Abstract: A defrost duct assembly for a vehicle includes a housing having a wall that defines an air passage. The air passage extends between an inlet and an outlet of the housing. The wall includes an opening into the air passage. A noise attenuation panel is attached to the housing, and covers the opening in the housing. The noise attenuation panel is an acoustic material that is operable to attenuate noise from within the passage of the housing, while maintaining sufficient air flow to adequately defrost a front windshield of the vehicle. The housing may include multiple outlets and multiple openings covered by one or more noise attenuation panels. The noise attenuation panel is preformed to mate with the housing, and minimize disturbance to the flow of air within the passage.

Abstract: In an opposite arrangement-type wiper system, an operation range 5b of an assistant driver's seat-side wiper blade 1b is set in such a way as to be narrower than an operation range 5a of a driver's seat-side wiper blade 1a and to overlap with the operation range 5a only partially. A lower side turn point Lb of the wiper blade 1b is set near an outer periphery R of the operation range 5a and an overlapping operation range 6c is formed between the operation ranges 5a and 5b. A normal stop position of the wiper blade 1b at the time when the wiper system is not running is set on the side of an upper side turn point Ub. While being arranged opposite from each other, the wiper blades 1a and 1b operate in tandem in the same direction when moving back and forth for wiping.

Abstract: In a brushless wiper motor, first and second pressing claws (43a and 43b) are formed on an outer periphery (OP) of steel sheets (34a) forming a stator core (34), and press-fitted to an inner periphery (IP) of the motor housing unit (31) so that the stator core (34) is fixed to the motor housing unit (31), base end portions of the first and second pressing claws (43a and 43b) are respectively connected to first and second walls formed on the outer periphery (OP) of the steel sheets (34a), and tip end portions of the first and second pressing claws (43a and 43b) each serves as a free end, and are directed in a circumferential direction of the stator core (34).

Abstract: A wiper system performs operation control on wiper driving electric motors and based on position information about wiper blades and attached to pivot shafts, wherein a learning mode in which a position of the wiper blades is learned to correct blade position information is executed after the wiper blades are attached to the pivot shafts, respectively. In the learning mode, the wiper blades are moved to a prescribed position such as a lower retracted position, and that the wiper blades are located in the prescribed position is detected by such means as a sensor, a video image, and contact with a jig. If the wiper blades are detected to be in the prescribed position, the blade position information is corrected to a value corresponding to the position.

Abstract: A wiper blade assembly including an varying width elastic member having a first elastic member region and a second elastic member region, wherein the first elastic member region includes a first body part extending in a first direction from a center part of the elastic member; a first end part provided at an end of the first body part; and a first body part center point which is the center of the length of the first body part, and a region ranging from the center part to the first body part center point is a first width maintaining part, and a region ranging from the first end part to the first body part center point is a first width varying part, the elastic member having a curvature applied thereto depending on the length thereof may enable the pressing pressure to be uniformly distributed in the lengthwise direction of the wiper blade assembly.

Abstract: An aspect of the invention refers to a system for cleaning an external vehicle-mounted sensor surface. The system comprises an air nozzle arranged to discharge air onto a sensor surface; an air pump comprising a fluid inlet, an air outlet, an air-fluid interface and a variable volume compression chamber communicated with the air outlet; an air flow control device communicated with the air nozzle and the air outlet for controlling the flow of air therethrough; and a liquid pump communicated with the fluid inlet to supply a flow of pressurized liquid such that the volume of the compression chamber varies to generate a volume of pressurized air with an absolute pressure below 10 bar.

Abstract: The invention refers to an on-board vision and cleaning system comprising a sensor unit mounted in a vehicle body, a cleaning fluid source, a cleaning fluid pump, a nozzle carrier, at least one cleaning fluid nozzle attached to the nozzle carrier, wherein the nozzle carrier is designed as a swivel arm which upon actuation may be flipped from a tilted back position which is a rest position into an elevated position which is an operating position.

Abstract: A vehicle camera protection and cleaning system is disclosed in which at least one wiper is positioned on an underside surface of a camera cover to clean a lens of a vehicle camera. In one embodiment, the system includes an inner ring fixedly attached to an underside surface of the cover, and a plurality of aperture members pivotally connected to the inner ring on one end and pivotally connected on another end to an outer gear that is movable relative to the inner gear, where at least one of the plurality of aperture members comprises a wiper configured to clean a lens of the camera when the aperture members are moved over the lens. In other embodiments, the wiper may be positioned on an underside surface of a cover of the camera that either rotates in a circular manner or translates over the lens of the camera.

