Class / Patent application number | Description | Number of patent applications / Date published |
323314000 | With additional stage | 36 |
20080265860 | Low voltage bandgap reference source - A bandgap voltage reference circuit is described. By providing first and second bipolar devices that are operable with different current densities a base emitter voltage difference is created. This voltage difference is increased by coupling first and second cascode circuits to the first and second bipolars, the cascode circuits also being scaled relative to one another. | 10-30-2008 |
20090058392 | REFERENCE VOLTAGE CIRCUIT - A reference voltage circuit that obtains a precisely constant voltage by compensating a temperature variation of a reference voltage circuit using band gap voltage. A p-type MOS transistor (PNP) outputs a reference voltage according to a control voltage, and provides respective PNPs having diode connections with currents corresponding to the reference voltage. A temperature compensation unit adds compensation currents proportional to the second power of absolute current to currents flowing in the respective PNPs, so that both voltages generated corresponding to the currents flowing in the respective PNPs become the same in the case where the band gap unit has temperature characteristics including a peak value. The band gap unit has a differential amplifier for outputting the control voltage. In the case where the band gap unit has a bottom value, the compensation unit subtracts the above compensation currents from the currents flowing in the respective PNPs. | 03-05-2009 |
20090140714 | START-UP CIRCUIT FOR GENERATING BANDGAP REFERENCE VOLTAGE - Disclosed is a start-up circuit that can stably and rapidly start up a bandgap reference voltage generating circuit when the bandgap reference voltage generating circuit is switched from a sleep mode to an operation mode, even if a difference in electrical characteristic, such as DC offset or the like, occurs due to, e.g, a physical difference between input transistors of an operational amplifier. | 06-04-2009 |
20100213918 | Layout of a Reference Generating System - A layout of a voltage/current reference system is disclosed. A first voltage/current reference circuit (for example, a bandgap reference circuit) and a second voltage/current reference circuit are respectively laid out on either side of a substrate, such as edges or perimeter sides of the substrate. A reference voltage/current is derived by averaging respective output reference voltage/current values of the first and the second voltage/current reference circuits. Accordingly, the noise influence on the voltage/current reference system is minimized. | 08-26-2010 |
20100301832 | Curvature Compensated Bandgap Voltage Reference - Embodiments of the present invention include systems and methods for generating a curvature compensated bandgap voltage reference. In an embodiment, a curvature compensated bandgap reference voltage is achieved by injecting a temperature dependent current at different points in the bandgap reference voltage circuit. In an embodiment, the temperature dependent current is injected in the proportional to absolute temperature (PTAT) and complementary to absolute temperature (CTAT) current generation block of the bandgap circuit. Alternatively, or additionally, the temperature dependent current is injected at the output stage of the bandgap circuit. In an embodiment, the temperature dependent current is a linear piecewise continuous function of temperature. In another embodiment, the temperature dependent current has opposite dependence on temperature to that of the bandgap voltage reference before curvature compensation. | 12-02-2010 |
20100315060 | REFERENCE VOLTAGE GENERATION CIRCUIT - A basic structure of a reference voltage generation circuit is formed by a buffer amplifier ( | 12-16-2010 |
20110006750 | LOW POWER AND HIGH ACCURACY BAND GAP VOLTAGE REFERENCE CIRCUIT - A band gap voltage reference circuit includes a first band gap circuit configured to generate a first band gap voltage potential. A second band gap circuit includes a variable resistance. The second band gap circuit is configured to output a second band gap voltage potential based on a value of the variable resistance. A calibration circuit is configured to adjust the variable resistance of the second band gap circuit based on the first band gap voltage potential and the second band gap voltage potential. The first band gap circuit is shut down in response to the second band gap voltage potential being within a predetermined range of the first band gap voltage potential. | 01-13-2011 |
20110012582 | LOW-PASS FILTER, CONSTANT VOLTAGE CIRCUIT, AND SEMICONDUCTOR INTEGRATED CIRCUIT INCLUDING SAME - A low-pass filter that filters an input signal input to a filter input terminal to output a filtered output signal to a filter output terminal includes a capacitor, a first field-effect transistor, a first resistor, and a first current source. The capacitor is connected between the filter output terminal and ground. The first field-effect transistor has a gate terminal, a first conduction terminal connected to the filter input terminal, and a second conduction terminal connected to the filter output terminal. The first resistor is connected between the gate and first conduction terminals of the first transistor. The first current source is connected to the first resistor to supply a first current to the first resistor. The first resistor generates a first voltage thereacross based on the supplied first current for electrically biasing the gate terminal of the first transistor. | 01-20-2011 |
