| Class / Patent application number | Description | Number of patent applications / Date published |
|---|
| 327065000 | Differential input | 48 |
| 20080218218 | POTENTIAL COMPARATOR AND TEST APPARATUS - The potential comparator includes input wires 3 and 4 that input a differential signal output from a test object | 09-11-2008 |
| 20080238491 | Interface circuit - An interface circuit includes a reference voltage generation circuit to generate a reference voltage, a differential voltage signal generation circuit to convert send data input in sending data into a pair of differential voltage signals and output the pair of differential voltage signals based on the reference voltage generated by the reference voltage generation circuit, a receiver to convert a pair of differential voltage signals input in receiving data and output received data, and a receiver test circuit to perform a sensitivity test of the receiver, the receiver test circuit having a resistance circuit to generate a pair of differential voltage signals having a potential difference being necessary for the sensitivity test of the receiver. | 10-02-2008 |
| 20090021284 | Low voltage differential signal receiver - The invention discloses a low voltage differential signal (LVDS) receiver, which is realized in an integrated circuit. The LVDS receiver includes: an input stage circuit receiving a full-range common-mode voltage and converting it into a current signal; a current source circuit coupled to the input stage circuit to provide a current source; and a current mirror circuit coupled the input stage circuit and the current source circuit to provide several bias voltage signals for the current source circuit and output a voltage signal to a buffer. | 01-22-2009 |
| 20090033370 | COMPARATOR WITH LOW SUPPLIES CURRENT SPIKE AND INPUT OFFSET CANCELLATION - A current control circuit is coupled in parallel with the current paths of a differential comparator circuit to ensure that a substantially constant current is drawn from a current source during all operating phases of a comparator. The current control circuit is biased by a reference voltage, which is also used to bias a V− input terminal of the differential comparator circuit. The reference voltage is stored by a sample capacitor, which is charged by applying the reference voltage to a V+ input terminal of the differential comparator circuit while coupling an output terminal of the differential comparator circuit to the sample capacitor in a unity feedback configuration. | 02-05-2009 |
| 20090033371 | AMPLIFIER CIRCUIT FOR DOUBLE SAMPLED ARCHITECTURES - A double sampled switched capacitor architecture as described herein includes an amplifier having two separate inputs corresponding to two separate amplifier sections. The amplifier uses a first differential transistor pair for the first amplifier section, a second differential transistor pair for the second amplifier section, a first tail current bias arrangement for the first differential transistor pair, and a second tail current bias arrangement for the second differential transistor pair. The tail current bias arrangements are driven by a bias switching architecture that alternately activates one tail current bias arrangement while at least partially deactivating the other tail current bias arrangement. The amplifier and bias switching architecture cooperate to eliminate gain error that would otherwise be caused by a common parasitic capacitance shared by a single amplifier section. | 02-05-2009 |
| 20090033372 | SIMULTANEOUS LVDS I/O SIGNALING METHOD AND APPARATUS - First and second devices may simultaneously communicate bidirectionally with each other using only a single pair of LVDS signal paths. Each device includes an input circuit and a differential output driver connected to the single pair of LVDS signal paths. An input to the input circuit is also connected to the input of the driver. The input circuit may also receive an offset voltage. In response to its inputs, the input circuit in each device can use comparators, gates and a multiplexer to determine the logic state being transmitted over the pair of LVDS signal paths from the other device. This advantageously reduces the number of required interconnects between the first and second devices by one half. | 02-05-2009 |
| 20090058471 | Rail-to-rail comparator with hysteresis - A comparator, comprising at least one current stage for providing a first current proportional to a difference between first and second comparator inputs, the first current being provided to an amplifier input; an amplifier for amplifying a current provided to the amplifier input and providing a comparator output; apparatus for introducing hysteresis, comprising at least one of a current source and a current sink, the current source being arranged to selectively source a source current to the amplifier input such that the comparator output changes from a first state to a second state when a difference between the first and second inputs rises above a first value, and the current sink being arranged to selectively sink a sink current from the amplifier input such that the comparator output changes from the second state to the first state when the difference between the first and second inputs falls below a second value; and apparatus for controlling at least one of the source current and the sink current to be proportional to a bias current of the current stage. | 03-05-2009 |
