Class / Patent application number | Description | Number of patent applications / Date published |
327072000 | Input signal compared to reference derived therefrom | 38 |
20080197887 | Comparator Circuit - Provided is a comparator circuit that is capable of operating at high speed and canceling an offset voltage with high precision. The comparator circuit includes a second amplifier circuit for amplifying an output of an amplifier circuit and feeding back the amplified output to an input of the amplifier circuit. When the comparator circuit samples the input voltage, the second amplifier circuit conducts feedback and increases a gain to cancel the offset. Also, when the gain of the amplifier circuit is made lower than the gain of the second amplifier circuit, and the comparator circuit compares the input voltage, the comparing operation can be conducted at high speed by separating the amplifier circuit from the feedback of the second amplifier circuit. | 08-21-2008 |
20080197888 | Low voltage shutdown circuit - A low voltage shutdown circuit comprises an input node for receiving a voltage V | 08-21-2008 |
20080231326 | SIGNAL CONDITIONING FOR AN OPTICAL ENCODER - An encoder with signal conditioning of an emitter drive signal is described. In one embodiment, the encoder includes a peak comparator, a pulse generator, a threshold comparator, and digital circuitry. The peak comparator outputs a peak comparator signal based on a comparison of an input sinusoidal signal stored at a first time with the input sinusoidal signal stored at a second time. The pulse generator determines a peak of the input sinusoidal signal based on the peak comparator signal. The threshold comparator compares a differential signal amplitude with a differential signal amplitude window at approximately the peak of the input sinusoidal signal. The differential signal amplitude is associated with the input sinusoidal signal. The digital circuitry generates an emitter modification signal in response to a determination that the differential signal amplitude is outside of the differential signal amplitude window. | 09-25-2008 |
20080315923 | COMPENSATING A PUSH-PULL TRANSMIT DRIVER - An interface such a PCI-E interface may comprise a transmitter and a compensation circuit. In one embodiment, the transmitter may comprise a transmit driver, which may use a push-pull configuration. The transmit driver may require stable voltages such as (Vdd/2+0.25) and (Vdd/2−0.25) Volts. The compensation circuit may comprise a voltage generator circuit and a dummy driver circuit. The dummy driver may be a replica of the transmit driver. A correction module may generate correction factors based on the deviation of the voltages generated by the dummy driver from the voltages generated by the voltage generator. The voltages provided to the transmit driver are corrected based on the correction factors to compensate for the deviation. | 12-25-2008 |
20090027087 | LOW POWER VOLTAGE DETECTION CIRCUIT AND METHOD THEREFOR - In one embodiment, a low power voltage detection circuit includes a first voltage detection device that receives power from an input voltage and a second voltage detection device receives power from an output of the low power voltage detection circuit. | 01-29-2009 |
20090051392 | Circuit device and electronic equipment provided with the same - In one embodiment, a circuit device that performs a certain processing operation with respect to an input signal by referring to a reference voltage and outputs the result is caused to have a function of switching the reference voltage, whereby a circuit device from which a stable output can be obtained is disclosed. The circuit device includes a comparator and a reference voltage setting circuit. The comparator compares an input voltage fed from outside with a reference voltage selected from a reference voltage set including a plurality of voltage values that are different from one another. The reference voltage setting circuit selects a voltage value lower than the reference voltage from the reference voltage set when it is detected that the input voltage in a rising transition reaches the reference voltage, selects a voltage value higher than the reference voltage from the reference voltage set when it is detected that the input voltage in a falling transition reaches the reference voltage, and sets the selected voltage value as the reference voltage of the comparator. | 02-26-2009 |
20090167363 | REDUCTION OF SIGNAL SKEW - Skew is reduced by extracting the AC component of an input signal and superimposing it on a common reference voltage to produce a resulting voltage. The resulting voltage is provided as an input to a comparator, which compares it to the reference voltage to provide a final output. Thus, all signals fed to a system, in accordance with an embodiment, are referenced at the same DC level and hence, skew is reduced. | 07-02-2009 |
20100079172 | DIFFERENTIAL OUTPUT CIRCUIT - A differential output circuit including a first output driving circuit that includes a first PMOS transistor and a first NMOS transistor connected in series to each other, a second output driving circuit that includes a second PMOS transistor and a second NMOS transistor connected in series to each other and a control circuit, wherein, when a control signal has a first value, the control circuit selectively turns on one of the first and second PMOS transistors and selectively turns on one of the first and second NMOS transistors, thereby controlling the first and second output driving circuits to output a first pair of differential signals, and when the control signal has a second value, the control circuit supplies no current to the PMOS transistors and selectively turns on one of the NMOS transistors, thereby controlling the output driving circuits to output a second pair of differential signals. | 04-01-2010 |