20110080154 | TEMPERATURE COMPENSATION CIRCUIT AND METHOD FOR GENERATING A VOLTAGE REFERENCE WITH A WELL-DEFINED TEMPERATURE BEHAVIOR - A temperature compensation circuit, comprises a temperature sensor circuit. The circuit comprises two or more temperature sensitive devices. In use, the devices are operated at different current densities and sense virtually the same ambient temperature. The devices provide temperature dependent signals having linear components with slopes of identical signs. The circuit further comprises one of more differential signal providing device for generating a difference of the signals generated by the temperature sensitive devices. A method for generating a voltage reference with a well-defined temperature behaviour, comprises applying different current densities to two or more temperature sensitive devices of a temperature sensor circuit; sensing virtually the same ambient temperature with the two or more temperature sensitive devices. Each temperature sensitive devices generates a slightly different temperature dependent signal; and provide at least one differential signal based on said temperature dependent signals. | 04-07-2011 |
20110133719 | Voltage reference circuit operable with a low voltage supply and method for implementing same - According to one embodiment, a voltage reference circuit operable with a low voltage supply comprises an op-amp powered by the low voltage supply and a feedback branch including a transistor driven by an output of the op-amp. The feedback branch couples the low voltage supply to ground through the transistor and at least a rectifying device situated between a reference node of the feedback branch and ground. An input of the op-amp is coupled to the reference node by a voltage divider. In one embodiment, the voltage reference circuit further comprises a reference branch coupling a second reference node to ground through at least a second rectifying device, and wherein a second input of the op-amp is coupled to the second reference node by a second voltage divider. | 06-09-2011 |
20110221419 | SEMICONDUCTOR INTEGRATED CIRCUIT DEVICE - The semiconductor integrated circuit device includes load circuits and internal voltage generators for generating internal source voltages for driving the load circuits. Each of the internal voltage generators includes a reference voltage generating circuit for generating reference voltages, and regulator circuits for generating the internal source voltages with reference to the reference voltages. The regulator circuit is formed over an SOI substrate and includes a preamplifier circuit for detecting and amplifying a difference between each of the internal source voltages and each of the reference voltages, a main amplifier circuit for amplifying the output of the preamplifier circuit and generating a control signal, and a driver circuit for generating the internal source voltage in response to the control signal. An input stage of the main amplifier circuit is configured by MOS transistors coupling the gates and bodies of the MOS transistors. | 09-15-2011 |
20110227555 | BUFFER FOR TEMPERATURE COMPENSATED CRYSTAL OSCILLATOR SIGNALS - A buffer is provided. The buffer includes a buffering stage that receives an enable signal and an input signal and that provides an output signal and a bandgap stage that is coupled to the buffering stage and that is activated and deactivated by the enable signal. In particular, the buffering stage includes a buffering substage that includes a buffering transistor that is coupled to the input stage, wherein the buffering transistor is formed on a substrate, and wherein the buffering transistor has a channel with a doping concentration that is approximately the same as the substrate. | 09-22-2011 |
20110309818 | LOW-VOLTAGE SOURCE BANDGAP REFERENCE VOLTAGE CIRCUIT AND INTEGRATED CIRCUIT - A low-voltage source bandgap reference voltage circuit is provided. In the circuit, a differential amplification module ( | 12-22-2011 |
20110309819 | REGULATOR CIRCUIT - There is provided a regulator circuit capable of increasing the capacity of the output transistor for supplying current, stably generating an internal power supply voltage and adapting to the reduction of a power supply voltage. The regulator circuit includes an output transistor which is supplied with an external power supply voltage and supplies dropped voltage to an internal circuit, a differential amplifier for outputting a gate potential applied to the gate of the output transistor, a reference voltage generating circuit for supplying a reference voltage to the differential amplifier, and a cut-off transistor for turning off the output transistor to stop supplying power to the internal circuit. The output transistor is comprised of a depression NMOS transistor whose threshold voltage is a negative voltage. The regulator circuit further includes substrate potential control means for controlling the substrate potential of the depression NMOS transistor. | 12-22-2011 |