Abstract: A vehicle wash component includes a hub portion with a first hub section and a second hub section. The first hub section includes a first distal end and a first proximate end opposite the first distal end. The first hub section defines a first axis of rotation. The second hub section includes a second distal end and a second proximate end opposite the second distal end. The second hub section defines a second axis of rotation. A connector device rotatably couples the first hub section to the second hub section. An actuator is in communication with the first hub section to effectuate movement of the first distal end between a retracted position and an extended position. In the retracted position, the first axis of rotation and the second axis of rotation are parallel. In the extended position, the first axis of rotation is at a non-90 angle with respect to the second axis of rotation.

Abstract: A brake system for a vehicle includes a first brake device for braking a first wheel of the vehicle, a second brake device for braking a second wheel of the vehicle, a first brake pedal which is paired with the first wheel, a second brake pedal which is paired with the second wheel, a brake control valve which is designed to act on the first brake device and/or the second brake device, a first control valve for controlling a brake pressure in the first brake device, and a second control valve for controlling a brake pressure in the second brake device. The brake system further has an electromechanical switching module in order to block or at least reduce a braking effect of the second brake device while the first brake pedal is being actuated, and the switching module is designed to block or at least reduce a braking effect of the first brake device while the second brake pedal is being actuated.

Abstract: A valve module is provided for enabling a vehicle to control an autonomous event of the vehicle. The valve module comprises a relay valve, a first solenoid valve, and a second solenoid valve. A first control pressure can be delivered through the first solenoid valve and applied to a control port of the relay valve. In one embodiment, a second control pressure can be delivered through the second solenoid valve and combined with the first control pressure. The combined first and second control pressures are applied to the control port of the relay valve. In another embodiment, a second control pressure can be delivered through the second solenoid valve only when no first control pressure is delivered through the first solenoid valve.

Abstract: A guide ring for a piston pump of a vehicle brake system includes a body and a seal. The body is configured to movably support a piston of the piston pump in a cylinder liner. The seal is held on the guide ring and configured to inhibit passage of air between the piston and the guide ring during movement of the piston.

Abstract: A pneumatic brake system (110) for a commercial vehicle (1) has one spring brake (27), a protection valve (56), a parking brake unit (30), a network of pipelines (40), at least a first (4) and a second (5) tank with compressed air and a relay valve (19) for the parking brake unit (30). A first subnetwork of pipelines (40a) comprises pipelines configured to be pressurized at all times. A second subnetwork of pipelines (40b) comprises at least one pipeline configured to be non-pressurized when the parking brake function is applied. The first subnetwork (40a) comprises pipelines establishing fluid communication between the tanks (4, 5) and the parking brake unit (30), wherein the direction of air flow in these pipelines is by at least one thereto associated valve (50). A method for managing an air flow to an air-actuated spring brake (27) of a pneumatic brake system (110) is disclosed.

Abstract: A vehicle brake system for giving an excellent brake feeling to a driver includes: a stroke detector configured to detect a stroke of a brake pedal; a brake fluid pressure generator including a motor actuator and configured to generate a brake fluid pressure by operation of the motor actuator, and a controller configured to control the operation of the motor actuator on the basis of a detected value by the stroke detector. The controller has a base required-deceleration map for obtaining a base required-deceleration associated with a detected value by the stroke detector; a responsive-feeling required-deceleration map for obtaining a responsive-feeling required-deceleration associated with the detected value by the stroke detector; and a phase-lag processor applying phase-lag processing on the responsive-feeling required-deceleration, and control the operation of the motor actuator on the basis of the required-deceleration and the responsive-feeling required-deceleration applied with the phase-lag processing.

Abstract: Methods for estimating the cooling time of a brake assembly are disclosed. Methods are provided comprising receiving, by the processor, a first temperature of a brake assembly at a first time, receiving, by the processor, a second temperature of a brake assembly at a second time, wherein the second time occurs a fixed period after the first time, determining, by the processor, a temperature decay coefficient (“?”) of the brake assembly based on the first temperature and the second temperature and calculating, by the processor, an estimated total time to cool the brake assembly to a predetermined temperature based on the first temperature, the predetermined temperature and ?.