20100097103 | Receiving circuit, electronic apparatus and method for controlling receiving circuit - A receiving circuit includes a comparing circuit, a first storage circuit, a second storage circuit, and a voltage controlling circuit. The comparing circuit compares an input signal with a reference voltage and outputs a signal with either a first level when the input signal is larger than the reference voltage or a second level when the input signal is smaller than the reference voltage as a comparison result. The first storage circuit stores an output level of the comparing circuit for a next one cycle. The second storage circuit stores an output level of the first storage circuit for a next one cycle. The voltage controlling circuit controls a level of the reference voltage in each cycle on the basis of output levels of the first storage circuit and the second storage circuit. | 04-22-2010 |
20100207664 | INPUT VOLTAGE DETECTING CIRCUIT AND POWER SUPPLY HAVING SUCH INPUT VOLTAGE DETECTING CIRCUIT - An input voltage detecting circuit includes an input circuit, a signal processing circuit and an output circuit. The input circuit is used for processing the intensity and the waveform of an input voltage, thereby generating a first signal, wherein the first signal and the input voltage have similar time sequences. The signal processing circuit is connected to the input circuit for reducing a first delaying time of the first signal, thereby generating a second signal having a second delaying time shorter than the first delaying time. The output circuit is connected to the signal processing circuit for processing the intensity and the waveform of the second signal, thereby generating the power status signal. If the input voltage is uninterrupted, the power status signal is in an uninterrupted status. If the input voltage is interrupted, the power status signal is in an interrupted status. | 08-19-2010 |
20100271075 | TEST AND MEASUREMENT INSTRUMENT WITH AN AUTOMATIC THRESHOLD CONTROL - A test and measurement instrument including a plurality of channels, each channel configured to receive a corresponding input signal. Each channel includes a comparator configured to compare the input signal to a threshold for the channel; an edge detector configured to detect an edge of an output signal of the comparator; and a threshold controller configured to adjust the threshold for the channel in response to the edge detector. | 10-28-2010 |
20110050286 | TEMPERATURE SENSING CIRCUIT - A temperature sensing circuit that does not use an oscillator is presented. The temperature sensing circuit includes a selector and a detector. The selector is configured to select and output a reference voltage from first and second level signals in response to first and second trimming signals. The first and second level signals are relatively insensitive to temperature variations. The detector is configured to generate a detection voltage by comparing the reference voltage with a variable voltage depending on internal temperature. | 03-03-2011 |
20110095789 | CIRCUITS AND METHODS FOR VOLTAGE DETECTION - A circuit for detecting an input voltage includes a voltage-to-current converter and a current comparator. The voltage-to-current converter is operable for generating a monitoring current that varies in accordance with the input voltage. The current comparator coupled to the voltage-to-current converter is operable for comparing the monitoring current to a threshold current proportional to the temperature of the circuit, and for generating a detection signal indicating a condition of the input voltage based on a result of the comparison. | 04-28-2011 |
20110121864 | START SIGNAL DETECTOR CIRCUIT - The nonlinearity effect of a rectifying element is enhanced, and further a resonant circuit is used to enlarge the input amplitude. Furthermore, the rectifying efficiency of a detection rectifier circuit is enhanced, thereby allowing the gain of an amplifier circuit in the following stage to be set to a low value. Signals having mutually opposite phases are inputted to RF input terminals ( | 05-26-2011 |
20110128046 | Monitoring system - The invention relates to a monitoring system, having an output module for generating a control signal in response to an input signal, a monitoring module for generating the input signal for the output module, an output device for outputting an output signal in response to the control signal, and a feedthrough device for preventing outputting of the output signal. According to the invention, the monitoring module is designed to instruct the feedthrough device to prevent outputting of the output signal when there is a deviation between the control signal and a control signal which is expected on the basis of the input signal. | 06-02-2011 |