20110316515 | OSCILLATION CIRCUIT - An oscillation circuit including a reference voltage generation circuit that adds a proportional-to-absolute-temperature (PTAT) output, which increases in proportion to an absolute temperature, to a complementary-to-absolute-temperature (CTAT) output, which decreases in proportion to an absolute temperature, to generate and output a reference voltage. The oscillation circuit generates an oscillation signal having a desired and fixed frequency. | 12-29-2011 |
20120081100 | SEMICONDUCTOR APPARATUS - A semiconductor apparatus includes a comparison voltage generation unit configured to generate a plurality of different comparison voltages, a reference voltage generation unit configured to receive a generation code from an external system, select one of the plurality of the different comparison voltages according to the generation code, and generate a reference voltage, and a reference voltage determination unit configured to receive the generation code and an expected reference voltage from the external system, check whether a level of the expected reference voltage is in a target range, and output a check result to the external system. | 04-05-2012 |
20120256613 | LOW SUPPLY REGULATOR HAVING A HIGH POWER SUPPLY REJECTION RATIO - A power supply noise rejection circuit for functional circuits, such as a voltage controlled oscillator (VCO). The power supply noise rejection circuit includes an isolation transistor connected to a voltage supply for providing an output current and voltage substantially free of noise across the full frequency range. A current source, a diode connected reference transistor with resistance means connected between its gate and drain terminals, and a dummy circuit serially connected between the voltage supply and ground generate a bias voltage that is applied to the gate of the isolation transistor. The dummy circuit mimics the DC characteristics of the functional circuit such that the output current tracks with process and temperature variations. The isolation transistor and the reference transistor can have negative threshold voltages, and the circuit can include bleed means for drawing current from the gate of the reference transistor and isolation transistor. | 10-11-2012 |
20130021016 | BANDGAP REFERENCE CIRCUIT AND METHOD OF STARTING BANDGAP REFERENCE CIRCUIT - In accordance with a bandgap circuit and a method of starting the bandgap circuit, a start signal is continuously supplied to a differential amplifier circuit to start up the differential amplifier circuit that controls a bandgap core circuit until the differential amplifier circuit has started up, and then the supply of the start signal to the differential amplifier circuit is discontinued after the differential amplifier circuit has started up. | 01-24-2013 |
20130076331 | VOLTAGE REFERENCE CIRCUIT - The voltage reference circuit includes: a first MOS transistor; a second MOS transistor including a gate terminal connected to a gate terminal of the first MOS transistor and having an absolute value of a threshold value and a K value higher than an absolute value of a threshold value and a K value of the first MOS transistor; a current mirror circuit flowing a current based on a difference between the absolute values of the threshold values of the first MOS transistor and the second MOS transistor; a third MOS transistor flowing the current; and a fourth MOS transistor having an absolute value of a threshold value and a K value higher than an absolute value of a threshold value of the third MOS transistor and flowing the current. | 03-28-2013 |
20130106394 | CONSTANT CURRENT CIRCUIT AND VOLTAGE REFERENCE CIRCUIT | 05-02-2013 |
20130241526 | REFERENCE VOLTAGE GENERATING CIRCUIT AND REFERENCE VOLTAGE SOURCE - The present invention provides a reference voltage generating circuit capable of improving a temperature dependence characteristic by a simple configuration. The reference voltage generating circuit includes: a reference voltage generating circuit element including a first diode characteristic element and a second diode characteristic element, a density of a current flowing through the second diode characteristic element being different from a density of a current flowing through the first diode characteristic element, the reference voltage generating circuit element being configured to output a reference voltage generated based on a difference between voltages respectively applied to the first diode characteristic element and the second diode characteristic element; a first adjusting circuit element configured to adjust a first-order temperature coefficient of the reference voltage; and a second adjusting circuit element configured to adjust a second-order temperature coefficient of the reference voltage. | 09-19-2013 |
