Abstract: An adaptive, automatically-reconfigurable, vehicle instrument display method and system are described that use information from multiple sensors located within the vehicle that monitor various aspects of a vehicle's operation and health to automatically modify presence and/or location of widgets in the vehicle's instrument display panel based upon circumstances or conditions as they occur or change.

Abstract: An adaptive, automatically-reconfigurable, vehicle instrument display method and system are described that continuously looks for a specified physical action of a driver operating the vehicle and, upon determining that the specified physical action of the driver has occurred, automatically effects a change to at least one widget in the instrument panel display of the vehicle.

Abstract: A method for operating a motor vehicle involves displaying a first assistance graphic of a first active driver assistance system in a first display mode on at least one display device of the motor vehicle when the motor vehicle is operated in a first driving mode, and displaying the first assistance graphic of the first active driver assistance system in a second display mode on the at least one display device when the motor vehicle is operated in a second driving mode that is different from the first driving mode. The first assistance graphic is displayed in a first perspective in the first display mode and is displayed in a second perspective, which is different from the first perspective, in the second display mode.

Abstract: Provided in the present disclosure is a fingerprint bookmark system which may be implemented in a vehicle with one or more configurable interior settings. The fingerprint bookmark system may contain a scanner which may be configured to record a fingerprint from a vehicle occupant such that a fingerprint image showing the fingerprint and a duration data for the fingerprint image are recorded by the scanner. The system may contain one or more processors which may be configured to compare the duration data associated with the fingerprint image with a duration threshold. The one or more processors may be configured to initiate a search to obtain a bookmark for the fingerprint shown in the fingerprint image when the duration data is less than the duration threshold. The one or more processors may be further configured to create a new bookmark when the duration data exceeds the duration threshold.

Abstract: Techniques for electric vehicle systems, and in particular to an electric vehicle charging device obstacle avoidance system and method of use. In one embodiment, a system for obstacle avoidance of a charging panel of an electrical vehicle is disclosed, the system comprising: a charging panel interconnected to the electric vehicle; an actuator interconnected to the charging panel, the actuator configured to position the charging panel; at least one sensor configured to sense an obstacle location measurement in a predicted travel path of the electric vehicle; and an obstacle avoidance controller that receives the obstacle location measurement and determines if an obstacle avoidance action is recommended.

Abstract: Techniques for electric vehicle systems, and in particular to a vehicle to vehicle charging system and method of use. In one embodiment, a system for vehicle to vehicle charging comprises: an electrical storage unit disposed on a charging vehicle; a charging plate in electrical communication with the electrical storage unit, the charging plate configured to provide a charge to a receiving vehicle; a charging vehicle arm interconnected to the charging plate and to the charging vehicle, the charging vehicle arm extendable; a charging vehicle controller that determines if the receiving vehicle requires charging and configured to position the charging plate proximate a charging panel of the receiving vehicle; wherein the charging panel receives a charge from the charging plate and charges the receiving vehicle.

Abstract: A system for charging an electrical storage unit of an electrical vehicle through a contact device, the system comprising: a contact device interconnected to the electrical storage unit of an electrical vehicle and configured to receive an electrical charge from an external power source; a contact arm interconnected to the contact device, the contact arm configured to position the contact device at a first position relative to the external power source; and a contact device controller interconnected to the contact arm and configured to control the contact arm wherein the first position is maintained; wherein the contact device receives the electrical charge from the external power source; wherein the electrical storage unit of the electrical vehicle is charged.

Abstract: Systems, methods, and devices are described with respect to storing energy in an electric vehicle. At least one coil winding located in a wheel assembly is provided, where the wheel assembly includes a tire and a rim. At least one charge storage device located in the wheel assembly is provided. At least one electrical storage unit located within the electric vehicle is provided, where an induced charge resulting from the at least one winding passing through an electromagnetic field is stored in the at least one charge storage device and transferred to the at least one electrical storage unit via the rim of the wheel assembly. Moreover, a charging capacity for the at least one charge storage device may change to cause the electric vehicle to slow.

