Class / Patent application number | Description | Number of patent applications / Date published |
327064000 | With logic or bistable circuit | 14 |
20080197886 | CIRCUIT FOR DISCRIMINATING OUTPUT OF SQUELCH CIRCUIT AND CIRCUIT FOR REGULATING SENSIVITY OF THE SAME - A circuit for discriminating a ‘Noisy’ state of an output of a squelch circuit is disclosed. A circuit for resolve the ‘Noisy’ state of the output of the squelch circuit is also disclosed which uses the output identification circuit. The output of the squelch circuit and a clear signal are input into a first AND gate. The output of the first AND gate is input into a first flip-flop. An inversed signal of the output of the first AND gate is input into a second flip-flop. The outputs of the first and second flip-flops are input into a discriminating unit including a second AND gate. The ‘Noisy’ state is identified by the output of the second AND gate. Based on the identification result, sensitivity of the squelch circuit is regulated. | 08-21-2008 |
20090039921 | VOLTAGE DETECTING CIRCUIT AND BATTERY DEVICE USING SAME - A voltage detecting circuit included in a battery device includes an input voltage comparing circuit that compares a first threshold value voltage or a second threshold value voltage lower than the first threshold value voltage with an input voltage to control the opening and closing of an output switching element, and a threshold value voltage setting circuit that compares a third threshold value voltage lower than the second threshold value voltage with the input voltage and, when the input voltage changes from a low voltage to a high voltage and intersects the third threshold value voltage, outputs a pulse for a predetermined period thereafter so that the second threshold value is selected in the input voltage comparing circuit. As a result, when the input voltage increases from the ground potential, the second threshold value is compared with the input voltage in the input voltage comparing circuit. The voltage detecting circuit and battery device using the circuit, when assembled in battery using equipment, uses a battery up to its usage limit. | 02-12-2009 |
20090134914 | LOW OFFSET COMPARATOR AND OFFSET CANCELLATION METHOD THEREOF - A low offset comparator includes a preamplifier and a latch. The preamplifier includes a first output offset storage stage, a cascade of input offset storage stages and a second output offset storage stage. The first output offset storage stage receives an input voltage. The cascade of input offset storage stages is connected to follow the first output offset storage stage. The second output offset storage stage is connected to follow the input offset storage stages. The latch is connected to follow the preamplifier. The low offset comparator is characterized in that the cascade of input offset storage stages, the second output offset storage stage and the first output offset storage stage are configured to sequentially leave an offset cancellation mode, and the input offset storage stages, when leaving the offset cancellation mode, are to open their unity-gain feedback loops before disconnecting their input offset storages from a ground voltage. | 05-28-2009 |
20090153196 | VOLTAGE COMPARATOR HAVING IMPROVED KICKBACK AND JITTER CHARACTERISTICS - A comparator apparatus for comparing a first and a second voltage input includes a pair of cross-coupled inverter devices, including a pull up device and a pull down device, with output nodes defined between the pull up and pull down devices. A first switching device is coupled to the first input and a second switching device is coupled to the second input, with control circuitry configured for selective switching between a reset mode and a compare mode. In the reset mode, the first and second voltage inputs are coupled to respective output nodes so as to develop a differential signal thereacross, and the pull down devices in each inverter are isolated from the pull up devices. In the compare mode, the voltage inputs are isolated from the output nodes, and the pull down devices in each inverter are coupled to the pull up devices to latch the output nodes. | 06-18-2009 |
20090167362 | COMPARATOR - A comparator is provided. In a first period, input terminal of the pre-amplifier is coupled to a first voltage. A first terminal of the first capacitor is coupled to the second input terminal of the pre-amplifier. A second terminal of the first capacitor is coupled to the first input voltage in the first period, and is coupled to the second input voltage in the second period. The second capacitor is coupled between the output terminal of the pre-amplifier and an input terminal of the gain unit. The switch is coupled between the input terminal and an output terminal of the gain unit. An input terminal of the latch is coupled to the output terminal of the gain unit. The latch outputs a comparison result. | 07-02-2009 |
20100007385 | 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. | 01-14-2010 |
20110068829 | COMPARATOR CIRCUIT AND DISPLAY DEVICE PROVIDED WITH THE SAME - An inverter is configured by double gate TFTs, and an inverter is configured by double gate TFTs. Top gate terminals of the TFTs that configure the inverter are connected to an input terminal DAT(+), and bottom gate terminals are connected to an output of the inverter and an output terminal OUT. Bottom gate terminals of the TFTs that configure the inverter are connected to an input terminal DAT(−), and bottom gate terminals are connected to an output of the inverter. With this, threshold voltages of the inverters are controlled so as to facilitate switching operations of the inverters, and whereby the comparator circuit operates at a high speed. It is possible to obtain a comparator circuit that is insusceptible to a variation in the threshold voltages of the transistors and fluctuation of a common mode voltage of an input signal and capable of operating at a high speed. | 03-24-2011 |
