Abstract: An expandable reel for a well system includes a support frame configured to receive a torque from a motor a plurality of circumferentially spaced spokes each extending radially away from a central axis of the expandable reel, a core assembly configured to couple to the support frame and receive a tubular of the well system about an outer surface of the core assembly, wherein the core assembly includes a plurality of circumferentially spaced panel assemblies each extending longitudinally between opposed ends thereof that are in sliding engagement with the plurality of spokes, and a linear actuator coupled between the support frame and the core assembly and configured to actuate the core assembly, including the plurality of panel assemblies, between a first configuration providing a first outer diameter and a second configuration providing a second outer diameter that is different from the first outer diameter.

Abstract: A navigation system includes: a communication unit configured to receive vehicle environment information of a user vehicle, the vehicle environment information including proximate vehicle information representing proximately located vehicles relative to the user vehicle; and a control unit, coupled to the communication unit, configured to: determine lane reference vehicles from the proximately located vehicles based on a vehicle type of the proximately located vehicles; monitor the relative location of the lane reference vehicles; generate a road lane model including a lane delineation estimation based on the relative location of the lane reference vehicles; and calculate a lane position of the user vehicle according to the lane delineation estimation based on a lateral position shift of the user vehicle.

Abstract: A bag comprises a front face, a rear face, a first side face comprising a first side pocket, a second side face, a top face and a bottom face. The bottom face comprises a rigid base. A storage region is positioned between the front face, the rear face, the first side face, the second side face, the top face and the bottom face. An access mechanism is constructed and arranged to allow access to the storage region. Four wheels are coupled to the bottom face. An expansion mechanism is constructed and arranged to expand the storage region.

Abstract: A flame analytics system that may incorporate a burner, one or more sensors at the burner, a historical database connected to the one or more sensors, a model training module connected to the historical database, and a runtime algorithm module connected to the one or more sensors and the model training module. The runtime algorithm may compare realtime data from the one or more sensors and historical data from the model training module in accordance with a machine learning algorithm. The system may further incorporate a fault detection module connected to the runtime algorithm module, a fault diagnostics module connected to the fault detection module, and an enunciator connected to the fault detection module. The one or more sensors may also include having video or acoustic sensitivity of combustion in the burner.

Abstract: A system and approach for catalyst model parameter identification with modeling accomplished by an identification procedure that may incorporate a catalyst parameter identification procedure which may include determination of parameters for a catalyst device, specification of values for parameters and component level identification. Component level identification may be of a thermal model, adsorption and desorption, and chemistry. There may then be system level identification to get a final estimate of catalyst parameters.

Abstract: Provided is a method of modeling behavior for a self-driving vehicle, e.g., as a follower vehicle. Also provided is a vehicle configured to execute the behavior model to cooperatively navigate at least one structural element in an environment. The structural element can be or include a door, a vestibule, and/or an elevator, as examples. The behavior model can be formed by a method that includes tracking and measuring leader-follower interactions and actions with at least one structural element of an environment, representing the leader behaviors and the follower behavior in a behavior model, and electronically storing the behavioral model. The leader-follower interactions and actions can include leader behaviors and follower behaviors, including starts, stops, pauses, and movements of the leader, follower vehicle, and/or objects.

Abstract: Provided is a self-driving vehicle, e.g., a follower vehicle, that engages in communicative behaviors using body dynamics. Also provided is a method of using body dynamics to communicate behaviors in a self-driving vehicle. The vehicle may include a shifting assembly configured to shift and/or tilt a vehicle body to communicate such behaviors, e.g., acceleration, deceleration, and near constant velocity. The shifting and/or tilting of the body in combination with the vehicle's operation communicates those operations to bystanders. With better informed bystanders, improved safety between bystanders and the vehicle may be achieved.

Abstract: A method of operation of a navigation system comprising: determining a geographic limitation with a control unit based on the geographic limitation associated with a traveler information included in a traveler restriction information; generating a provisional route based on a path between a start point and a destination point; determining a provisional POI based on a POI of the provisional route; determining a POI restriction based on the POI restriction associated with the provisional POI included in a rule information; determining a navigation restriction based on matching the geographic limitation and the POI restriction for presenting on a device.

Abstract: A method of operation of a vehicle system including capturing a current image from a current location towards a travel direction along a travel path; generating an image category for the current image based on a weather condition, the current location, or a combination thereof; determining a clear path towards the travel direction of the travel path based on the image category, the current image, and a previous image; and communicating the clear path for assisting in operation of a vehicle.

Abstract: A two-wheeled vehicle is provided. The two-wheeled vehicle includes a chassis having a height, a length and a width, in a first wheel rotatably connected to the chassis, the first wheel having a perimeter, a diameter and a geometric center, and the diameter of the first wheel being at least 75% of the height of the chassis, a motor for providing a drive energy to the first wheel, an axle rotated by the motor, a drive gear connected with the axle such that the drive gear rotates with a rotation of the axle, and a plurality of teeth disposed about the first wheel and mechanically engaged with the drive gear at a location closer to the perimeter of the first wheel than to the geometric center of the first wheel.