Abstract: A high voltage device for a vehicle, which at least during driving operation is supplied with electric energy from a power system providing a high voltage, having at least one high voltage component which by a main power switching unit is electrically connectable to the power system and a grounding switching device having at least one switching device. In order to increase personal safety during work on the high voltage device in a constructively simple manner, it is proposed that the high voltage component has at least one receiving region in which the switching device is accommodated—at least in a grounding position that grounds at least one active section of the high voltage component.

Abstract: A battery/capacitive vehicle charging system, the system comprising: at least one capacitive electrical storage unit, disposed on a charge receiving vehicle, and configured to receive a charge at a charging site and further configured to hold a charge at a first charge value; at least one battery, disposed on the charge receiving vehicle, and configured to hold a charge at a second charge value; a charge management unit configured to communicate with the at least one capacitive electrical storage unit and the at least one battery, and further configured to control the first charge value and the second charge value; wherein the at least one capacitive electrical storage unit receives a charge from the charging site wherein the charge receiving vehicle is charged.

Abstract: An apparatus, system and method for wirelessly charging are provided within a vehicular environment. The wireless charging system (500) comprises a seatbelt receptacle (102) containing a transmit coil (104) integrated therein for transmitting a charging signal to a battery or powering a battery operated device. A repeater coil (506) may be wirelessly coupled to the transmit coil (104) via the seatbelt's buckle, as a buckle repeater coil (206) or a retrofit cover repeater coil (308). Additional repeater coils (514, 524) may be added to a shoulder strap (510), lap strap (520), or other portions of the seat belt harness for additional charging points. The additional repeater coils (514, 524) are slideable to adjust for different body sizes. One or more portable devices having receive coils can be charged or powered wirelessly from the transmit coil (104) in the seatbelt receptacle (102), the repeater coil (506) of the seatbelt buckle or cover, and/or the additional adjustable strap repeater coils (514, 524).

Abstract: Techniques for electric vehicle systems, and in particular to an electric vehicle emergency charging system and method of use. In one embodiment, a system for charging an electric vehicle is provided, the system comprising: an electrical storage unit disposed on the electric vehicle; a charging panel in electrical communication with the electrical storage unit; a vehicle controller that determines if the electrical storage unit requires charging and configured to determine if an aerial external power source is available to charge the electrical storage unit; wherein the charging panel receives the charge from the aerial external power source and charges the electrical storage unit.

Abstract: A rechargeable electric vehicle comprises a power rectifier to convert alternating current electrical energy to direct current electrical energy; a power inverter to convert direct current electrical energy to alternating current electrical energy; a rechargeable energy storage for storing direct current electrical energy; and a coil. In a first mode, alternating current electrical energy is received by the coil and passed through the power rectifier to form direct current electrical energy for storage in the rechargeable energy storage. In a second mode, direct current electrical energy is passed through the power inverter to form alternating current electrical energy and the alternating current electrical energy is passed through the coil for wireless transfer, over an air gap, to a secondary coil.

Abstract: A control system for a rechargeable vehicle control system, comprises: a processor and a computer readable medium, in communication with the processor, that comprises processor executable instructions. The processor executable instructions comprise: a vehicle tracker that identifies rechargeable electric vehicles currently using a transportation network and tracks a last known position in the transportation network of each rechargeable electric vehicle and a vehicle router that directs the rechargeable electric vehicles to one of plural charging segments located along the transportation routes in the transportation network to receive a charge, thereby load balancing the rechargeable electric vehicles over the plurality of charging segments.

Abstract: Techniques for electric vehicle systems, and in particular to a vehicle optical charging system and method of use. In one embodiment, a system for vehicle optical charging comprises: an optical charging station configured to transmit an optical signal, the optical charging station comprising a directive element configured to direct the transmitted optical signal; a receiving vehicle comprising an electrical storage unit and a receiver configured to receive the transmitted optical signal, the receiver in electrical communication with the electrical storage unit; wherein the received optical signal enables charging of the electrical storage unit.

Abstract: A system and method for charging a receiving vehicle, the system comprising: a receiving vehicle comprising an electrical storage unit; a charging panel in electrical communication with the electrical storage unit, the charging panel configured to receive a charge from a charging source and charge the electrical storage unit; and a vehicle controller configured to identify one or more charging sources and further configured to transmit a query to the one or more charging sources and receive at least charging data from the one or more charging sources; and one or more charging sources, each comprising: a charging plate configured to provide a charge to the charging panel; and a charging source controller configured to transmit at least charging data to the vehicle controller in response to the query; wherein if the vehicle controller determines that the charging data received is acceptable, the receiving vehicle is charged.

