Patent application number | Description | Published |
20080308853 | Tunnel transistor having spin-dependent transfer characteristics and non-volatile memory using the same - A MISFET the channel region of which is a ferromagnetic semi-conductor has a feature that the drain current can be controlled by the gate voltage and a feature that the transfer conductance can be controlled by the relative directions of magnetization in the ferromagnetic channel region and the ferromagnetic source (or the ferromagnetic drain, or both the ferromagnetic source and ferromagnetic drain). As a result, binary information can be stored in the form of the relative magnetization directions, and the relative magnetization directions are electrically detected. If the magnetism is controlled by the electric field effect of the channel region of a ferromagnetic semiconductor, the current needed to rewrite the information can be greatly reduced. Thus, the MISFET can constitute a high-performance non-volatile memory cell suited to high-density integration. | 12-18-2008 |
20090039401 | Logic Circuit and Single-Electron Spin Transistor - A logic circuit that can reconfigure its functions in a nonvolatile manner and a single-electron transistor to be used in the logic circuits are provided. The logic circuit has a single-electron spin transistor that includes: a source; a drain; an island that is provided between the source and the drain, and has tunnel junctions between the island and the source and drain; and a gate that is capacitively coupled to the island. In this logic circuit, at least one of the source, the drain, and the island includes a ferromagnetic material having a variable magnetization direction. | 02-12-2009 |
20090236646 | Field-effect transistor with spin-dependent transmission characteristics and non-volatile memory using the same - When a gate voltage V | 09-24-2009 |
20110031545 | Spin transistor based on the spin-filter effect, and non-volatile memory using spin transistors - A spin transistor comprises a spin injector for injecting, from a first nonmagnetic electrode carriers with a spin parallel to a spin band forming the band edge of a first ferromagnetic barrier layer, to a second nonmagnetic electrode layer, as hot carriers. It also comprises a spin analyzer whereby, due to spin-splitting at the band edge of a second ferromagnetic barrier layer, the spin-polarized hot carriers are transported to a third nonmagnetic electrode when the direction of the spin of the carriers injected into the second nonmagnetic electrode is parallel to that of the spin of the spin band at the band edge of the second ferromagnetic barrier layer, whereas the hot carriers are not transported to the third nonmagnetic electrode in the case of antiparallel spin. A memory element is also provided that comprises such a spin transistor. | 02-10-2011 |
Patent application number | Description | Published |
20080247198 | CONTROL CIRCUIT AND CONTROLLING METHOD OF SWITCHING POWER SUPPLY SYSTEM - A switching power supply system has a control circuit that controls an output voltage by causing a switching device to turn ON and OFF. The control circuit includes a control pulse supplying unit that supplies a pulsed signal that_keeps the switching device turned-ON and -OFF. A protection circuit shuts down the switching power supply system upon occurrence of an abnormality. A delay circuit produces a delay signal that delays by a specified time duration the termination of a state of the pulsed signal in which the pulsed signal keeps the switching device turned-ON. The protection circuit is responsive to the pulsed signal or the delay signal to switch between an operation state and a stand-by state. | 10-09-2008 |
20080298092 | Control circuit and method for controlling switching power supply - Control circuit and method for controlling a switching power supply, which regulates its output voltage using pulse-width modulation (PWM) that switches on and off a main switch with a PWM signal (VCONT) at an adjusted ON-period ratio of the main switch. The control circuit includes an error signal amplifier circuit that compares the output voltage with a reference voltage and outputs an error signal VE based on the comparison. The control circuit also includes an ON-period adjusting circuit that starts generating a PWM signal (VCONT) in every cycle based on a pulse VPULSE, the period thereof being fixed, and adjusts the HIGH-period of the PWM signal (VCONT) based on the output voltage of the error signal VE. As a result, the control circuit widens the HIGH-period ratio range or the LOW-period ratio range of the PWM signal greatly. | 12-04-2008 |
20090096436 | DC-DC CONVERTER - A DC-DC converter includes a series circuit of a main switch and a choke coil and an output capacitor connected to one end of the series circuit and outputs a DC voltage from the one end of the series circuit. A first MOS transistor is connected in parallel to the series circuit and a second MOS transistor is connected in parallel to the output capacitor. A control circuit controls the gate voltages of the first MOS transistor and/or the second MOS transistor so that the first MOS transistor and/or the second MOS transistor outputs a changed target output voltage, whereby the output voltage is made equal to the target voltage at high speed. | 04-16-2009 |