20130249527 | Electronic Device and Method for Generating a Curvature Compensated Bandgap Reference Voltage - The invention relates to an electronic device with a bandgap reference generator including a first path with series connection of a first bipolar transistor, a first resistor and a second resistor, and a second path with series connection of a second bipolar transistor and a third resistor. The first and second paths are supplied current via a common node through a fourth resistor controlled by an amplifier sensing voltage drops within the first and second paths. A curvature compensation stage compensates for a variation of base emitter voltage of the bipolar transistors by drawing a compensation current from the common resistor node. | 09-26-2013 |
20130335056 | Regulator Circuit and RFID Tag Including the Same - One object of the present invention is to provide a regulator circuit with an improved noise margin. In a regulator circuit including a bias circuit generating a reference voltage on the basis of the potential difference between a first power supply terminal and a second power supply terminal, and a voltage regulator outputting a potential to an output terminal on the basis of a reference potential input from the bias circuit, a bypass capacitor is provided between a power supply terminal and a node to which a gate of a transistor included in the bias circuit is connected. | 12-19-2013 |
20140049245 | REFERENCE VOLTAGE GENERATION CIRCUIT OF SEMICONDUCTOR DEVICE - A reference voltage generation circuit includes: a reference voltage generation unit configured to generate a plurality of reference voltages having mutually different temperature characteristics, a switching unit configured to select and output one of the plurality of reference voltages in response to a control signal, a temperature detection unit configured to detect temperature change and to output a temperature detection signal, and a control unit configured to generate the control signal in response to the temperature detection to signal. | 02-20-2014 |
20140077791 | LOW POWER FAST SETTLING VOLTAGE REFERENCE CIRCUIT - Embodiments of a voltage reference circuit are described. In one embodiment, a voltage reference circuit includes a startup circuit configured to generate a startup current and to be turned off in response to a comparison between the startup current and a current threshold, an amplifier connected to the startup circuit and configured to generate an amplified current using a positive current feedback loop in response to the startup current, and a proportional to absolute temperature (PTAT) current generator configured to generate a temperature-independent reference voltage in response to the startup current and the amplified current. Other embodiments are also described. | 03-20-2014 |
20140091780 | REFERENCE VOLTAGE GENERATOR - A reference voltage generator including a reference voltage generating unit is provided. The reference voltage generating unit receives a first bias voltage current and a first mirror current and generates a reference voltage. The reference voltage generating unit includes a first metal-oxide-semiconductor (MOS) transistor, a second MOS transistor, a first impedance providing element and a second impedance providing element. The first and the second MOS transistors operate in a sub-threshold region so as to generate a first gate-source voltage and a second gate-source voltage having a negative temperature coefficient. The first impedance providing element is configured to generate a first current having a positive temperature coefficient. The second impedance providing element is configured to generate a first voltage having a negative temperature coefficient at its first terminal. The reference voltage is equal to a sum of the second gate-source voltage and the first voltage. | 04-03-2014 |
20140132241 | SMALL-CIRCUIT-SCALE REFERENCE VOLTAGE GENERATING CIRCUIT - A BGR circuit controls a switch circuit in synchronization with a clock signal from a control signal generating circuit and an inverted signal thereof, and thereby, alternately switches between a differential input terminal receiving a voltage VIM and a differential input terminal receiving a voltage VIP. An LPF circuit includes capacitive elements, a switch connected between an input node and each capacitive element, and a switch connected between an output node and each capacitive element. The LPF circuit controls ON/OFF of the switches in synchronization with a clock signal CLK, and thereby, calculates a moving average value of an output voltage of the BGR circuit in the most recent one clock cycle. | 05-15-2014 |
20140145701 | Self-Calibrating Digital Bandgap Voltage and Current Reference - A reference voltage generator is provided. In an example, the reference voltage generator includes a temperature-dependent device, a processing module configured to process a digital representations of first and second voltages derived from the temperature-dependent device and a reference voltage to determine a value, and a digital to analog converter (DAC) configured to generate a reference voltage based on the value. The first voltage is proportional to absolute temperature (PTAT) and the second voltage is complementary to absolute temperature (CTAT) and the reference voltage is substantially independent of absolute temperature in an operating temperature range of the reference voltage generator. | 05-29-2014 |