Abstract: A brake fluid feeding device includes a fluid container, a cap, and an inflator. The cap is assembled on the fluid container. The cap has a first hole and a second hole opened thereon. A gas inlet hose is connected to the first hole and extending outward. A fluid-supplying hose is connected to the second hole. The inflator has a gas-supplying portion for gas output. One end of the gas inlet hose is detachably connected to the gas-supplying portion. When the gas inlet hose is connected to the gas-supplying portion, the gas output from the gas-supplying portion enters into the fluid container via the gas inlet hose. Accordingly, the brake fluid feeding device has a simple structure and can be operated conveniently.

Abstract: This invention provides a secure self-driving system or drive-assisting system. A drive control system of the present invention has an image recognition unit for detecting the peripheral environment of a vehicle and a drive control apparatus that controls driving of the vehicle, characterized by having a peripheral environment storage unit for storing the peripheral environment of the vehicle and by changing a mode of drive control performed by the drive control apparatus on the basis of a detection performance status of the image recognition unit obtained on the basis of information about the peripheral environment stored in the peripheral environment storage unit and information detected by the image recognition unit.

Abstract: The present invention relates to a method for managing the drive system of a hybrid vehicle comprising an internal combustion engine and an electric machine having an energy storage means, wherein the vehicle has information on the topology of an approaching downward section of road. Said method includes: predicting a power need of the vehicle according to at least one slope degree of said section of road; predicting the mode of operation of the drive system as well, said mode of operation being selected from at least: a freewheel descent, a descent assisted by the drive system, preferably by the electric machine only, a descent braked by energy recovery; and adjusting the energy level in the storage system prior to arrival on the section of road according to said predictions.

Abstract: An anti jerk control system and method of an eco-friendly vehicle are provided to prevent a driver from sensing a difference in vehicle starting at an initial stage when the vehicle is parked on a downhill road. The anti-jerk control method uses a motor as a driving source and includes calculating an actual speed of the motor, calculating a model speed of the motor, and acquiring a gradient of a road, on which the vehicle is located, using a gradient detector. Additionally, the method includes determining a speed offset value that corresponds to the acquired gradient, compensating the model speed by the speed offset value, and calculating a motor vibration component using a difference between the compensated model speed and the actual speed of the motor. Then, anti-jerk compensation torque is calculated using the calculated motor vibration component.

Abstract: A plurality of virtual gear positions are established by an electric continuously variable transmission, and the number of speeds of the virtual gear positions is equal to or larger than the number of speeds of mechanical gear positions of a mechanical stepwise variable transmission. One virtual gear position or two or more virtual gear positions is/are assigned to each mechanical gear position, and the mechanical gear position is shifted in the same timing as shift timing of the virtual gear position. The virtual gear positions assigned to each mechanical gear position when the mechanical gear position is upshifted are different from the virtual gear positions assigned to each mechanical gear position when the mechanical gear position is downshifted. Thus, the amount of heat generated in frictional engagement elements of the mechanical stepwise variable transmission is prevented from being increased.

Abstract: On simultaneous shifts in which shift control of virtual gear positions overlaps shift control of mechanical gear positions, an electronic control unit is configured to delay output of a shift command on the virtual gear position such that shifts of the virtual gear position and the mechanical gear position are performed in synchronization. Therefore, the virtual gear position and the mechanical gear position are shifted in synchronization, irrespective of a difference between the shift response times, and the feeling of strangeness given to the driver due to shift shock, or the like, is suppressed.

Abstract: A hybrid drive apparatus is provided to allow setting a variety of driving modes while achieving improvement in transmission efficiency. The hybrid drive apparatus includes an engine, first and second motor generators and a planetary gear mechanism. An output shaft of the first motor generator, an output shaft of an engine and an output shaft of the second motor generator, and an input shaft of the continuously variable transmission mechanism are coupled respectively to a sun gear, ring gear and carrier of the planetary gear mechanism. The hybrid drive apparatus includes first, second and third clutches which can switch engagement/disengagement respectively between the output shaft of the engine and the ring gear, between the carrier and the ring gear, and on the input shaft of the continuously variable transmission mechanism.

Abstract: An arrangement and method for optimizing load position in relation to a plurality of transportation vehicles comprising at least one master vehicle and at least one slave vehicle, the arrangement comprising a platform arranged to the at least one slave vehicle for receiving a load; an actuating device of the at least one slave vehicle for moving the platform in relation to the at least one slave vehicle; a sensing device configured to generate a vehicle sensing signal and/or a non-vehicle sensing signal; an a controlling device of the at least one master vehicle.