| 20090091354 | Semiconductor circuit - In a conventional circuit to buffer differential clock signals at plural stages, the deteriorations of duty ratios caused by the variations of transistors constituting the circuit have not been compensated. Further, when it is attempted to increase the effect of compensating the duty ratios, the size of the circuit increases and the consumed electric current also increases accordingly. A semiconductor circuit according to the present invention includes: a differential input section to receive input differential signals; differential signal output terminals to output output differential signals in accordance with the voltages input into the differential input section; a low-pass filter to extract the DC components of signals output from the differential signal output terminals; and a load resistor section connected to the differential input section, wherein resistance values are determined on the basis of the DC components of the signals extracted with the low-pass filter. | 04-09-2009 |
| 20090128193 | FAST, LOW OFFSET GROUND SENSING COMPARATOR - A fast, accurate, low offset comparator may be configured with multiple gain stages. A low gain, low input impedance, and fully differential common-gate amplifier may be configured as a first stage in the multi-stage comparator, providing a wide bandwidth for small power consumption. The inputs of the comparator may comprise a pair of differential inputs at respective source terminals of gate-coupled metal oxide semiconductor (MOS) devices configured in the input stage of the common-gate amplifier. A pair of differential outputs of the first stage may be coupled to a pair of differential inputs of a second stage, which may be a differential input current-mirror amplifier that may perform differential to single-ended conversion. The single-ended output of the second stage may serve as the input into a latch, which may be a bistable set-reset (SR) latch configured to increase the gain and response time while protecting against multiple switching, with the single-ended output of the latch configured as the output of the comparator. | 05-21-2009 |
| 20100141302 | SIGNAL CONVERTING CIRCUIT - A signal conversion circuit | 06-10-2010 |
| 20100182051 | INPUT CIRCUIT OF SEMICONDUCTOR INTEGRATED CIRCUIT - An input circuit is disclosed. The input circuit can include a cross voltage generating block that can be configured to perform charge-sharing on a pair of input signals whose phases are opposite to each other and generate a cross voltage, and an input buffer block that can be configured to buffer the pair of input signals at a voltage level corresponding to a voltage level of the cross voltage and generate an output signal. | 07-22-2010 |
| 20100213983 | AMPLIFIERS WITH INPUT OFFSET TRIM AND METHODS - Amplifiers with power-on trim and methods using an amplifier system having an amplifier system input and an amplifier system output, an amplifier, a comparator, a successive approximation register having an input coupled to an output of the comparator, a first switch for switching an input of the amplifier from the amplifier system input to shorting the amplifier input, a second switch for switching an output of the amplifier from the amplifier system output to an input of the comparator, an output of the successive approximation register being coupled to an N bit digital to analog (D/A) converter, the D/A converter being a non-binary converter using a radix of less than 2 for at least the most significant bits, and an output of the D/A converter being coupled to the amplifier to control the input offset of the amplifier. Novel embodiments for the amplifier, comparator and D/A converter are disclosed. | 08-26-2010 |
| 20100237906 | RECEIVING CIRCUIT - A receiving circuit includes an impedance compensating circuit, a first input terminal and a second input terminal coupled to a first signal line and a second signal line, a first signal and a second signal corresponding to differential signals being transmitted at the first input terminal and the second input terminal, respectively, a signal input circuit, coupled to the first input terminal and the second input terminal, which receives the first signal and the second signal are input, and a differential-signal detector that detects whether or not the differential signals are supplied to the first input terminal and the second input terminal. | 09-23-2010 |
| 20100289531 | COMPARATOR WITH HYSTERESIS - Techniques for providing a comparator incorporating amplitude hysteresis. In an exemplary embodiment, a current offset stage is coupled to a comparator having a folded cascode architecture. The current offset stage offsets the current generated from an input stage to delay switching of the comparator output to implement amplitude hysteresis. In an exemplary embodiment, rail-to-rail input voltages may be accommodated by providing dual NMOS and PMOS input stages. In another exemplary embodiment, the amplitude hysteresis may be controlled by an adjustable threshold voltage. In yet another exemplary embodiment, a constant transconductance g | 11-18-2010 |