20110215838 | DIGITAL NOISE FILTER - A digital noise filter circuit includes a gating clock generating circuit and a noise filter circuit. The gating clock generating circuit compares logic levels of an input signal and an output signal of the noise filter circuit. The gating clock generating circuit supplies a gating clock as an operating clock to the noise filter circuit when the logic levels of both signals do not coincide, and halts supply of the gating clock when the logic levels of both signals do coincide. The noise filter circuit removes noise from the input signal and outputting the resultant signal as the output signal. | 09-08-2011 |
20120274358 | IDENTICAL-DATA DETERMINATION CIRCUIT - A identical-data determination circuit includes a first activation unit configured to activate an output signal when first and second signals each have a first level, a second activation unit configured to activate the output signal when the first and second signals each have a second level different from the first level, an initialization unit configured to deactivate the output signal when an initialization signal is applied, and a storage unit configured to store the output signal. | 11-01-2012 |
20130335119 | Bi-Directional Comparator - A bi-directional comparator compares two input signals and applies a hysteresis level to the smaller input signal only after the output signal switches logical states and when the two input signals are within a predetermined range of each other. In one embodiment, the hysteresis applied to the smaller input signal is removed when the two input signals are no longer within the predetermined range of each other. | 12-19-2013 |
20140084960 | DYNAMIC COMPARATOR WITH EQUALIZATION FUNCTION - The present disclosure provides a dynamic comparator with equalization function including a preamplifier, switched latch and dynamic transconductance circuit. The preamplifier amplifies input signals of the dynamic comparator. The dynamic transconductance circuit is inserted between the preamplifier and the switched latch for operating in a reset mode or a comparison mode. When operating in the reset mode, the dynamic transconductance circuit in conjunction with the switched latch performs voltage equalization of output signals of the switched latch, or when operating in the comparison mode, the dynamic transconductance circuit in conjunction with the switched latch receives the output signals generated by the preamplifier and carries out signal transconductance. The switched latch generates output signals as a comparison result of the dynamic comparator based on the transconductance signals generated by the dynamic transconductance circuit. The present disclosure provides a dynamic comparator that reduces the power consumption and increasing the operating speed. | 03-27-2014 |
20140132307 | Comparator and calibration thereof - A comparator is provided and the comparator includes a comparing input unit and a latching unit. Wherein, the comparing input unit has a first input receiving a first comparing signal and has a second input receiving a second comparing signal. The comparing input unit drives a first intermediate node signal at a first intermediate node depending on the first comparing signal according to a first strobe signal, and the comparing input unit drives a second intermediate node signal at a second intermediate node depending on the second comparing signal according to the first strobe signal. The latching unit determines a comparing result according to at least one of the first intermediate node signal and the second intermediate node signal. In addition, the latching unit latches the comparing result according to a second strobe signal. | 05-15-2014 |
20140285239 | POWER MONITORING CIRCUITRY - Power monitoring circuitry. In some embodiments, comparator circuitry may be configured to receive a first voltage value and a second voltage value, and to identify the greater of the first and second voltage values. Selector circuitry coupled to the comparator circuitry may be configured to power one or more components within the comparator circuitry with a supply voltage corresponding to the greater voltage value. In other embodiments, a method may include identifying, via a comparator, the largest among a plurality of voltage values, and powering one or more logic components within the comparator with the identified voltage value. | 09-25-2014 |
20160028378 | RECEIVING CIRCUIT - A receiving circuit includes first input transistors of a first conductivity type including control terminals to which differential input signals are applied; load transistors of a second conductivity type connected between a first wiring to which a first voltage is supplied and first terminals of the first input transistors; second input transistors of the second conductivity type including control terminals to which the differential input signals are applied; a latch circuit connected between a second wiring to which a second voltage is supplied and first terminals of the second input transistors; and conversion transistors of the second conductivity type connected in parallel to the second input transistors, the conversion transistors including control terminals that are connected to output nodes to which the first input transistors and the load transistors are connected. | 01-28-2016 |