Abstract: A travel control device for a vehicle executes a self-driving control based on traveling environment information on which the vehicle travels and traveling information on the vehicle. In the device, a traveling environment information acquisition unit acquires the traveling environment information. A traveling information detection unit detects the traveling information. An unstable behavior detector detects an unstable behavior in one or both of a rolling direction and a yaw direction of the vehicle. A steering wheel holding state detector detects a state in which a driver holds a steering wheel. The first unstable behavior reducer reduces the detected unstable behavior by correcting a steering angle. A second unstable behavior reducer reduces the detected unstable behavior by selecting a predetermined wheel and applying a braking force to the wheel. A vehicle behavior controller freely operates the unstable behavior reducers according to detection results.

Abstract: A method (and corresponding parking facility management server, parking system, and computer program) for carrying out an automatic parking process of a vehicle includes a reservation request for a parking position of a parking facility being sent to a parking facility management server via a communication network, navigation data for an autonomous navigation to the reserved parking position corresponding to the reservation request being received by the vehicle via the communication network, and the vehicle autonomously navigating in the parking facility to the reserved parking position based on the navigation data. It is preferably provided that the vehicle autonomously pulls into the parking position, pulls out of this parking position, and travels back to a drop-off position or pick-up position, from which a driver of the vehicle may pick up the vehicle.

Abstract: A method for the assisted driving of a vehicle. A setpoint trajectory for the vehicle to be followed in a parking facility being ascertained as a function of a type of the vehicle. The ascertained setpoint trajectory is transmitted to the vehicle via a communication network. A digital map of the parking facility is transmitted to the vehicle via the communication network. The vehicle may autonomously drive in the parking facility based on the setpoint trajectory and the digital map. Additionally, the vehicle may be monitored with the aid of a vehicle-external monitoring system while it is driving autonomously in the parking facility. A device for the assisted driving of a vehicle, a method and a device for operating a vehicle, a parking system for vehicles, a vehicle, and a computer program, are also described.

Abstract: A server for operating a parking facility, including: —a database in which a digital map of a parking facility is stored, —a processor which is designed for ascertaining at least one target position for a vehicle in the parking facility and at least one section of the digital map which corresponds to a portion of the parking facility, through which the vehicle is to drive autonomously during its driving operation to the target position, and —a communication interface which is designed for transmitting the section of the digital map and the target position to the vehicle via a communication network. A method for operating a parking facility, a device and a method for operating a vehicle, a vehicle, a parking system, and a computer program, are also described.

Abstract: A composite autonomous driving assistant system for making decision and a method of using the same is provided. A longitudinal-controlling autonomous driving assistant device and a lateral-controlling autonomous driving assistant device start to automatically assist in driving a vehicle. Then, a sensing device senses states of the vehicle and an environment and generates one sensing signal. When a controller determines that the collision period is less than a preset collision period and that a deceleration signal of the sensing signal is larger than a preset deceleration, the controller generates a turn-stopping signal. When the controller determines that a rotation angle signal of the sensing signal is larger than a preset angle, the controller generates a speed-stopping signal. The present invention establishes an excellent switching threshold condition when the plurality autonomous driving assistant device coexist.

Abstract: A lane keeping control apparatus includes a selection unit configured to select an operational mode of lane keeping control from operational modes based on an approaching speed; and a control unit configured to execute the lane keeping control in the selected operational mode. The operational modes include a first operational mode in which a steering unit is operated, and in which a brake unit is not operated, and a second operational mode in which the steering unit is operated, and in which the brake unit is operated. If the approaching speed is less than a threshold value, the selection unit selects the first operational mode, and if the approaching speed is the threshold value or greater, the selection unit selects the second operational mode.

Abstract: A system for control of a steering system of a vehicle, mechanically coupled to the wheels and including an actuator for applying a force or a torque to the steering system. A force or torque can be superimposed on a force or torque originating from the wheels. The system includes a detection unit disposed on the vehicle and configured for anticipatorily detecting at least one surface condition of a surface section located ahead of the vehicle in the direction of vehicle travel and subsequently driven on by the vehicle. The system including a data processing unit disposed on the vehicle and connected to and communicating with the detection unit. The data processing unit configured for generating control signals for controlling an actuator of the steering system based on the detected surface condition.

Abstract: A driving assistance apparatus is mounted in an own vehicle and performs driving assistance for the own vehicle. The driving assistance apparatus determines a travel recommended lane in which the own vehicle is to travel, based on a comparison of a preset vehicle speed set in advance to allow the own vehicle to travel at a constant speed, to a travel state of a preceding vehicle traveling ahead of the own vehicle in a travel lane in which the own vehicle is traveling and a travel state of an adjacent vehicle traveling ahead of the own vehicle in an adjacent lane that is adjacent to the travel lane. The driving assistance apparatus performs output based on the travel recommended lane.