20110133783 | SIGNAL INTERPOLATION METHODS AND CIRCUITS - An interpolation circuit for comparing an input voltage signal with an interpolated reference signal derived from a first reference voltage signal and a second reference voltage signal may include a transconductive circuit configured to generate a first differential current signal proportional to a difference between the first reference voltage signal and the input voltage signal and a second differential current signal proportional to a difference between the second reference voltage signal and the input voltage signal, an intermediate circuit configured to generate a third differential current signal, and a transinductive circuit configured to generate an output voltage signal having a first polarity if a value of the input voltage signal is greater than a value of the interpolated reference signal and a second polarity if the value of the input signal is less than the value of the interpolated reference signal. | 06-09-2011 |
20110156758 | SIGNAL MONITORING SYSTEMS - In a signal monitoring system, a circuit includes an input terminal and an output terminal. In addition, a processor coupled to the circuit is operable for calculating a parameter indicative of an error factor of the circuit by setting a level difference between an input signal at the input terminal and an output signal at the output terminal to a predetermined level. | 06-30-2011 |
20110304359 | SEMICONDUCTOR INTEGRATED CIRCUIT, THRESHOLD VALUE SETTING METHOD, AND COMMUNICATION APPARATUS - A semiconductor integrated circuit includes first to N-th comparators to compare an input voltage with a threshold value; and a control circuit to perform first and second operations, set a threshold value of the first comparator as a first threshold value, and set a threshold value of an M-th comparator as a second threshold value, wherein the first operation includes an operation where a value obtained by multiplying a value obtained by subtracting the threshold value of the M-th comparator from a threshold value of an (M+1)th comparator by a real number is added to the threshold value of the M-th comparator, and wherein the second operation includes an operation where a value obtained by multiplying a value obtained by subtracting the threshold value of the M-th comparator from a threshold value of an (M−1)th comparator by a real number is added to the threshold value of the M-th comparator. | 12-15-2011 |
20120013365 | LOW VOLTAGE DETECTOR - A low voltage detector ( | 01-19-2012 |
20120013366 | CALIBRATING A SYSTEM BY SETTING DIFFERENCE BETWEEN SIGNALS - In a signal monitoring system, a circuit includes an input terminal and an output terminal. In addition, a processor coupled to the circuit is operable for calculating a parameter indicative of an error factor of the circuit by setting a level difference between an input signal at the input terminal and an output signal at the output terminal to a predetermined level. | 01-19-2012 |
20120218003 | Systems and Methods for Current Sensing - Systems and methods for current sensing are described. The described systems and methods utilize a comparator for generating a current sense signal based on comparing an output current of a circuit against a reference current. The reference current is generated by using a current sourcing circuit that is connected to a controllable current source. | 08-30-2012 |
20120280720 | INTRA-PAIR SKEW CANCELLATION TECHNIQUE FOR DIFFERENTIAL SIGNALING - A method for deskewing a differential signal is provided. A common-mode voltage of a differential signal and an average for the common-mode voltage of the differential signal are measured. A difference between first and second portions of the differential signal is determined, and deskew information is derived from the common-mode voltage and the average. The deskew information can then be combined with the difference to deskew the differential signal. | 11-08-2012 |
20130154688 | Method for Detecting a Working Area and Device Therefor - A method for detecting a position with respect to a mobile working machine includes providing a current signal in a boundary conductor, which surrounds the defined area, in accordance with a boundary signal that is provided, the boundary signal corresponding to a pseudo-accident signal; and receiving a detection signal of a magnetic field. The method further includes generating a reconstructed boundary signal from the detection signal; providing a reference signal which has a bit pattern corresponding to the boundary signal provided; carrying out a correlation method in order to determine a time-based correlation offset between the reference signal and the reconstructed boundary signal and a correlation value between the reference signal and the reconstructed boundary signal, which are displaced in relation to each other by the correlation offset determined; and determining a position inside or outside the defined area as a function of the correlation value determined. | 06-20-2013 |
20130321029 | INPUT DECISION CIRCUIT - An input decision circuit includes a comparator outputting either one of a high voltage or a low voltage on the basis of the result of a comparison between a reference voltage and an input voltage, a base voltage source acting as a base common to the reference voltage and the input voltage, a constant current source supplying a constant current to a constant current path from a DC power supply to the base voltage source, and a resistor inserted in the constant current path. A constant voltage is produced across the resistor for the reference voltage with the electric potential of the base voltage source acting as a base. This provides an input decision circuit in which a threshold voltage is hard to shift even when the driving voltage of the comparator or the electric potential of the ground acting as the base voltage source is varied. | 12-05-2013 |
