract: Provided herein is a mechanism to controllably move a wire within a flexible tubular member, the wire including opposed wire ends extending outwardly of a proximal end of the flexible tubular member, comprising a drive mechanism and a coupling located between the drive mechanism and the wire end, wherein movement of the coupling in the direction of the wire end results in opposed motion of the wire end.

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 canula and into a cigarette or container. A revolver houses the cigarettes or containers and vertically transitions them to an insertion position, where the insertion canula can infuse the cigarettes or containers.