Abstract: A system for vehicle charging comprising: an electrical storage unit disposed on a charge receiving vehicle; at least one integrated charging panel in electrical communication with the electrical storage unit, the at least one integrated charging panel configured to receive a charge at a charging site; a charge receiving vehicle controller configured to communicate with the charging site to determine a compatibility of the at least one integrated charging panel to receive charging from the charging site; wherein the at least one integrated charging panel receives a charge from the charging site wherein the charge receiving vehicle is charged.

Abstract: A system for capacitive vehicle charging, the system comprising: a capacitive electrical storage unit disposed on a charge receiving vehicle, the capacitive electrical storage unit comprising at least one surface conformal with an exterior surface of the charge receiving vehicle, the capacitive electrical storage unit configured to receive a charge at a charging site; a charge receiving vehicle controller configured to communicate with the charging site to receive charging from the charging site; wherein the capacitive electrical storage unit receives a charge from the charging site.

Abstract: Methods, devices, and systems are provided for establishing communications between a vehicle and charging system. The communications may include charge request messages sent by or received from the vehicle defining charge particulars, such as, a charge type, charging locations, charging orientation, and/or other information corresponding to charging requirements for the requesting vehicle. The charging system can respond to the charge request messages accepting or denying the vehicle charging request. In response to accepting the request message, the charging system provides charge to the vehicle in accordance with the charge particulars.

Abstract: Systems, methods, and devices are described with respect to storing energy in an electric vehicle. At least one coil winding located in a wheel assembly is provided, where the wheel assembly includes a tire and a rim. At least one charge storage device located in the wheel assembly is provided. At least one electrical storage unit located within the electric vehicle is provided, where an induced charge resulting from the at least one winding passing through an electromagnetic field created by at least one power transmission line is stored in the at least one charge storage device and transferred to the at least one electrical storage unit via the rim of the wheel assembly.

Abstract: Methods, devices, and systems are provided to shield a passenger compartment of an electric vehicle from electromagnetic fields present during a wireless charging process. A charging system may include a shield portion between the charging plate and a passenger compartment of the electric vehicle. The shield portion may include at least two states, a first state being a non-deployed state and a second state being a deployed state and the shield portion is configured to attenuate an electromagnetic field provided by the charging system when in the second state.

Abstract: Devices and systems are provided to isolate and/or reduce vibration from a charging panel. A system for reducing vibration between a charging panel of an electric vehicle and the electric vehicle may include a charging panel, an armature coupled to the charging panel, and a floating section, wherein the armature is between the floating section and the charging panel.

Abstract: A common problem in wireless charging systems in automotive applications is alignment of the wireless power transfer transmitter and receiver units. Poor alignment leads to poor power transfer capacity and a longer charging time. Costly optical sensors and electromechanical systems may be employed to align the transmitter and receiver units. A solution to this problem is to employ a freely moveable wireless power transmitter in at least one direction that is magnetically attracted to the wireless power receiver unit in the vehicle that does not require electrically powered sensors or mechanical alignment systems.

Abstract: A method and system for efficient distribution of power using wireless means, and a system and method for wireless power distribution to provide electric devices, such as vehicles with a way to continuously and wirelessly collect, use and charge their power systems and thereby use the transmitted power for operation. The system and method allows a hybrid, simplified and less costly way to charge devices, such as vehicles so that the devices continuously operate while charging/recharging.

Abstract: A battery system includes: a power detector that detects output power from an external power source; a charging mechanism that charges a main battery by external power; a temperature raising mechanism that raises a temperature of the main battery to a temperature not lower than a reference temperature; and a controller that controls the charging mechanism and the temperature raising mechanism, wherein when the detected output power is lower than a reference power, the controller prohibits a temperature raising process with an SOC of the main battery lower than a charge reference value and performs a charging process.

Abstract: The disclosure provides a battery which can include a power supply and power supply circuit, the power supply circuit connected to the power supply. The power supply can discharge through the power supply circuit. An electronic switch can control the power-on or off of the power supply, thereby avoiding the generation of sparks during the power on process and allowing for the normal use of the battery and the safety of the aircraft. The disclosure also provides an aircraft having the battery.