20140152290 | REFERENCE VOLTAGE CIRCUIT - A reference voltage circuit and method making same, the reference voltage circuit including: a first sub-circuit for generating first and second temperature-compensated voltages; a second sub-circuit configured to receive the first and second temperature-compensated voltages and generate first and second reference voltages based on the first and second temperature-compensated voltages, respectively; and a third sub-circuit configured to receive and change voltage levels of the first and second reference voltages, and output a third reference voltage. | 06-05-2014 |
20140312875 | STARTUP CIRCUITS WITH NATIVE TRANSISTORS - Startup circuits with native transistors. In some embodiments, a startup circuit may include a first inverter configured to receive a bandgap voltage (V | 10-23-2014 |
20140312876 | Low Power Tunable Reference Voltage Generator - A method and apparatus for generating an improved reference voltage for use, for example, in a system requiring accurate low power operation. In particular, our reference voltage generator is adapted to output VREF as a function of the voltage difference between V1 and V2. The reference voltage generator is further adapted to include our reference voltage tuner to compensate for predetermined sensitivities of the reference voltage VREF, and to adjust the absolute value of VREF. During manufacturing and system test, a driver may be used to drive a buffered or unbuffered version of VREF to off-chip test functionality. Also, a configuration memory may be used to store the trim settings during normal operation, and make such settings available to outside resources. | 10-23-2014 |
20150022178 | REFERENCE VOLTAGE GENERATING CIRCUITS - A reference voltage generating circuit. A bandgap circuit includes a current mirror circuit and an output circuit. The current mirror circuit generates a first current. The output circuit generates a reference current based on the first current. A compensation circuit is coupled to the bandgap circuit in parallel at a combination node and generates a compensation current. The compensation current is smaller than the reference current. The reference current has a first temperature coefficient and the compensation current has a second temperature coefficient that is inverse to the first temperature coefficient. The reference current and the compensation current are combined at the combination node, such that an absolute value of a temperature coefficient of the reference voltage of the combination node is smaller than an absolute value of the first temperature coefficient and an absolute value of the second temperature coefficient. | 01-22-2015 |
20150054486 | Bandgap Reference Circuit and Related Method - A device includes a bandgap reference circuit and a start-up circuit. The bandgap reference circuit includes an amplifier and a first transistor. The amplifier has an inverting input terminal, a non-inverting input terminal, and an output terminal. The first transistor has a gate electrode electrically connected to the output terminal. The start-up circuit has a first path electrically connected to the output terminal and the non-inverting input terminal, and a second path electrically connected to the output terminal and the inverting input terminal. | 02-26-2015 |
20150054487 | REFERENCE VOLTAGE SOURCE AND METHOD FOR PROVIDING A CURVATURE-COMPENSATED REFERENCE VOLTAGE - A reference voltage source comprises a bandgap voltage reference circuit having a first node and an output node, the output node being arranged for providing a reference voltage. A curvature correction circuit has an input node connected to the output node and/or to a base of a first bipolar device of the bandgap voltage reference circuit and/or to a base of a second bipolar device of the bandgap voltage reference circuit. The curvature correction circuit has an output node connected to the first node of the bandgap voltage reference circuit. The curvature correction circuit comprises a current source for providing a current having a different temperature dependency than a temperature dependency of a first current through the first bipolar device of the bandgap voltage reference circuit. | 02-26-2015 |
20160018839 | CONFIGURABLE SLOPE TEMPERATURE SENSOR - Representative implementations of devices and techniques provide a configurable slope of a voltage response of a bandgap-based temperature sensor circuit. The slope and/or a translation of the voltage response may be configured by current domain operations at a strategic node. | 01-21-2016 |
20160026204 | High-Voltage to Low-Voltage Low Dropout Regulator with Self Contained Voltage Reference - A circuit and method for providing a temperature compensated voltage comprising a voltage regulator circuit configured to provide a regulator voltage, a voltage reference circuit configured to provide a reference voltage, VREF, a comparison circuit configured to provide a control voltage VCTL, and an operational amplifier configured to provide amplification and coupling to said comparison circuit, wherein the voltage can be a high voltage greater than 1.2 V. | 01-28-2016 |