Abstract: Methods and systems are disclosed for radio positioning of a vehicle using a virtual positioning reference established by logging a known position of the vehicle together with a local time that a first instance of a predictably repeated code word is received from an opportunistic terrestrial radio transmitter. During movement of the vehicle to a second, unknown position, a local clock is used to determine the time difference between when the virtual positioning reference is predicted to receive a second instance of the code word and when the vehicle actually receives the second instance of the code word, thereby providing positioning information when traditional navigation signals such as GPS are not available. The radio positioning information is then used to initiate an action such as recording the location information for future retrieval by a user, and/or controlling the movements of an autonomous vehicle.

Abstract: An apparatus includes (i) an absolute position sensor coupled to a case, the position sensor including a light sensor, and circuitry configured to determine an identifier within a barcode, the individual bars of the barcode being sensed by the light sensor, and (ii) a motion sensor coupled to the case, the motion sensor including a first magnetic field sensor, a code wheel having two or more magnets positioned to rotate in unison with a wheel of the moveable object, and encoder circuitry configured to determine an amount of rotation of the wheel of the moveable object based on an output of the first magnetic field sensor.

Abstract: A regenerative braking control method of a hybrid vehicle may include determining whether to perform regenerative braking in a regenerative braking determining step, determining whether to stop an engine in an engine stopping determining step, and performing shifting to a lowest gear stage driven by a motor in a preceding shifting step if it is determined in the engine stopping determining step that the engine stops.

Abstract: An autonomous method for detecting when an earthmoving machine has moved a pile of dirt into contact with another pile of dirt may include receiving at a controller a plurality of signals indicative of one or more parameters including a ground speed of the machine, a target ground speed of the machine, a load on a work implement of the machine, an output speed of a torque converter of the machine, a machine pitch, a machine steering command, a machine heading, and a heading of a slot the machine is in. The controller may standardize and normalize each signal from the plurality of signals in order to create values for each of the one or more parameters that all fall within a common range, wherein the common range is representative of a range from minimum to maximum values for each of the one or more parameters.

Abstract: A device for making available navigation parameter values of a vehicle is provided. The device includes components distributed in the following categories: several sensors collecting measurement data relating to at least one navigation parameter of the vehicle; several computers processing the measurement data collected by the sensors and calculating said navigation parameters; several networks linking the sensors to the computers and linking the computers to systems using said parameters. The networks transmit all the collected measurement data to the computers, which calculate a value for each navigation parameter as well as an estimated value of the associated fault, using a single common fusion algorithm.

Abstract: A system for reprogramming a vehicle controller includes: a plurality of controllers equipped in a vehicle; a battery configured to provide operation power to the plurality of controllers; and a charging control device configured to sense a connection with a charger providing charging power from an external power source to the battery, request latest software version information corresponding to each of the plurality of controllers from the charger through power-line communication (PLC) while the charging power is provided from the charger to the battery, confirm the requested latest software version information, receive upgrade data from the charger, and transmit the received upgrade data to the plurality of controllers.

Abstract: It is disclosed to select a relative positioning method from a set of at least two different relative positioning methods that are for determining an estimate of a relative position between first and second entities. The method is selected in dependence on at least one of the following criteria: an estimated/measured distance between the first and second entities; a relative positioning capability, of at least one of the first entity, the second entity and at least one server entity associated with at least one of the first and second entities, to determine an estimate of a relative position between two entities; and an availability, at at least one of the at least one server entity, of a service providing data of at least one reference entity useable for determining an estimate of a relative position between the reference entity and one of the first and second entities.

Abstract: A method is provided for monitoring a state of health of a vehicle system and includes measuring a plurality of parameter values for the system at different running conditions as an end of line test, storing the parameter values in a fingerprint file, measuring the same plurality of parameter values that is comprised in the fingerprint file after a predefined time interval, adding a predefined ageing offset to the fingerprint file, where the ageing offset corresponds to a predicted wear of the system during the predefined time interval, thereby obtaining a time modified fingerprint file for the system, comparing the measured values with the time modified fingerprint file, and issuing a message if the measured values deviates from the time modified fingerprint file. The state of health can be compared with initial measurements such that the state of health of a vehicle system or component can be monitored over a longer time period.

Abstract: A method for monitoring a drive of a motor vehicle, including acceleration monitoring, including: ascertaining an actual acceleration of the motor vehicle with the aid of a signal of a kinematics sensor, in particular of an acceleration sensor or of a wheel speed sensor, ascertaining a permissible acceleration of the motor vehicle as a function of a position of a gas pedal, and ascertaining the permissibility of an operating state of the drive as a function of the ascertained actual acceleration and the ascertained permissible acceleration, the permissibility of the operating state of the drive being monitored with the aid of alternative monitoring instead of acceleration monitoring when the operating state of the drive meets at least one predetermined condition.

