Abstract: An induction cooker includes a first coil, a second coil, a third coil, and a controller. Responsive to determining that a heating target placed above a first coil is formed of a magnetic material, a heating target placed above a second coil is formed of a magnetic material or a composite containing a magnetic material and a non-magnetic material, and a heating target placed above a third coil is formed of a non-magnetic material, the controller stops an operation of a first inverter circuit, causes a second inverter circuit and a third inverter circuit to operate, and sets a frequency of a third high-frequency current to be higher than a frequency of a second high-frequency current.

Abstract: A heating cooking apparatus has an electricity-recovery coil configured to recover a leakage magnetic flux that leaks from a heating coil and to generate electricity, a storage battery configured to store the electricity generated by the electricity-recovery coil, a first driving circuit configured to receive electricity supplied by a commercial electricity source and to supply high-frequency current to the heating coil, a second driving circuit configured to receive electricity supplied by the storage battery and to supply high-frequency current to the heating coil, and a controller configured to operate in an induction heating mode to inductively heat a heating target placed on a heating zone by the heating coil supplied with high-frequency current from the first driving circuit, and to operate in a power supply mode to supply power to a power receiver by the heating coil supplied with high-frequency current from the second driving circuit.

Abstract: An elevator includes: a car moving in a hoistway; a load provided to the car; a first power storage unit, composed of one battery capable of charging and discharging, connected to the load, and supplying power to the load; a second power storage unit, composed of one or more batteries capable of charging and discharging, and connected to the load; a power transmission circuit and capable of transmitting power between the first power storage unit and the second power storage unit; and a control unit controlling the power transmission circuit to supply power from the second power storage unit to the first power storage unit, when it is determined that a remaining stored power amount of the battery constituting the first power storage unit is less than an amount of power required for driving the load for a certain period of time.

Abstract: A wireless power supply system for elevators includes a power transmitting device, first and second power receiving devices provided in the first and second elevator cars respectively, and a control device. The power transmitting device includes power transmitting units each having an inverter and two power transmitter coils. The first power receiving device includes first power receiving units each having a rectifier circuit and a power receiver coil that can be coupled with one of the two power transmitter coils. The second power receiving device includes second power receiving units each having a rectifier circuit and a power receiver coil that can be coupled with the other of the two power transmitter coils. The power transmitting device, or the first and second power receiving devices include switches to disconnect the inverter and the first load device as well as the inverter and the second load device.

Abstract: An elevator includes a plurality of power transmission/reception devices each including: a power transmission coil connected to a main power supply; a power reception coil for receiving power transmitted from the power transmission coil and supplying power to a load; and an inverter which is provided between the main power supply and the power transmission coil, and which converts power supplied from the main power supply, to power having a predetermined frequency, and supplies the power to the power transmission coil, wherein the plurality of power transmission/reception devices are connected in parallel between the main power supply and the load. Since the inverters are individually connected to the power transmission coils, it is possible to efficiently supply power to the load even when using some of the power transmission coils.

Abstract: A wireless power transfer system includes an induction heating cooking apparatus including a heating coil that produces a high-frequency magnetic field, a power reception device including a power reception coil that receives power from the heating coil, a first communication device provided on the power reception device to transmit a communication signal, a second communication device provided above the induction heating cooking apparatus to receive the communication signal from the first communication device, and a notification unit that indicates whether the power reception coil is located within a predetermined region that is set in advance with respect to the heating coil, when the second communication device receives the communication signal from the first communication device.

Abstract: An induction heating cooker includes a first coil, a second coil, a third coil, a first inverter circuit configured to supply a first high-frequency current to the first coil, a second inverter circuit configured to supply a second high-frequency current to the second coil, a third inverter circuit configured to supply a third high-frequency current to the third coil, a controller, and a load determining unit configured to determine a material of a heating object, wherein when a material of the heating object placed above the first coil is a magnetic material and a material of the heating object placed above the second coil includes a non-magnetic material, the controller operates the first inverter circuit and the second inverter circuit, and stops an operation of the third inverter circuit, and controls such that a frequency of the second high-frequency current is higher than a frequency of the first high-frequency current.

Abstract: In an induction cooker according to the present invention, when a heating target placed above a first coil is formed of a magnetic material, a heating target placed above a second coil is formed of a magnetic material or a composite containing a magnetic material and a non-magnetic material, and a heating target placed above a third coil is formed of a non-magnetic material, an operation of a first inverter circuit is stopped, a second inverter circuit and a third inverter circuit are caused to operate, and a frequency of a third high-frequency current is set to be higher than a frequency of a second high-frequency current.