20140077842 | ZERO OR ULTRA-LOW DC CURRENT CONSUMPTION POWER-ON AND BROWN-OUT DETECTOR - Embodiments of a power-on and brown-out detector are described. In an embodiment, a power-on and brown-out detector for a power supply includes a power-on detection module, a brown-out detection module, and a logic module. The power-on detection module is connected to the power supply and is configured to generate a power-on signal in response to a voltage increase of the power supply. The brown-out detection module is connected to the power supply and is configured to generate a brown-out signal in response to a voltage charge by the power supply and a subsequent voltage decrease of the power supply. The logic module is configured to generate a control signal in response to the power-on signal and the brown-out signal. The power-on detection module is further configured to be activated or deactivated by the control signal. Other embodiments are also described. | 03-20-2014 |
20140312934 | LOW-POWER MAGNETIC SLOPE DETECTING CIRCUIT - One embodiment of the present invention relates to a method and apparatus to perform a low power activation of a system by measuring the slope of a digital signal corresponding to a motion sensor measurement value. In one embodiment, a low power activation circuit is coupled to magnetic motion sensor configured to output a magnetic signal proportional to a measured magnetic field. The low power activation circuit may comprise a digital tracking circuit configured to provide a digital signal that tracks the magnetic field and a difference detector configured to detect a difference between a current digital signal and a prior digital signal stored in a digital storage means. If the detected difference is larger than a digital reference level, an activation signal is output to awaken a system from a sleep mode. | 10-23-2014 |
20150333752 | LOW-POWER MAGNETIC SLOPE DETECTING CIRCUIT - One embodiment of the present invention relates to a method and apparatus to perform a low power activation of a system by measuring the slope of a digital signal corresponding to a motion sensor measurement value. In one embodiment, a low power activation circuit is coupled to magnetic motion sensor configured to output a magnetic signal proportional to a measured magnetic field. The low power activation circuit may comprise a digital tracking circuit configured to provide a digital signal that tracks the magnetic field and a difference detector configured to detect a difference between a current digital signal and a prior digital signal stored in a digital storage means. If the detected difference is larger than a digital reference level, an activation signal is output to awaken a system from a sleep mode. | 11-19-2015 |
20180026614 | SEMICONDUCTOR DEVICE | 01-25-2018 |
327073000 | Reference derived by feedback | 10 |
20090002033 | Noise removal circuit and comparator circuit including same - The present invention reliably removes a signal change associated with a noise component from a comparison signal of a comparator. A comparator circuit includes a comparator and a timer circuit. After a reversal of the comparison signal, if the level of the comparator is sustained at least from a first time to a second time, an output signal is reversed and output. The timer circuit includes a memory unit that is shifted to a memory state in which the reversal of the comparison signal is stored at the first time if the reversal is verified. If the comparison signal is reversed during the interval between the first time and second time, the memory state is cleared. | 01-01-2009 |
20090212827 | Correlated double sampling circuit - A correlated double sampling circuit includes a first capacitor and a comparator. The first capacitor may be configured to receive a ramp signal via a first end. The comparator may be configured to receive the ramp signal and an output signal of a unit pixel circuit via a differential amplifier included in the comparator. The comparator may be also be configured to compare the output signal with the ramp signal and may be configured to directly receive the output signal of the unit pixel circuit at a first input terminal of the differential amplifier. A second input terminal of the differential amplifier is connected to a second end of the first capacitor. | 08-27-2009 |
20090261862 | Techniques For Measuring Voltages in a Circuit - A circuit can include a comparator, a resistor divider, a control circuit, and a multiplexer. The comparator compares an internal supply voltage of the circuit to a selected reference voltage. The resistor divider generates reference voltages. The control circuit receives an output signal of the comparator and generates a select signal. The multiplexer transmits one of the reference voltages from the resistor divider to the comparator as the selected reference voltage in response to the select signal. | 10-22-2009 |