Abstract: Various embodiments of the present invention are directed to a fleet management system configured for capturing and evaluating vehicle telematics data, such as data captured from one or more vehicle telematics devices indicative of one or more vehicle dynamics, and service data, such as data captured from one or more portable data acquisition devices indicative of one or more service dynamics. In certain embodiments, the fleet management system is configured to associate captured vehicle telematics data with captured service data based on the contextual attributes of each, such as the time, date, and location of data capture. By synching the vehicle telematics data to the service data, the operational data can be uniquely assessed for various operational efficiencies.

Abstract: A method and device for automatically determining a speed profile with speed levels for an aircraft. The device includes a calculation unit which is configured for determining a speed profile (P1) which is such that, from upstream to downstream, the speed (V) is maintained at a speed constraint (V1) imposed at a waypoint (B1), up to said waypoint (B1), then a deceleration (T2) is performed from this waypoint (B1) up to an optimum speed (Vopt), said optimum speed (Vopt) being maintained up to another deceleration (T4) ending directly at a downstream speed limit (V2) reached at a given altitude level (A2).

Abstract: The present disclosure is directed to an autonomous vehicle having a vehicle control system. The vehicle control system includes an image processing system. The image processing system receives an image that includes a light indicator. The light indicator includes an illuminated component. The image processing system determines a color of the illuminated component of the light indicator and an associated confidence level of the determination of the color of the illuminated component. The image processing system also determines a shape of the illuminated component of the light indicator and an associated confidence level of the determination of the shape of the illuminated component. The determined confidence levels represent an estimated accuracy of the determinations of the shape and color. Additionally, the image processing system provides instructions executable by a computing device to control the autonomous vehicle based on at least one of the determined confidence levels exceeding a threshold value.

Abstract: Techniques are provided which may be implemented using various methods and/or apparatuses to allow for delay zone information to be gathered by one or more mobile stations used in route navigation, provided to one or more computing devices and processed in some manner to establish navigation information that may be of use by mobile stations involved in route navigation. For example, in certain instances navigation information may be indicative of an expected delay with regard to at least one known delay zone that may affect a user of the mobile station attempting to adhere to a route.

Abstract: A system and method for determining a direction of travel of a vehicle and/or identifying a misplaced wayside device obtain location data from wayside devices. The location data are representative of locations of the wayside devices along a route being traveled by a vehicle. The system and method also determine whether the location data in a series of the wayside devices exhibit an increase or a decrease in the location data across the wayside devices in the series and, responsive to determining whether the location data in the series of the wayside devices does exhibit the increase or the decrease in the location data, the system and method determine a direction of travel of the vehicle along the route, determine a location of the vehicle along the route, and/or identify a misplaced wayside device.

Abstract: A method for operating an electrical machine, in particular for making available drive power for a drive train of a motor vehicle, the electrical machine being controlled by several phase currents, the method including sensing an electrical variable that represents the torque delivered by the electrical machine; and monitoring the torque. A degradation of the electrical machine is taken into consideration in the monitoring of the torque.

Abstract: When a brake of a tractor is released, a control unit having a computer built therein monitors the pressure of working fluid output from a trailer control valve that controls a brake of the trailer in conjunction with the brake of the tractor. When time required for a pressure of the working fluid to decrease to a predetermined pressure is a predetermined time or longer, the control unit determines that the trailer is coupled with the tractor. When the time is less than the predetermined time, the control unit determines that the trailer is not coupled with the tractor.

Abstract: A method includes detecting at least one position measurement of a separator piston of a pitch trim actuator. The method includes detecting at least one pressure measurement of a gas. The method includes detecting at least one temperature measurement of the gas. The method includes storing at least one position value based on the at least one position measurement of the separator piston, at least one pressure value based on the at least one pressure measurement of the gas and at least one temperature value based on the at least one temperature measurement of the gas. The method includes determining a volume of an oil within an oil chamber of the pitch trim actuator and a pressure of the gas within the gas chamber of the pitch trim actuator, based on the at least one position value, the at least one pressure value and the at least one temperature value.

Abstract: The present disclosure provides a method of controlling a drive speed of a drive unit powering a work machine. The method includes determining if a control switch is in an enabled position and detecting if a control mechanism is moved within a defined period of time to operate the machine to perform a function. The method also includes detecting if a control means has been positioned in the active state once the control mechanism is not moved within the defined period of time. The method further includes sending a signal to a drive unit controller to shut off the drive unit when the control means is triggered to the active state. The drive unit is turned off as electrical energy continues to be provided from an energy storage device to at least the vehicle control unit, drive unit controller, and sensor after the drive unit is turned off.

Abstract: A restraint system includes a plurality of sensors deployable in a vehicle, a restraint device, and a computing device. The restraint device includes a tether, a collar, an actuator coupled to a stopper, and an identification tag. The computing device is programmed to engage the stopper to prevent the tether from extending beyond a predetermined length upon at least one of the sensors indicating the identification tag.

Abstract: An on-the-go monitor and control means and method for an agriculture machines includes on-the-go soil sensors that can be used to control tillage and seeding depth. On seeder implements, the sensors provide information that affects uniform plant emergence.