Abstract: Disclosed are an adaptive cruise control apparatus and an adaptive cruise control method using the same. An adaptive cruise control apparatus comprises an image acquisition device for acquiring image data in front of a subject vehicle; and a processor configured to detect presence of a forward vehicle using the image data; obtain information on the forward vehicle by using information on the presence of the forward vehicle and the image data; and predict a trajectory and speed of the subject vehicle using the information on the forward vehicle.

Abstract: One of objectives of the present invention is to provide a vehicle control system, a vehicle control method and a vehicle control program, which can properly perform control related to automatic driving based on the energy of the vehicle. The vehicle control system comprises: an automatic driving control part, executing automatic driving performing automatic driving of at least one of velocity control and steering control of an automatic vehicle, and a function limiting part, limiting functions related to automatic driving when the energy of the vehicle is insufficient due to automatic driving.

Abstract: A vehicle control system includes : a driving controller that executes any one of automated driving and manual driving; an electrically drivable driver's seat of the vehicle; a state detector that detects a state of an occupant seated in the driver's seat; and a seat controller that drives the driver's seat if the state detector detects that the occupant seated in the driver's seat is not in a wakeful state, when a changeover of the driving modes by the driving controller causes a transition from a driving mode in which the occupant seated in the driver's seat does not have a responsibility to monitor the surroundings of the vehicle, to a driving mode in which the occupant has the responsibility to monitor the surroundings.

Abstract: A vehicle control apparatus for controlling a vehicle including an engine, a motor generator, a manual transmission, a clutch, an accelerator pedal, a clutch pedal, a brake pedal, a shift lever, and a control unit that performs inertia travel control to cause a vehicle to start inertia travel when a predetermined condition is satisfied during travel of the vehicle, performs free-run transition control to change to a free-run travel when a predetermined inertia travel time has elapsed since the start of the inertia travel, and sets the inertia travel time in a case where the last operation before the inertia travel is one of predetermined operation to be longer than the inertia travel time in a case where the last operation before the inertia travel is an operation in which the return speed of the accelerator pedal is greater than or equal to a predetermined return speed.

Abstract: Provided is a control apparatus of a vehicle, which includes a transmission mode switching control program for controlling the automatic transmission to switch between an automatic transmission mode and a manual transmission mode, a coast idle stop control program for performing a coast idle stop control in which the engine is stopped automatically and the automatic transmission is changed into a neutral position while the vehicle is traveling, and a coast idle control program for performing a coast idle control in which the engine is made running idle and the automatic transmission is changed into the neutral position while the vehicle is traveling.

Abstract: A vehicle behavior stabilization apparatus 10 as a vehicle control system includes: a selector position sensor 28 configured to detect a selector position selected in accordance with an operation of a selector lever 52, and wheel velocity sensors 30, 31 configured to measure a direction of travel and a traveling velocity |V| of a vehicle 40, and an ESP-ECU 12 configured to execute velocity reducing control that applies a braking force with wheel cylinders 36 in a case where the measured direction of travel is different from a tendency of behavior corresponding to the detected selector position and the measured traveling velocity |V| is larger than a threshold value Vth.

Abstract: An agricultural vehicle and method of controlling the same are provided, the vehicle having a motive power unit providing a driving torque to at least one driven wheel and having at least one tyre or track frictionally coupled with the periphery of the driven wheel. A vehicle operating parameter is controlled in dependence on the driving torque and a slippage characteristic relating the respective driving torque at which the frictional coupling between driven wheel and tyre or track begins to slip for a range of vehicle operating parameter values. The operating parameter is suitably a tyre pressure or track tension, and the control may involve reducing driving torque or increasing pressure/tension to prevent slipping.

Abstract: A driving consciousness estimation device includes a driving readiness estimation unit configured to estimate a driving readiness relating to a driving consciousness of the driver from a driver's reaction to the travelling environment, a driving task demand estimation unit configured to estimate a driving task demand which is an index required for the driver with respect to the driving readiness from the travelling environment, and an attention awakening unit configured to execute awakening of attention for the driver relating to the driving of the vehicle based on the result of comparison between the driving readiness and the driving task demand.

Abstract: A vehicle control-system includes an automated driving controller and a vehicle-side communication section. The automated driving controller executes automated driving in which at least one out of speed control or steering control of a vehicle is performed automatically, and executes automated driving in a mode from out of plural modes with differing degrees of automated driving. The vehicle-side communication section communicates with a server for managing characteristic information of a vehicle occupant. The automated driving controller controls automated driving based on the characteristic information of the vehicle occupant received from a server-side communication section using the vehicle-side communication section.

