Abstract: There is provided a non-contact power transmission apparatus which can supply stable power from a power transmitting side to a power receiving side even if a load is changed. The power transmission apparatus transmits power from a power transmitting device to a power receiving device in a non-contact manner. The power transmitting device includes a series circuit which is connected to a direct-current power source, and includes a parallel resonance circuit including a first capacitor and a first inductor, and a switch element, a drive source to drive on or off the switch element, and a first series resonance circuit connected to a connection point between the parallel resonance circuit and the switch element and including a second inductor, a second capacitor and a power transmission coil.

Abstract: According to one embodiment, power conversion apparatus includes a converter and a controller. A converter receives an AC power as an input, and outputs a DC voltage by turning on and off a first switching element which operates when the AC power is positive, and a second switching element which operates when the AC power is negative. A controller receives an AC input voltage and alternating input current to the converter, and a DC output voltage from the converter, as an input, determines a pulse width of a first pulse signal to turn on the first switching element and a pulse width of a second pulse signal to turn on the second switching element, and outputs the first pulse signal and second pulse signal to the converter.

Abstract: A power conversion apparatus determines a peak value of circuit current in each pulse cycle and a lower limit value lower than the peak value, from a corrected output voltage value obtained by subtracting a predetermined reference voltage from an output voltage detected, and an input voltage detected. The pulse signal output unit outputs a pulse signal to the first switch when the polarity of input voltage is positive, and outputs a pulse signal to the second switch when the polarity of input voltage is negative. A pulse signal is turned on in response to start of a pulse cycle, and is kept on until a circuit current detected reaches a peak value. A pulse signal turns off when a circuit current reaches a peak value, and turns on again when a circuit current decreases to a lower limit value.

Abstract: According to one embodiment, a power conversion apparatus includes a first LC circuit, a first switch, a second switch, a smoothing capacitor, a second LC circuit and a controller. The first switch is connected to the AC power supply through the first LC circuit. The second switch is connected in series to the first switch. The smoothing capacitor is connected in parallel to a series circuit of the first switch and the second switch. The second LC circuit is connected between a connection point between the first switch and the second switch and a load. The controller outputs a first pulse signal to the first switch when a voltage polarity of the AC power supply is positive, and outputs a second pulse signal to the second switch when the voltage polarity is negative.

Abstract: According to one embodiment, a controller determines the polarity of the input voltage detected by an input voltage detector. Then, when the polarity of the input voltage is positive, the first switch is subject to pulse driving, and when the polarity of the input voltage is negative, the second switch is subject to pulse driving, where the pulse driving is carried out at an on/off timing determined on the basis of the respective detection outputs of an input voltage detector, an input current detector, an output voltage detector, and an output current detector.

Abstract: According to one embodiment, a power conversion apparatus determines a peak value of circuit current in each pulse cycle, from a corrected output voltage value by subtracting a predetermined reference voltage from an output voltage detected by the output voltage detector, and an input voltage detected by the input voltage detector. The pulse signal output unit outputs a pulse signal to the first switch when the polarity of input voltage is positive, and outputs a pulse signal to the second switch when the polarity of input voltage is negative. A pulse signal turns on in synchronization with a clock signal input from the oscillator, and is kept on until the circuit current detected by the circuit current detector reaches the peak value. A pulse signal turns off when the circuit current reaches the peak value, and turns on again in synchronization with the next clock signal.

Abstract: According to one embodiment, a power conversion apparatus includes a first LC circuit, a first switch, a second switch, a smoothing capacitor, a second LC circuit and a controller. The first switch is connected to the AC power supply through the first LC circuit. The second switch is connected in series to the first switch. The smoothing capacitor is connected in parallel to a series circuit of the first switch and the second switch. The second LC circuit is connected between a connection point between the first switch and the second switch and a load. The controller outputs a first pulse signal to the first switch when a voltage polarity of the AC power supply is positive, and outputs a second pulse signal to the second switch when the voltage polarity is negative.

Abstract: According to one embodiment, power conversion apparatus includes a converter and a controller. A converter receives an AC power as an input, and outputs a DC voltage by turning on and off a first switching element which operates when the AC power is positive, and a second switching element which operates when the AC power is negative. A controller receives an AC input voltage and alternating input current to the converter, and a DC output voltage from the converter, as an input, determines a pulse width of a first pulse signal to turn on the first switching element and a pulse width of a second pulse signal to turn on the second switching element, and outputs the first pulse signal and second pulse signal to the converter.

