An ECU of a vehicle performs processing including transmitting a power feeding request during traveling along a power feeding lane, transmitting a vehicle ID when the vehicle is determined as having deviated from the power feeding lane, and transmitting the vehicle ID again when the vehicle is determined as having returned to the power feeding lane. A management server performs processing including starting power feeding when it receives the power feeding request, storing the received vehicle ID, stopping power feeding, and resuming power feeding when it receives again the vehicle ID and when the received vehicle ID matches with the stored vehicle ID.

An ECU of a vehicle performs processing including transmitting a power feeding request during traveling along a power feeding lane, transmitting a vehicle ID when the vehicle is determined as having deviated from the power feeding lane, and transmitting the vehicle ID again when the vehicle is determined as having returned to the power feeding lane. A management server performs processing including starting power feeding when it receives the power feeding request, storing the received vehicle ID, stopping power feeding, and resuming power feeding when it receives again the vehicle ID and when the received vehicle ID matches with the stored vehicle ID.

Disclosed is an electronic device including a plurality of sensing coils for sensing an external device; a power transmitting coil for transmitting power to the external device; and a processor configured to: sequentially apply, to the power transmitting coil, powers having magnitudes respectively set to correspond to the plurality of sensing coils, and during a period in which power corresponding to each sensing coil of the plurality of sensing coils among the powers is applied, identify induction voltages respectively induced in the plurality of sensing coils, and sense the external device located on a wireless power transmitting device, on the basis of the identified induction voltages.

Disclosed is an electronic device including a plurality of sensing coils for sensing an external device; a power transmitting coil for transmitting power to the external device; and a processor configured to: sequentially apply, to the power transmitting coil, powers having magnitudes respectively set to correspond to the plurality of sensing coils, and during a period in which power corresponding to each sensing coil of the plurality of sensing coils among the powers is applied, identify induction voltages respectively induced in the plurality of sensing coils, and sense the external device located on a wireless power transmitting device, on the basis of the identified induction voltages.

A power transmitter for wireless power transfer includes a verification load, a control and communications unit, an inverter circuit, a coil, and a shielding. The control and communications unit is configured to provide power control signals to control a power level of a power signal configured for transmission to a power receiver, provide a power request to an external power supply, determine if a power signal at the verification load is compliant with the power request, and, if the power signal at the verification load is compliant with the power request, continue to operate for wireless power transmission. The coil is configured to transmit the power signal to a power receiver. The shielding comprises a ferrite core.

A pinless power plug for receiving wireless power from a pinless power jack is disclosed. The pinless power plug may comprise at least one secondary coil for inductively coupling with a primary coil. The primary coil may be associated with the pinless power jack. The primary coil may be shielded behind an insulating layer. The pinless power plug may comprise an annular magnetic anchor arranged around a perimeter of the at least one secondary coil concentric and non-overlapping with the at least one secondary coil. The annular magnetic anchor may be configured to magnetically couple with an annular magnetic snag in the pinless power jack. The pinless power plug may comprise at least one magnet spaced away from and outside of the annular magnetic anchor. The at least one magnet may be configured to magnetically couple with a magnet in the pinless power jack at a particular orientation or angle.

A pinless power plug for receiving wireless power from a pinless power jack is disclosed. The pinless power plug may comprise at least one secondary coil for inductively coupling with a primary coil. The primary coil may be associated with the pinless power jack. The primary coil may be shielded behind an insulating layer. The pinless power plug may comprise an annular magnetic anchor arranged around a perimeter of the at least one secondary coil concentric and non-overlapping with the at least one secondary coil. The annular magnetic anchor may be configured to magnetically couple with an annular magnetic snag in the pinless power jack. The pinless power plug may comprise at least one magnet spaced away from and outside of the annular magnetic anchor. The at least one magnet may be configured to magnetically couple with a magnet in the pinless power jack at a particular orientation or angle.

A device includes a signaling means and a motion sensor, and logic for activating or controlling the signaling means in response to a sensed motion according to an embedded logic. The device may be used as a toy, and may be shaped like a play ball or as a handheld unit. It may be powered from a battery, either chargeable from an AC power source directly or contactless by using induction or by converting electrical energy from harvested kinetic energy. The embedded logic may activate or control the signaling means, predictably or randomly, in response to sensed acceleration magnitude or direction, such as sensing the crossing of a preset threshold or sensing the peak value. The visual means may be a numeric display for displaying a value associated with the count of the number of times the threshold has been exceeded or the peak magnitude of the acceleration sensed.

A device includes a signaling means and a motion sensor, and logic for activating or controlling the signaling means in response to a sensed motion according to an embedded logic. The device may be used as a toy, and may be shaped like a play ball or as a handheld unit. It may be powered from a battery, either chargeable from an AC power source directly or contactless by using induction or by converting electrical energy from harvested kinetic energy. The embedded logic may activate or control the signaling means, predictably or randomly, in response to sensed acceleration magnitude or direction, such as sensing the crossing of a preset threshold or sensing the peak value. The visual means may be a numeric display for displaying a value associated with the count of the number of times the threshold has been exceeded or the peak magnitude of the acceleration sensed.

A wireless power transmitter configured to transfer power to a wireless power receiver including primary coils comprising first and second bottom coils placed adjacent to each other in a line and each consisting of a single layer of 11 turns and a top coil stacked on the first and second bottom coils and consisting of a single layer of 12 turns; a shielding; and a full-bridge inverter, wherein the first and second bottom coils and the top coil have a substantially rectangular frame structure with a through hole in the center, wherein the top coil lies on a plane surface in the middle between the first and second bottom coils, wherein a distance from the center of the first and second bottom coils to the center of the top coil is set to a range of 21 mm to 25 mm, wherein the first and second bottom coils have a height of 48 mm to 50 mm and a width of 43 mm to 45 mm, and the through hole in the first and second bottom coils has a height of 25 mm to 27 mm and a width of 21 mm to 23 mm, wherein the top coil has a height of 45 mm to 47 mm and a width of 48.5 mm to 50.5 mm, and the through hole in the top coil has a height of 20 mm to 22 mm and a width of 24.5 mm to 26.5 mm, wherein the first and second bottom coils and the top coil have a thickness of 0.9 mm to 1.3 mm, wherein an amount of power which is transferred is controlled based on an input voltage of the full-bridge inverter, wherein the input voltage has a range of 1 V to 18 V, wherein an operating frequency to control the amount of the power is within a range of 140 kHz to 150 kHz, wherein an assembly of the primary coils and the shielding has a self-inductance value of 11.3 .Math.H, wherein the full-bridge invertor drives a series capacitance, and wherein a value of the series capacitance is 139 nF.