Abstract: A vehicle control system includes: an automated driving controller executing automated driving that automatically performs at least one of speed control and steering control of a vehicle to allow the vehicle to travel to a set destination; a calculator which, referring to a plan of the automated driving, calculates an amount of energy expected to be consumed if the vehicle travels the guiding route from the current position of the vehicle to the destination by the automated driving; and a route changing section which changes the guiding route based on the amount of energy calculated by the calculator.

Abstract: Vehicle setting data received from a vehicle is processed according to preferences and rules set forth by the vehicle's driver. The processed vehicle setting data can be shared with various third-parties.

Abstract: Example systems and methods for vehicle mode scheduling with learned user preferences are disclosed. The example disclosed method includes monitoring vehicle data when a vehicle changes from a first mode to a second mode. The example method also includes analyzing the vehicle data to identify a preference for the second mode during a driving context. Additionally, the example method includes generating a recommendation on whether to switch to the second mode while traversing a route based on the vehicle data, and the driving context, and presenting the recommendation to the driver.

Abstract: A vehicle automated driving system 100 comprises a surrounding environment information acquiring device 10, a vehicle information acquiring device 20, a driver information acquiring device 30, a package selecting part 90, a package proposing part 91, an automated driving executing part 92, and a rejection count detecting part 93. The package selecting part determines the driving assistance package based on at least one of the surrounding environment information, the vehicle information, and the driver information, selects the determined driving assistance package if the rejection count of the determined driving assistance package is less than a predetermined threshold value, and selects a driving assistance package different from the determined driving assistance package if the rejection count of the determined driving assistance package is the threshold value or more.

Abstract: A vehicle control system includes an automated driving controller configured to execute automated driving of a vehicle by automatically performing at least one of speed control and steering control of the vehicle, an operation reception section configured to receive an operation to switch a shift position of the vehicle, and an operation controller configured to limit reception, by the operation reception section, of the operation to switch the shift position while the automated driving is being executed by the automated driving controller.

Abstract: A sensory stimulation system for autonomous vehicle (AV) can determine a set of maneuvers of the AV. Based on each respective maneuver, the sensory stimulation system can determine a set of visual stimulation outputs to provide a passenger of the AV with visual indications of the respective maneuver. The sensory stimulation system can then display the set of visual stimulation outputs on a display unit within the interior of the AV prior to executing each respective maneuver.

Abstract: A ropeway vehicle transportation network includes pairs of ropeway cables on which ropeway vehicles travel the network stations. A plurality of network stations are line changer stations connected to at least two ropeway lines. Each line changer station includes shifter rails that rotate around a vertical axis. When a first ropeway vehicle is on the shifter rails, the shifter rails can be rotated to select on which set of the at least two ropeway lines the first ropeway vehicle will traverse when the first ropeway vehicle exits the shifter rails.

Abstract: A ropeway vehicle is used within a ropeway vehicle transportation network. The ropeway vehicle includes at least one power drive wheel that is powered to move the ropeway vehicle along ropeway lines. At least one commutator wheel draws electrical power from ropeway cables that form the ropeway lines. A controller includes an on-board battery to back-up and supplement electrical power obtained from the ropeway cables.

Abstract: A system is provided that includes a detection circuit having a first and second sensor. The first sensor is configured to measure a rotational speed of a first wheel. The second sensor is coupled to a vehicle chassis and configured to measure a position over time of the vehicle chassis. The system further includes a controller circuit configured to determine a shock frequency based on the position of the vehicle chassis. The controller circuit is further configured to determine a condition (e.g., an anomalous condition) of the first wheel based on the shock frequency and the rotational speed, and may be further configured for vehicle control based on the determined condition.

Abstract: A method is provided for operating a vehicle having a drive unit, a driving-data determination unit, a consumer set, and a power management unit for managing the consumer set. The driving-data determination unit identifies or determines driving curve data and the drive unit is controlled on the basis of the driving curve data. The method achieves an optimization with regard to a defined quality criterion while also taking the consumer set into account, in that the power management unit receives consumer data from the consumer set, the power management unit determines anticipatory load profile data at least on the basis of the consumer data, determination or identification data are transmitted to the driving-data determination unit in accordance with the load profile data, and the driving-data determination unit determines or identifies the driving curve data in accordance with the determination data.