Abstract: According to one embodiment, a power conversion apparatus determines a peak value of circuit current in each pulse cycle, from a corrected output voltage value by subtracting a predetermined reference voltage from an output voltage detected by the output voltage detector, and an input voltage detected by the input voltage detector. The pulse signal output unit outputs a pulse signal to the first switch when the polarity of input voltage is positive, and outputs a pulse signal to the second switch when the polarity of input voltage is negative. A pulse signal turns on in synchronization with a clock signal input from the oscillator, and is kept on until the circuit current detected by the circuit current detector reaches the peak value. A pulse signal turns off when the circuit current reaches the peak value, and turns on again in synchronization with the next clock signal.

Abstract: According to one embodiment, a power conversion apparatus determines a peak value of circuit current in each pulse cycle and a lower limit value lower than the peak value, from a corrected output voltage value obtained by subtracting a predetermined reference voltage from an output voltage detected, and an input voltage detected. The pulse signal output unit outputs a pulse signal to the first switch when the polarity of input voltage is positive, and outputs a pulse signal to the second switch when the polarity of input voltage is negative. A pulse signal is turned on in response to start of a pulse cycle, and is kept on until a circuit current detected reaches a peak value. A pulse signal turns off when a circuit current reaches a peak value, and turns on again when a circuit current decreases to a lower limit value.

Abstract: According to one embodiment a power conversion apparatus includes a first switch, a second switch, and a pulse generator. The first switch is connected at both ends of an AC power supply through an inductor and capacitor connected in series. The second switch is connected at both ends of the first switch through a smoothing capacitor connected in series. The pulse generator generates a first pulse signal for driving the first switch at a frequency higher than a cycle of the AC voltage, and supplies it to the first switch, when the polarity of the voltage of the AC power supply is positive. The pulse generator generates a second pulse signal for driving the second switch at a frequency higher than a cycle of the AC voltage, and supplies it to the second switch, when the polarity of the voltage of the AC power supply is negative.

Abstract: According to an electric network simulating method, element cells representing electric functions of a plurality of circuit elements and connection pipes representing wiring lines for connecting the circuit elements are defined. A current is defined as the number of particles moving through the connection pipe per unit time, and a voltage is defined as the number of particles present in the connection pipe. A rule for expressing the electric function of each circuit element in accordance the state of the connection pipe is set beforehand in units of element cells. The particles are transferred between the element cell and the connection pipe in accordance with the rule. The state of the electric network is simulated in accordance with the number of particles passing through the connection pipe per unit time and the number of particles present in the connection pipe.

Abstract: A server system transmits display information that allows selecting a circuit module, display information that allows designating a parameter of the circuit module, and display information that allows inputting circuit specifications to a client terminal through a network. The server system acquires circuit module selection information, designated parameter information, and circuit specification information from the client terminal, simulates the electrical characteristics of the circuit, and transmits the determination result to the client terminal. With this arrangement, a circuit that meets the client's specifications is designed.

Abstract: A lighting apparatus includes a full-wave rectifier circuit for rectifying an AC voltage from a commercial power source, a smoothing condenser connected is series with an inductor and a diode between output terminals of the full-wave rectifier circuit, a light source unit containing a series circuit of light emitting diodes and connected in parallel with the smoothing condenser, a MOSFET connected in series with the inductor between the output terminals of the full-wave rectifier circuit, and a control circuit for performing switching control of the MOSFET. In particular, the control circuit is constituted such that a voltage across the smoothing condenser is set higher than a peak of an input voltage input to the smoothing condenser through the diode and equal to a total sum of forward voltage drops of the light emitting diodes at a time of igniting the light source, under the switching control.

Abstract: A discharge lamp lighting apparatus comprises a transformer for stepping up an AC power source voltage from an AC power source to produce a high voltage as an output voltage required for lighting a discharge lamp. Particularly, the lighting apparatus further comprises a diode for rectifying the output voltage of the transformer to be supplied to the discharge lamp. The amount of current supply from the AC power source is determined to obtain an output impedance capable of limiting the current which is to flow through the discharge lamp after the start of discharging to maintain the voltage across the discharge lamp at a level required for continuing the discharge.

Abstract: A thermal printer includes a thermal head having n heating elements arranged at a preset pitch D1 in a line, a memory including a first memory area storing a plurality of high speed printing character data each column of which is composed of n-bit data and a second memory area storing a plurality of high resolution printing character data each column of which is composed of m-bit data (m>n); and printing control circuit which reads out the m-bit data of each column designated by the input character code data from the second memory area in accordance with the high resolution printing mode designation data, and drives the thermal head in accordance with the m-bit data read out.

Abstract: Disclosed is a control device having a detector for detecting the degree of superheating or supercooling of refrigerating or air-conditioning units. The detector includes a pressure responsive chamber for guiding the pressure of a coolant and a diaphragm disposed therein. The diaphragm is connected with a temperature-responsive cylinder for sensing the temperature of the coolant and a connecting rod. The connecting rod moves corresponding to the pressure and temperature of the coolant, and the position thereof is sensed by a position sensor means.