| 20100327914 | Accurate Hysteretic Comparator and Method - A hysteretic comparator is proposed for comparing input signals and producing an output signal VOT with a hysteresis window V | 12-30-2010 |
| 20110001516 | CIRCUIT, APPARATUS, AND METHOD FOR SIGNAL TRANSFER - A signal transfer circuit according to the present invention includes a differential signal generation unit that generates a differential signal according to a voltage difference between two input signals, a voltage difference detection unit that detects a voltage difference between the two input signals input to the differential signal generation unit, and a signal output unit that outputs a signal including a predetermined value if the voltage difference is not detected by the voltage difference detection unit, and outputs the differential signal generated by the differential signal generation unit if the voltage difference is detected by the voltage detection unit. | 01-06-2011 |
| 20110025379 | LATCHED COMPARATOR AND METHODS THEREFOR - A compare cycle of a comparator includes a precharge phase and a compare phase. During the precharge phase, a node of the comparator is precharged to a defined voltage. In addition, during the precharge phase an input transistor of the comparator is decoupled from the node. During the compare phase, an input voltage is coupled to the node via the input transistor. The input transistor is maintained in saturation during both the precharge phase and the compare phase, reducing switching noise. | 02-03-2011 |
| 20110057686 | HYSTERESIS COMPARATOR CIRCUIT AND SEMICONDUCTOR DEVICE INCORPORATING SAME - A hysteresis comparator circuit that compares first and second input signals to output a hysteresis output signal includes a constant current source, a first comparator, a second comparator, and an output circuit. The constant current source includes a load resistor to generate a given constant current. The first comparator is controlled by the constant current supplied from the constant current source to compare the first and second input signals to output a first comparison result. The second comparator is controlled by the constant current supplied from the constant current source to compare the first and second input signals to output a second comparison result. The output circuit has a pair of inputs thereof connected to the first and second comparators, respectively, which inverts an output thereof in response to each of the first and second comparison results to generate the hysteresis output signal. | 03-10-2011 |
| 20110089977 | Systems and Methods of Low Offset Switched Capacitor Comparators - The disclosed systems and methods of low offset switched capacitor comparator reduce settling errors. The system operates in two major phases. During a first phase, the input voltage is sampled on the input capacitors and a differential amplifier is configured in a unity gain configuration to sample the amplifier offset. During the second phase, the input voltage difference is amplified at the output of the comparator. The amplifier transient sampling error is reduced by shorting the outputs of the differential amplifier for a shorting period at the start of the second phase. A clocked comparator at the output of the differential amplifier provides a fast comparison using internal positive feedback. The differential amplifier should have developed sufficient differential output voltage to overcome the offset of the clocked comparator. | 04-21-2011 |
| 20110109348 | DYNAMIC COMPARATOR WITH BACKGROUND OFFSET CALIBRATION - A dynamic comparator with background offset calibration is provided. The dynamic comparator includes at least one input differential pair, a first back-to-back inverter, a second back-to-back inverter, and an integrator. The input differential pair includes two current branches, wherein one of the current branches has an input referred offset. The first back-to-back inverter determines which one of the two current branches has the input referred offset in response to a first clock signal and generates two control signals accordingly. The integrator generates two calibration voltages for the input differential pair in response to the two control signals, so as to calibrate the input referred offset. The second back-to-back inverter determines a difference between two input signals received by the input differential pair after the input referred offset is calibrated in response to a second clock signal and outputs two comparison signals accordingly. | 05-12-2011 |
| 20110140742 | TRANSMISSION DEVICE HAVING EMPHASIS FUNCTION - A transmission driver including a main driving stage and a sub-driving stage is provided. The main driving stage has a main current source, and is adapted for receiving a first differential input data stream and outputting a differential output data stream by using the main current source. The sub-driving stage has two sub-current sources, and is adapted for receiving a second differential input data stream and counteracting/reducing the attenuation or distortion of the differential output data stream caused by a long transmission distance by using the sub-current sources. There is a delay of a specific bit length between the first and the second differential input data streams. | 06-16-2011 |