Abstract: A heating cooker system includes a first coil configured to produce a first high-frequency magnetic field by receiving supply of a first high-frequency current, a first inverter circuit configured to supply the first high-frequency current to the first coil, a first heating element positioned in reach of the first high-frequency magnetic field produced by the first coil to be inductively heated by the first coil, a second coil configured to produce a second high-frequency magnetic field by receiving supply of a second high-frequency current, a second inverter circuit configured to supply the second high-frequency current to the second coil, a power receiving coil positioned in reach of the second high-frequency magnetic field produced by the second coil to receive electric power from the second coil, and a second heating element configured to generate heat by the electric power received by the power receiving coil.

Abstract: A wireless power transmission apparatus according to the present invention includes a coil which generates a high-frequency magnetic field upon reception of a high-frequency current, a support which supports the power receiving device within the high-frequency magnetic field, an inverter circuit which supplies the high-frequency current to the coil, and a controller which controls the driving of the inverter circuit. The controller performs a power transmission operation to transmit power to the power receiving device, if the impedance on the output side of the inverter circuit exhibits a resonant characteristic as the driving frequency of the inverter circuit is changed.

Abstract: A wireless power transfer system includes an induction heating cooking apparatus including a heating coil that produces a high-frequency magnetic field, a power reception device including a power reception coil that receives power from the heating coil, a first communication device provided on the power reception device to transmit a communication signal, a second communication device provided above the induction heating cooking apparatus to receive the communication signal from the first communication device, and a notification unit that indicates whether the power reception coil is located within a predetermined region that is set in advance with respect to the heating coil, when the second communication device receives the communication signal from the first communication device.

Abstract: An induction heating cooker includes a first coil, a second coil, a third coil, a first inverter circuit configured to supply a first high-frequency current to the first coil, a second inverter circuit configured to supply a second high-frequency current to the second coil, a third inverter circuit configured to supply a third high-frequency current to the third coil, a controller, and a load determining unit configured to determine a material of a heating object, wherein when a material of the heating object placed above the first coil is a magnetic material and a material of the heating object placed above the second coil includes a non-magnetic material, the controller operates the first inverter circuit and the second inverter circuit, and stops an operation of the third inverter circuit, and controls such that a frequency of the second high-frequency current is higher than a frequency of the first high-frequency current.

Abstract: A wireless power transmission apparatus according to the present invention includes a coil which generates a high-frequency magnetic field upon reception of a high-frequency current, a support which supports the power receiving device within the high-frequency magnetic field, an inverter circuit which supplies the high-frequency current to the coil, and a controller which controls the driving of the inverter circuit. The controller performs a power transmission operation to transmit power to the power receiving device, if the impedance on the output side of the inverter circuit exhibits a resonant characteristic as the driving frequency of the inverter circuit is changed.

Abstract: A heating cooker system includes a first coil configured to produce a first high-frequency magnetic field by receiving supply of a first high-frequency current, a first inverter circuit configured to supply the first high-frequency current to the first coil, a first heating element positioned in reach of the first high-frequency magnetic field produced by the first coil to be inductively heated by the first coil, a second coil configured to produce a second high-frequency magnetic field by receiving supply of a second high-frequency current, a second inverter circuit configured to supply the second high-frequency current to the second coil, a power receiving coil positioned in reach of the second high-frequency magnetic field produced by the second coil to receive electric power from the second coil, and a second heating element configured to generate heat by the electric power received by the power receiving coil.

Abstract: A highly efficient rectifier can readily replace a two-terminal diode. Its conduction losses are reduced from that of the two-terminal diode. Connected between the source and drain of a MOSFET including a parasitic diode are a micro-power converter section for boosting a conduction voltage Vds between the source and drain to a predetermined voltage, and a self-drive control section that operates based on a voltage output from the micro-power converter section. When the source and drain are conductive with each other, the micro-power converter section generates, from the conduction voltage Vds, a power source voltage for the self-drive control section, and the self-drive control section (4) continues drive control of the MOSFET.

Abstract: Provided is a highly efficient rectifier which can readily replace a two-terminal diode and whose conduction loss is reduced from that of the two-terminal diode. Connected between the source and drain of a MOSFET (2) including a parasitic diode (2a) are: a micro-power converter section (3) for boosting a conduction voltage Vds between the source and drain to a predetermined voltage; and a self-drive control section (4) that operates based on a voltage outputted from the micro-power converter section (3). When the source and drain are conductive with each other, the micro-power converter section (3) generates, from the conduction voltage Vds, a power source voltage for the self-drive control section (4), and the self-drive control section (4) continues drive control of the MOSFET (2).

Abstract: A data processing apparatus (100) varying width data sizes for a data storing device is disclosed. A data processing apparatus (100) may include a data storage circuit (201), a read/write switch circuit (103), an address generating circuit (104), and a selection signal generating circuit (202). A data storage circuit (201) may include at least one memory array (112), a selecting circuit (211 and 212), a read circuit (214) and a write circuit (213). Selecting circuit (211 and 212) may select a plurality of data bits from a memory array (112) in a first mode and may select N times the plurality of data bits from a memory array (112) in a second mode. In this way, a data storage circuit (201) may be shared by, for example, processors having different data widths.