Abstract: Techniques for electric vehicle systems, and in particular to an electric vehicle charging system and method of use. In one embodiment, a system for charging an electric vehicle is provided, the system comprising: an electrical storage unit disposed on the electric vehicle; a charging panel in electrical communication with the electrical storage unit; a robotic unit comprising an external power source, a charging plate and a robotic arm, the charging plate interconnected to the robotic arm and configured to provide a charge to the charging panel; and a vehicle controller configured to communicate with the robotic unit and position the charging plate with respect to the charging panel; wherein the charging panel receives the charge from the external power source and charges the electrical storage unit.

Abstract: Techniques for electric vehicle systems, and in particular to an electric vehicle emergency charging system and method of use. In one embodiment, a system for charging a moving electric vehicle is disclosed, the system comprising: an electrical storage unit disposed on the electric vehicle; a charging panel in electrical communication with the electrical storage unit; a vehicle controller that determines if the electrical storage unit requires charging and configured to determine if an emergency external power source is available to charge the electrical storage unit; wherein the charging panel receives the charge from the emergency external power source and charges the electrical storage unit.

Abstract: Techniques for electric vehicle systems, and in particular to an electric vehicle emergency charging system and method of use. In one embodiment, a system for charging a moving electric vehicle is provided, the system comprising: an electrical storage unit disposed on the electric vehicle; a charging panel in electrical communication with the electrical storage unit; a vehicle controller that determines if the electrical storage unit requires charging and configured to determine if an overhead power source is available to charge the electrical storage unit; wherein the charging panel receives the charge from the overhead power source and charges the electrical storage unit.

Abstract: Techniques for electric vehicle systems, and in particular for positioning a charging panel of an electrical vehicle to receive a charge, are provided. In one embodiment, a system for positioning a charging panel of an electrical vehicle to receive a charge comprises an armature disposed on an electrical vehicle; a charging panel interconnected to the armature; and an actuator configured to maneuver the armature and position the charging panel relative to an external surface, the external surface in communication with a power source configured to provide a charge to the charging panel, wherein the charging panel is configured to receive the charge from the power source.

Abstract: Embodiments of the present invention provide a measuring device with a receiver coil array and evaluator. The receiver coil array is configured to detect three magnetic field components of a magnetic field of a conductor loop array generated by an electric alternating current signal and to provide a magnetic field component signal for each of the detected three magnetic field components. The evaluator is configured to evaluate the magnetic field component signals in order to determine the phase relation to the electric alternating current signal allocated for the magnetic field component signals, wherein the phase relations each include coarse position information of the conductor loop array relative to the conductor loop array and wherein the evaluator is configured to determine a resulting intersection of the coarse position information, wherein the resulting intersection includes or results in fine position information of the receiver coil array relative to the conductor loop array.

Abstract: Techniques for electric vehicle systems, and in particular to electric vehicle charging systems and associated methods of use are provided. In one embodiment, a system for aligning a charging panel of an electrical vehicle to receive a charge from an external source is provided, the system comprising a charging panel interconnected to the electrical vehicle; an actuator interconnected to the charging panel; a sensor configured to sense an alignment measurement between the charging panel and an external power source; and an alignment controller that receives the alignment measurement and determines a required alignment adjustment, wherein the charging panel may be adjusted to receive the charge from the external power source.

Abstract: A system includes charging segments positioned throughout a transportation network, the charging segments charging rechargeable electric vehicles. Each charging segment includes a primary coil to charge a selected rechargeable electric vehicle; a power inverter to convert alternating electrical current from a power grid to direct electrical current to pass through the primary coil; a switch to activate and deactivate the ability of the primary coil to charge the selected rechargeable electric vehicle; a transceiver to transmit signals to and receive signals from the selected rechargeable electric vehicle in spatial proximity to the charging segment; and a controller to control the switch in response to signals received from the transceiver.