| 20110181321 | SEMICONDUCTOR INTEGRATED CIRCUIT - A semiconductor integrated circuit has a squelch circuit which has a first noninverting input terminal and a first inverting input terminal, which compares differential amplitude between a signal which is input to the first noninverting input terminal and a signal which is input to the first inverting input terminal with a preset threshold, and which outputs a signal depending upon a result of the comparison. The semiconductor integrated circuit has a first switch circuit between a first reception terminal and the first noninverting input terminal. The semiconductor integrated circuit has a second switch circuit between a second reception terminal and the first inverting input terminal. The semiconductor integrated circuit has a third switch circuit between the first reception terminal and the first inverting input terminal. The semiconductor integrated circuit has a fourth switch circuit between the second reception terminal and the first noninverting input terminal. | 07-28-2011 |
| 20110221477 | HIGH-SPEED DIFFERENTIAL COMPARATOR CIRCUITRY WITH ACCURATELY ADJUSTABLE THRESHOLD - A high-speed differential comparator circuit is provided with an accurately adjustable threshold voltage. Differential reference voltage signals are provided to control the threshold voltage of the comparator. The common mode voltage of the reference signals preferably tracks the common mode voltage of the differential high-speed serial data signal being processed by the comparator circuit. | 09-15-2011 |
| 20110316587 | Bistable CML Circuit - A common-source circuit including two branches in parallel between a terminal of application of a voltage and a current source, each branch comprising: a series association of a resistor and a transistor, having their junction point defining an output terminal of the branch; a first switch connecting an input terminal of the branch to a control terminal of the transistor; and a controllable stage for amplifying data representing the level present on the output terminal of the opposite branch. | 12-29-2011 |
| 20120062279 | Adaptively Biased Comparator - The invention relates to an electronic device which comprises a comparator coupled to monitor a first supply voltage level at a first supply voltage node. The comparator comprises a differential input transistor stage having one input coupled to the first supply voltage node and the other input coupled to receive a reference voltage level, a first current source configured to supply a current of a first magnitude, a second current source configured to supply a current of a second magnitude, and a capacitor. The first magnitude is greater than the second magnitude and the first current source is coupled with one side to the differential input stage for supplying the differential input stage and with the other side to a first node. The second current source is coupled with one side to the first node and with the other side to a second supply voltage node having a second supply voltage level and the capacitor is coupled with one side to the first node and with the other side to the first supply voltage node. | 03-15-2012 |
| 20120098572 | LATCHED COMPARATOR HAVING ISOLATION INDUCTORS - Traditionally, latched comparators have suffered from performance problems related to exposure of the latch to load capacitances. Even attempts to isolate the latch from the load capacitances by way of resistors has resulted in performance problems (namely, voltage swing degradation). Here, however, a latched comparator is provided that employs inductors to generally provide isolation from load capacitances, which generally improves performance. Moreover, the latch has been modified to accommodate the inductors during a track period (namely, provision of grounding paths). | 04-26-2012 |
| 20120112794 | DIFFERENTIAL DRIVER WITH CALIBRATION CIRCUIT AND RELATED CALIBRATION METHOD - A calibration circuit for calibrating a differential driver with a differential output port including a first output node and a second output node includes: a comparing circuit arranged to receive a first output voltage corresponding to the first output node and a second output voltage corresponding to the second output node, and generate a comparison result according to the first output voltage, the second output voltage, and a predetermined voltage; and a controlling circuit coupled to the comparing circuit, a first resistive element and a second resistive element. The controlling circuit is arranged to adjust the first resistive element and the second resistive element according to the comparison result, wherein the first resistive element is coupled between the first output node and a reference voltage, and the second resistive element is coupled between the second output node and the reference voltage. | 05-10-2012 |