20090322380 | DRIVE CIRCUIT DEVICE FOR A POWER SEMICONDUCTOR, AND SIGNAL TRANSFER CIRCUIT DEVICE FOR USE THEREIN - A power semiconductor drive circuit device includes: an electronic control device generating a control input signal; a signal transfer circuit device having a main path and a self-diagnosis functional block; and a power semiconductor driven by the control output signal from the signal transfer circuit device. The self-diagnosis functional block includes: a feedback pulse transmitter circuit; a second signal transfer circuit; and a second receiver circuit. The second receiver circuit compares the control output signal with the control input signal so as to find out whether the control output signal is matched or unmatched with the control input signal, and then outputs a result to a comparison signal output terminal. A signal outputted to the comparison signal output terminal is transferred to the electronic control device. | 12-31-2009 |
20090322381 | LIGHT RECEIVING CIRCUIT, LIGHT RECEIVING METHOD, AND STORAGE MEDIUM - The PD converts the light into a current signal and supplies the converted a current signal to a TIA and a light intensity measuring unit. The TIA converts the current signal into a voltage signal. The CDR circuit identifies whether the voltage signal is 1 data or 0 data for reproduction. The counter counts the 1 data and 0 data, calculates their ratio. The control unit refers to light intensity data from the light intensity measuring unit and a ROM, acquires an optimum ratio, and determines whether the ratio supplied from the counter is the optimum ratio. When the ratio is not the optimum one, the control unit controls the threshold voltage setting unit to set the threshold voltage so that the ratio is the optimum one. | 12-31-2009 |
20110204924 | Techniques For Measuring Voltages in a Circuit - A circuit includes a comparator, a resistor divider, a control circuit, a multiplexer, and a programmable gain amplifier. The comparator is operable to measure an internal voltage of the circuit based on a selected reference voltage. The resistor divider is operable to generate reference voltages. The control circuit is operable to generate a select signal based on an output signal of the comparator. The multiplexer is operable to select one of the reference voltages from the resistor divider as the selected reference voltage based on the select signal. The programmable gain amplifier is configurable to generate a compensation voltage to compensate for an offset voltage of the comparator. The compensation voltage is provided to an input of the comparator. | 08-25-2011 |
20110210762 | COMPARATOR CIRCUIT PROVIDED WITH DIFFERENTIAL AMPLIFIER MAKING LOGICAL JUDGMENT BY COMPARING INPUT VOLTAGE WITH REFERENCE VOLTAGE - In a comparator circuit having a differential amplifier, which makes a logical judgment by comparing an input voltage with a reference voltage, generates and outputs a resulting output voltage thereof, a current source generates and supplies a bias current of a predetermined minute current to the differential amplifier, and a first inverter circuit inverts a differential voltage from the differential amplifier. An adaptive bias current generator circuit detects the bias current of the current source, and a through current of the first inverter circuit. The adaptive bias current generator circuit generates and supplies an adaptive bias current for executing adaptive bias current control to the differential amplifier to allow the differential amplifier to operate with the bias current upon no logical judgment, and to allow the differential amplifier to operate by using the adaptive bias current obtained by increasing the bias current upon logical judgment. | 09-01-2011 |
20120229169 | Techniques For Measuring Voltages in a Circuit - A circuit includes a comparator, a programmable current source, and a control circuit. The comparator is operable to compare an internal supply voltage of the circuit to a reference voltage. The programmable current source is operable to supply a first current for the reference voltage. The control circuit is operable to control the first current through the programmable current source based on an output signal of the comparator. | 09-13-2012 |
20120319735 | CIRCUIT AND METHOD FOR DETERMINING COMPARATOR OFFSETS OF ELECTRONIC DEVICES - A device includes a comparator, and a selection circuit coupled to the inputs of the comparator. The selection circuit receives reference voltages and a variable voltage. In a normal operation mode, the selection circuit provides the variable voltage and a selected reference voltage to the comparator and the comparator provides an indication based on the variable voltage. In a test mode, the selection circuit provides a first selected reference voltage and a second selected reference voltage to the comparator for determining a switching offset voltage of the comparator. | 12-20-2012 |
20140266310 | SYSTEMS AND METHODS FOR EDGE CONTROL BASED ON DETECTING CURRENT DIRECTION IN A SWITCHED OUTPUT STAGE - In accordance with these and other embodiments of the present disclosure, an apparatus and a method may include receiving a first input configured to indicate an output voltage of an output node of a switched output stage comprising a pull-down driver device coupled at its non-gate terminals between a ground voltage and the output node and a pull-up driver device coupled at its non-gate terminals between a supply voltage and the output node. The method may also include receiving a second input configured to indicate a gate voltage of a gate terminal of a first one of the pull-up driver device and the pull-down driver device. The method may further include detecting direction of an output current flowing into or out of the output node based on the first input and the second input. | 09-18-2014 |