Abstract: Provided is a method of modeling behavior for a self-driving vehicle, e.g., as a follower vehicle. Also provided is a vehicle configured to execute the behavior model to cooperatively navigate at least one structural element in an environment. The structural element can be or include a door, a vestibule, and/or an elevator, as examples. The behavior model can be formed by a method that includes tracking and measuring leader-follower interactions and actions with at least one structural element of an environment, representing the leader behaviors and the follower behavior in a behavior model, and electronically storing the behavioral model. The leader-follower interactions and actions can include leader behaviors and follower behaviors, including starts, stops, pauses, and movements of the leader, follower vehicle, and/or objects.

Abstract: The invention relates to a computer-implemented method comprising: receiving (102) a set of pedigree scores (300, 512) of pairs of plant breeding units over two or more generations; receiving (104) an incomplete set of similarity scores (200, 510) of the pairs of the plant breeding unit pairs; aligning (106) the pedigree scores and the similarity scores of identical plant breeding unit pairs; automatically analyzing (108) the aligned pedigree scores and similarity scores for computing a predictive model (508) based on associations of the similarity scores and of the pedigree scores; using the predictive model for creating (112) a complete set of similarity scores (400, 518); and using (114) the complete set of similarity scores for computationally predicting a feature (522) of a plant breeding unit or of an offspring thereof.

Abstract: Provided is a method of modeling behavior for a self-driving vehicle, e.g., as a follower vehicle. Also provided is a vehicle configured to execute the behavior model to cooperatively navigate at least one structural element in an environment. The structural element can be or include a door, a vestibule, and/or an elevator, as examples. The behavior model can be formed by a method that includes tracking and measuring leader-follower interactions and actions with at least one structural element of an environment, representing the leader behaviors and the follower behavior in a behavior model, and electronically storing the behavioral model. The leader-follower interactions and actions can include leader behaviors and follower behaviors, including starts, stops, pauses, and movements of the leader, follower vehicle, and/or objects.

Abstract: A computing system includes: a control unit, coupled to the communication unit, configured to: monitor a current vehicle operation measure for an essential vehicle control function of a user vehicle in an autonomous vehicle operation state; calculate an operation measure modification factor based on a vehicle operation profile of the user vehicle; calculate a modified model input from the current vehicle operation measure based on the operation measure modification factor; generate a vehicle operation instruction, with the modified model input, for the essential vehicle control function according to a vehicle operation model to operate the essential vehicle control function of the user vehicle in the autonomous vehicle operation state; and a communication unit configured to provide the vehicle operation instruction to an autonomous vehicle operation system.

Abstract: Provided is a method of modeling behavior for a self-driving vehicle, e.g., as a follower vehicle. Also provided is a vehicle configured to execute the behavior model to cooperatively navigate at least one structural element in an environment. The structural element can be or include a door, a vestibule, and/or an elevator, as examples. The behavior model can be formed by a method that includes tracking and measuring leader-follower interactions and actions with at least one structural element of an environment, representing the leader behaviors and the follower behavior in a behavior model, and electronically storing the behavioral model. The leader-follower interactions and actions can include leader behaviors and follower behaviors, including starts, stops, pauses, and movements of the leader, follower vehicle, and/or objects.

Abstract: A navigation system includes: a control unit configured to: identify a route obstacle in a travel environment of a user vehicle during operation of the user vehicle in an autonomous operation mode; generate an obstacle handling assessment of whether the user vehicle is capable of navigation beyond the route obstacle in the autonomous operation mode; generate an obstacle orientation alert based on the obstacle handling assessment and an engagement state of a system user of the user vehicle; a user interface, coupled to the control unit, configured to present the obstacle orientation alert.

Abstract: A method of operation of a navigation system includes: determining a start guidance area excluding a current location; determining an end guidance area excluding a destination; and generating a navigation guidance with a control unit for traversing from the start guidance area to the end guidance area to reach the destination.

Abstract: A navigation system includes: a communication unit configured to receive vehicle environment information of a user vehicle for identifying a proximately located vehicle relative to the user vehicle during operation of the user vehicle; a control unit, coupled to the communication unit, configured to: determine proximate vehicle information of the proximately located vehicle, including a relative location and a relative distance from the user vehicle, from the vehicle environment information; and generate a navigation interface including a proximate vehicle representation of the proximately located vehicle and a user vehicle representation of the user vehicle on an interface map based on the relative location and the relative distance of the proximately located vehicle, wherein the proximate vehicle representation and the user vehicle representation are presented based on an interface scaled distance for displaying on a device.