| 20120119790 | DYNAMIC COMPARATOR BASED COMPARISON SYSTEM - A comparison system including a dynamic comparator, a background offset calibration circuit, and an asynchronous reset timing control circuit is presented. The background offset calibration circuit is coupled to the dynamic comparator, and generates calibration signals in response to reference switching control signals. Where calibration signals are used to calibrate the input refer offset of the dynamic comparator. The asynchronous reset timing control circuit is coupled to the dynamic comparator and the background offset calibration circuit, and generates a control clock signal and the reference switching control signals in response to the output signals of the dynamic comparator and a plurality of basic clock signals. During each clock cycle of the first basic clock signal, the control clock signal is used to control the dynamic comparator to perform two data comparison, one for the input refer offset and the other for a differential input signal. | 05-17-2012 |
| 20120274359 | HIGH-SPEED DIFFERENTIAL COMPARATOR CIRCUITRY WITH ACCURATELY ADJUSTABLE THRESHOLD - A high-speed differential comparator circuit is provided with an accurately adjustable threshold voltage. Differential reference voltage signals are provided to control the threshold voltage of the comparator. The common mode voltage of the reference signals preferably tracks the common mode voltage of the differential high-speed serial data signal being processed by the comparator circuit. | 11-01-2012 |
| 20120280719 | Apparatus and Method for Selectively Enabling and Disabling a Squelch Circuit Across AHCI and SATA Power States - An apparatus and a method are provided for selectively enabling and disabling a squelch circuit in a Serial Advanced Technology Attachment (SATA) host or SATA device while maintaining proper operation of the host and device. An apparatus and method are provided which allow the squelch circuit to be selectively enabled and disabled across SATA power states (PHY Ready, Partial, and Slumber) and in Advanced Host Controller Interface (AHCI) Listen mode. | 11-08-2012 |
| 20120299623 | RADIO FREQUENCY (RF) POWER DETECTOR SUITABLE FOR USE IN AUTOMATIC GAIN CONTROL (AGC) - In one form, a power converter for a power detector or the like includes first and third transistors of a first conductivity type, and second and fourth transistors of a second conductivity type. A control electrode of the first transistor receives a first bias voltage plus a positive component of a differential input signal. The second transistor is coupled in series with the first transistor and has a control electrode receiving a second bias voltage plus a negative component of the differential input signal. The third transistor is biased using the first bias voltage plus the negative component. The fourth transistor is coupled in series with the third transistor and is biased using the second bias voltage plus the positive component. A common interconnection point of the first and third transistors forms an output node. | 11-29-2012 |
| 20130088262 | LOW VOLTAGE COMPARATOR CIRCUITS - Circuits that operate with power supplies of less than 1 Volt are presented. More particularly, circuits that operate with supply voltages near or lower than the threshold voltage of the transistors in those circuits are presented. Various circuits and embodiments such as operational transconductance amplifiers, biasing circuits, integrators, continuous-time sigma delta modulators, track-and-bold circuits, and others are presented. The techniques and circuits can be used in a wide range of applications and various transistors from metal-oxide-semiconductor to bipolar junction transistors may implement the techniques presented herein. | 04-11-2013 |
| 20130099824 | REDUCED OFFSET COMPARATOR - An apparatus is provided. The apparatus comprises backend circuitry and pairs of redundant input circuits. Each pair of redundant input circuits is configured to form a differential pair of transistors, and each redundant input circuit includes a multiplexer and a set of transistors. The multiplexer is coupled to the backend circuitry, and each transistor from the set of transistors has a first passive electrode, a second passive electrode, and a control electrode. The first passive electrode of each transistor from the set of transistors is coupled to the multiplexer, and the control electrodes from the set of transistors are coupled together. | 04-25-2013 |
| 20130099825 | VOLTAGE COMPARATOR - The present disclosure provides a voltage comparator including a current source, a differential gain module and a switch module, wherein the magnitude of the current flowing through the current source is nano ampere level; the differential gain module includes a first transistor, a second transistor, a third transistor and a fourth transistor, wherein the first transistor and the second transistor are respectively connected to the current source, the third transistor and the fourth transistor form a mirror current structure, the third transistor is connected to the first transistor, and the fourth transistor is connected to the second transistor via a ninth transistor used for forming asymmetric differential gain. | 04-25-2013 |