Abstract: A device and method is provided that establishes a charging connection and a communication connection between a charging station and a vehicle, the vehicle having a first charging device and a first communication device, the charging station having a second charging device and a second communication device. The first charging device is positioned with respect to the second charging device in a way that energy for charging a battery of the vehicle is transmitted via the charging connection, and an orientation of the second communication device with respect to the first communication device, is such that the communication connection can carry out a wireless exchange of information in a way that reception of the information by a further communication device is prevented. The first communication device and the second communication device are configured in a way that the information is emitted and/or received by means of at least one communication unit.

Abstract: Techniques for electric vehicle systems, and in particular to electric vehicle charging systems and associated methods of use are provided. In one embodiment, a system for charging an electric vehicle comprises an electrical storage unit, an external power source, a charging panel, and a vehicle controller configured to determine if the electrical storage unit requires charging and configured to determine if conditions allow for deployment of a charging panel.

Abstract: A control system for a power grid includes a grid load availability evaluator that determines, for a selected time interval, an amount of electrical energy from a power grid that can be used to charge rechargeable electric vehicles by a plurality of charging segments positioned along transportation routes in a transportation network and a switching fabric to regulate, over the selected time interval, the electrical energy provided by the charging segments in accordance with the determined amount of electrical energy from the power grid that can be used to charge rechargeable vehicles.

Abstract: A predictive charging system comprising: a predictive charging station providing a charging service to charge receiving vehicles, the predictive charging station comprising a database, an analysis module, and a billing module, the analysis module configured to determine a charging demand, the billing module configured to determine if charge receiving vehicles may be pre-billed; charge receiving vehicles each comprising a vehicle database and configured to communicate at least a need for the charging service to the predictive charging station and to provide pre-billing for the charging service and to receive the charging service from the predictive charging station; wherein the analysis module determines if the charging service is offered; and wherein if the charging service is offered and the charging service is accepted by at least one of the one or more charge receiving vehicles, the charge receiving vehicle is pre-billed for the charging service and the charging vehicles is charged.

Abstract: An apparatus and a method for detecting a relay fusion of an eco-friendly vehicle are provided. The apparatus and method detect whether a relay for preventing an over-discharge of a lithium ion battery of 12V is fused, by ascertaining a voltage change of the lithium ion battery of 12V based on a variation of an output voltage of a low direct current (DC)-DC converter (LDC).

Abstract: A battery system may include a first battery module that outputs a first voltage and a first current, a second battery module configured to output a second voltage and second current, and a display that depicts visualizations. The battery system may include a processor that may receive an indication to monitor a selected battery module comprising the first battery module or the second battery module, receive properties to monitor regarding the selected battery module, receive data regarding the properties from sensor circuitry configured receive the data from one or more sensors associated with the selected battery module, and generate visualizations that correspond to the one or more properties. Each of the visualizations may indicate a current value that corresponds to each of the properties based on the data. The processor may then display the visualizations on the display.

Abstract: Disclosed is a power system using a switched reluctance motor as a power transformer. The power system comprises a motor controller unit, an electricity storage device, two power converters and a motor set, wherein the electricity storage device, the power converters and a motor are respectively connected to the motor controller unit; one power converter is connected to the electricity storage device, and the other power converter is connected to an external power source; and the two power converters are respectively connected to the motor set. The power system can output relatively high power efficiently using a relatively low system voltage, thereby having relatively high differential tolerance of electricity storage devices, and can use different types of electricity devices in a mixing mode, thereby having strong fault-tolerant capability, good system manufacturing flexibility, high system compactness, low weight and low costs.

Abstract: An electric motor control system for a vehicle includes a vehicle speed module that determines a vehicle speed. A closed loop (CL) module determines a CL torque based on a difference between a target vehicle speed and the vehicle speed. A motor torque module determines a motor torque based on the CL torque and a motor torque request determined based on a position of an accelerator pedal. A switching control module controls switching of an inverter based on the motor torque to control application of power to an electric motor of the vehicle.

Abstract: An electric motor control system for a vehicle includes a vehicle speed module that determines a vehicle speed. A target speed module selectively transitions a target vehicle speed to zero over a period in response a driver actuating an input device. The input device is not an accelerator pedal or a brake pedal. A switching control module, based on a difference between a target vehicle speed and the vehicle speed, controls switching of an inverter to control application of power to an electric motor of the vehicle.