20090146638 | Micro power converter - An object of the invention is to provide a micro power converter of a step-up and step-down type without requiring more than two semiconductor switches, without increasing the size of a semiconductor chip, and without degrading efficiency. A micro power converter comprises a micro transformer composed of a planar transformer having a structure including a conductor wound on and through a planar magnetic core, and a semiconductor chip including semiconductor switches S | 06-11-2009 |
20120299624 | VOLTAGE CONTROLLED SWITCHING ELEMENT GATE DRIVE CIRCUIT - A voltage controlled switching element gate drive circuit makes it possible to suppress an occurrence of a malfunction, while suppressing surge voltage, surge current, and switching noise, when switching in a voltage controlled switching element. A gate drive circuit that supplies a gate voltage to the gate of a voltage controlled switching element, thus driving the voltage controlled switching element, includes a high potential side switching element and low potential side switching element connected in series, first variable resistors interposed between at least the high potential side switching element and a high potential power supply or the low potential side switching element and a low potential power supply, and a control circuit that adjusts the resistance values of the first variable resistors. | 11-29-2012 |
20130342947 | ABNORMAL VOLTAGE DETECTING DEVICE - An abnormal voltage detecting device monitors abnormal decrease in monitoring voltage during a start up period of a voltage generating apparatus. The abnormal voltage detecting device comprises a level shift circuit that generates a reference voltage for a start up period by reducing, in a predetermined amount, voltage from a reference voltage for soft starting, and further comprises a three input comparator that receives a monitoring voltage, a reference voltage Vref, and the reference voltage for the start up period, and that reverses a logical output when the monitoring voltage is lower than the reference voltage Vref and the reference voltage for the start up period. An abnormality detecting signal is delivered when the logical output of the three input comparator is reversed, and operation of an output circuit is inhibited until the reference voltage for the start up period exceeds a predetermined start up determining voltage. | 12-26-2013 |
20140055171 | DRIVER CIRCUIT - A driver circuit has a detector circuit including a high side detection transistor, a resistor, and a low side detection transistor connected to a high side output transistor and a low side output transistor. A clamping circuit converts a high voltage amplitude change signal generated at a connection point of the high side detection transistor and resistor to a signal clamped to a voltage range applied on the low side. An OR circuit outputs a signal taking the logical sum of an inverted control signal and an output of a low side first stage drive circuit. A level shifter circuit outputs a level-shifted signal of the OR circuit to a high side first stage drive circuit. A second OR circuit outputs a signal wherein the logical sum of an output signal of the clamping circuit and the control signal is inverted to the low side first stage drive circuit. | 02-27-2014 |
20150092819 | SENSOR SIGNAL OUTPUT CIRCUIT AND METHOD FOR ADJUSTING IT - A sensor signal output circuit includes: a buffer amplifier which amplifies an output of a temperature sensor; an operational amplifier which amplifies an output of the buffer amplifier; an oscillator which generates a triangular wave signal; and a comparator which compares the triangular wave signal with an output of the operational amplifier to generate a PWM signal. After an offset adjusting resistor of the operational amplifier is adjusted at first temperature, the amplitude of the triangular wave signal is set to adjust the pulse width of the PWM signal at the first temperature. After that, a gain adjusting resistor of the operational amplifier is set to adjust the pulse width of the PWM signal at a second temperature. | 04-02-2015 |
20150244265 | STARTUP CIRCUIT AND POWER SUPPLY CIRCUIT - In a startup circuit, an error amplifier receives a target voltage in a startup period that is a terminal voltage with a shape of a slope generated by charging a capacitor for soft starting with a current from a constant current circuit. A detecting circuit monitors variation of the terminal voltage and blocks pulse from a logic circuit until the terminal voltage, which has been zero volts at the moment of startup, reaches a predetermined threshold value. In this period, the detecting circuit disables the function of the error amplifier. It is not until the terminal voltage VCS reaches the predetermined threshold value and the PWM pulse begins to be delivered that the error amplifier is enabled. At this moment, startup control begins based on the difference between the terminal voltage and the feedback signal. Therefore, the output voltage never rises abruptly. | 08-27-2015 |