| 20130241599 | COMPARATOR CIRCUIT HAVING A CALIBRATION CIRCUIT - A comparator has a first terminal, a second terminal, and an output terminal. A selection circuit is coupled to the first terminal. A calibration circuit is coupled to the output terminal and the second terminal. The comparator is configured to operate in a first mode when the selection circuit provides a first input signal to the first terminal and the calibration circuit provides a second input signal to the second terminal. The comparator is configured to operate in a second mode when the selection circuit provides a first calibration signal to the first terminal and the calibration circuit provides a second calibration signal to the second terminal based on an output signal at the output terminal. The comparator generates the output signal based on the first calibration signal and the second calibration signal. | 09-19-2013 |
| 20130278291 | MULTIFUNCTION WORD RECOGNIZER ELEMENT - A circuit includes a load; a first differential pair coupled to the load and responsive to input data; a second differential pair coupled to the load and responsive to the input data; a third differential pair coupled to the first differential pair and the second differential pair and responsive to a first control signal and a second control signal; a bias circuit configured to pull a node coupled to both the first differential pair and the second differential pair to a predetermined state; and a current source coupled to the third differential pair and the bias circuit. | 10-24-2013 |
| 20220140823 | WIDE HIGH VOLTAGE SWING INPUT COMPARATOR STAGE WITH MATCHING OVERDRIVE - An apparatus includes a differential input pair, a first resistor, a second resistor, and a comparator. The differential input pair having first and second differential inputs. The first differential input is adapted to be coupled to an output of a controller and the second differential input is adapted to be coupled to a signal ground of the controller. The first resistor is adapted to be coupled to a third resistor via the first differential input to form a first voltage divider. The second resistor is adapted to be coupled to a fourth resistor via the second differential input to form a second voltage divider. The comparator having first and second comparator inputs. The first comparator input is coupled between the first resistor and the first differential input. The second comparator input is coupled between the second resistor and the second differential input. | 05-05-2022 |
| 327066000 | Current mirror | 7 |
| 20080265947 | Current mirror circuit and constant current having the same - A current mirror circuit includes a pair of first and second transistors having bases connected together and emitters connected to a power line, a resistor connected between the bases of the first and second transistors and the power line, a third transistor for providing base currents of the first and second transistors and a resistor current flowing through the resistor, and a current compensation circuit that adds a compensation current to an input current to the first transistor. The amount of the compensation current is approximately equal to that of the resistor current divided by a current gain of the third transistor. Thus, the compensation current compensates the difference between a collector current of the first transistor and the input current. | 10-30-2008 |
| 20090027086 | Comparator and method with controllable threshold and hysteresis - A comparator ( | 01-29-2009 |
| 20100001766 | SYSTEM TO EVALUATE A VOLTAGE IN A CHARGE PUMP AND ASSOCIATED METHODS - A system to evaluate a voltage in a charge pump may include a transistor, and a transistor drain carried by the transistor with the transistor drain receiving a reference current. The system may also include a transistor gate carried by the transistor and connected to the transistor drain. The system may further include an additional transistor and an additional transistor gate carried by the additional transistor and connected to the transistor gate. The system may additionally include an additional transistor drain to receive the reference current mirrored from the additional transistor. | 01-07-2010 |
| 20100052735 | SLEW RATE CONTROLLED LEVEL SHIFTER WITH REDUCED QUIESCENT CURRENT - A level shifter circuit includes two parallel current paths respectively controlled by switch transistors, a Wilson current mirror circuit, and a slew rate control circuit to selectively couple an output node either to a high (first) voltage source or to a ground (second voltage) source in response to differential input control signals signal. When the output node reaches a stable (high or low) voltage level, the low voltage on one of the current paths turns off a Wilson current mirror transistor in the other current path, thereby preventing quiescent current during stable periods. An optional cascode transistor is added to facilitate fabrication using low threshold voltage transistors. | 03-04-2010 |