Abstract: A control device (1), in particular for car seats (7), with at least one touch-sensitive surface (2). This is designed to generate a control signal for controlling a function, in particular a car seat function, when touched by the hand of an operator. The control device (1) has at least one recess (3) within which the touch-sensitive surface (2) is positioned.

Abstract: A seat cushion length adjusting device comprises a support, an adjusting member displaceably mounted to the support and configured for attachment to at least a portion of a seat cushion, and an actuator. The actuator is coupled to the support and the adjusting member. The actuator is configured to displace the adjusting member relative to the support. The actuator comprises a power drive, a speed reduction gearing, and a motion conversion mechanism for converting a rotational motion of an output of the speed reduction gearing into a linear displacement between the adjusting member and the support.

Abstract: A longitudinally adjustable vehicle seat comprises a seat frame, a backrest pivotally mounted on the seat frame and foldable down in the direction of a seat surface of the seat frame, a longitudinal rail guide having a guide rail pair 2 including a lower guide rail 21 and an upper guide rail 22, a seat adjuster mechanism including a releasable locking device 3 for locking and unlocking the position of the upper guide rail 22 relative to the lower guide rail 21 in a design position P between an internal full rear limit stop and a comfort full forward limit stop 62 defining a functional comfort adjustment range D, an easy-entry mechanism for displacing the vehicle seat to an extended travel full forward position C upon folding down the backrest onto the seat surface, and a pivotable over-travel and limit stop bracket 5 which is adapted to rotate to bypass the comfort full forward limit stop 62 upon activation of the easy-entry mechanism for entering an extended travel range.

Abstract: A backrest adjuster (4) is provided for a seat. The seat includes a backrest (1) that can be adjusted relative to a seat part (2) by a fitting (5) and which is arranged in a longitudinally displaceable manner. When the backrest (1) is displaced from a seating position (P1) to an entry position (P2), a gear unit (9) actuates a tension element (7) that unlatches a rail adjuster (10.1) and latches same when the backrest (1) is displaced in the opposite position. A vehicle seat is provided that includes such a backrest adjuster (4).

Abstract: The present application relates to a vehicle seat (1) comprising a seat surface (2) and at least one rest part (3.1, 3.2) at an angle to the seat surface (2). The angle between the seat surface (2) and the at least one rest part (3.1, 3.2) is movable via an adjusting device (6, 13) between a first position, in which the at least one rest part (3.1, 3.2) is substantially at right angles to the seat surface (2), and a second position, in which the seat surface (2) and the at least one rest part (3.1, 3.2) form a substantially flat surface. A second end (10.1, 10.2) of the at least one rest part (3.1, 3.2) comprises at least one pneumatic cushion (4) which is fluidically connected to a pump (7), wherein a control device is configured such that the pneumatic cushion (4) is substantially completely emptied when the at least one rest part (3.1, 3.2) moves from the first position into the second position.

Abstract: The invention relates to a motor-vehicle accessory, comprising a first part and at least one second part pivotal about an axis (a) relative to the first part in at least one bearing assembly (20a, 20b), and the bearing assembly (20a, 20b) comprises a bearing pin (14) on which a bearing sleeve (22) is coaxial to the bearing axis (a), and the bearing pin (14) forms a head (19) with an axial retaining face (30). The particularity is that of the bearing pin (14) having first coupling formation that engages in a second coupling formation of the bearing sleeve (22) and prevents relative rotation in a pivot direction (u1, u2) between the bearing sleeve (22) and the bearing pin (14).

Abstract: A sliding sleeve (6, 60) for fixing in a securing support (5, 50). The sliding sleeve (6, 60) includes a sleeve body (6.2, 60.2) with a coupling section (6.3, 60.3) with at least one flexible coupling face (6.4, 60.4) for bearing against the securing body (5, 50).

Abstract: The preset invention provides headrest reclining module that is mounted on a headrest. The headrest reclining module includes: a base supported on the headrest; a movable bracket coupled to the base to movable forward with respect to the base; a head support panel having an end coupled to the movable bracket to be tiltable forward; and a link which has both ends respectively coupled to the base and the head support panel such that at least one of the ends slides along a predetermined path set in the base or the head support panel and guides the head support panel to be tilted along the predetermined path when the movable bracket is moved.