| 20110001517 | SEMICONDUCTOR DEVICE - A disclosed semiconductor device includes an input terminal, a power line, a pnp-bipolar transistor connected to the power line, a first resistor connecting an emitter of the transistor to the input terminal, a second resistor connecting a collector of the transistor to ground, an operation circuit operable when the input voltage is a predetermined voltage or higher, the predetermined voltage being set within a first voltage region in which the input voltage cannot turn on the transistor, a comparator comparing an internal voltage with a reference voltage, the internal voltage being changed from a voltage value in a non-conductive state in which the transistor is not turned on, and an output terminal configured to output an output voltage which changes in response to a result of comparing the internal voltage with the reference voltage. | 01-06-2011 |
| 20110095788 | High-speed comparator with asymmetric frequency response - A comparator to provide an output voltage indicative of comparing an input voltage with a reference voltage, where the comparator has an asymmetric frequency response. With an asymmetric frequency response, the bandwidth of the input voltage may be greater than the bandwidth of the reference voltage. A comparator includes a differential pair of transistors coupled to a current mirror and biased by a current source, where in one embodiment, a capacitor shunts the sources of the differential pair. In a second embodiment, a capacitor couples the input voltage port to the gates of the current mirror transistors. In a third embodiment, the comparator utilizes both capacitors of the first and second embodiments. | 04-28-2011 |
| 20120126855 | REDUCED TEMPERATURE DEPENDENT HYSTERETIC COMPARATOR - This document discusses, among other things, apparatus and methods for controlling a hysteresis range of a voltage comparator. In an example, an apparatus can include an amplifier having a temperature dependency, a comparator configured to receive first and second currents and to provide an output voltage indicative of a hysteretic comparison of the first and second input voltages, wherein a range of hysteresis of the apparatus is controlled over a range of temperatures. In an example, the amplifier can be configured to receive first and second input voltages and to provide the first and second currents. | 05-24-2012 |
| 327067000 | Having feedback | 4 |
| 20090108882 | LOW POWER LOW VOLTAGE DIFFERENTIAL SIGNALING (LVDS) OUTPUT DRIVERS - A method and apparatus for providing a low power low voltage differential signaling driver are disclosed. In an example, a low voltage differential signaling driver circuit is described, comprising a first current source to provide current to a first differential pair of PNP transistors, a pair of transresistance amplifiers driven by a corresponding pair of transconductance stages, a second current source to provide current to a second differential pair of PNP transistors, and an output port having a common mode output voltage and a differential output voltage based on a state of the first differential pair of PNP transistors and the second differential pair of PNP transistors. | 04-30-2009 |
| 20090243663 | ANALOG COMPARATOR COMPRISING A DIGITAL OFFSET COMPENSATION - A digital compensation of an input stage of a comparator may be achieved by providing switched load elements, which may be appropriately connected to the differential input pair of the comparator in order to match transistor characteristics of the input pair and also match the load value of the input stage. Thus, enhanced offset behavior may be accomplished without providing an external signal and/or without requiring complex reference voltages/currents. | 10-01-2009 |
| 20120274360 | SWITCHED CAPACITANCE VOLTAGE DIFFERENTIAL SENSING CIRCUIT WITH NEAR INFINITE INPUT IMPEDANCE - A circuit may sense the differential voltage across two nodes that each have a non-zero common mode voltage. The circuit may have a positive input impedance that is imposed across the nodes. An impedance compensation circuit may generate a compensation current that is delivered to the nodes that substantially cancels the loading effect of the positive input impedance. The impedance compensation circuit may generate a negative input impedance that is imposed across the two nodes that is substantially the same as the positive input impedance. The impedance compensation circuit may instead be configured to deliver the compensation current to the nodes. | 11-01-2012 |
| 20130120025 | COMPARATOR AND AD CONVERTER PROVIDED THEREWITH - Disclosed is a comparator including a switching element, a differential pair, and a positive feedback part, the positive feedback part including a first CMOS inverter and a second CMOS inverter, the first CMOS inverter including a first element for providing a potential difference between a first PMOS transistor and a first NMOS transistor, the second CMOS inverter including a second element for providing a potential difference between a second PMOS transistor and a second NMOS transistor, a higher potential side of the first element being connected to a gate of the second NMOS transistor, a lower potential side of the first element being connected to a gate of the second PMOS transistor, a higher potential side of the second element being connected to a gate of the first NMOS transistor, and a lower potential side of the second element being connected to a gate of the first PMOS transistor. | 05-16-2013 |
