Class / Patent application number | Description | Number of patent applications / Date published |
327263000 | Delay interval set by rising or falling edge | 21 |
20080218236 | DELAY CIRCUIT - A delay circuit ( | 09-11-2008 |
20080303574 | INTERNAL CLOCK DRIVER CIRCUIT - An internal clock signal driver circuit includes a delay block that delays a rising clock signal and a falling clock signal, and outputs a delayed rising clock signal and a delayed falling clock signal, a rising DLL clock signal generating block that receives and combines the rising clock signal, the falling clock signal, and the delayed rising clock signal, and outputs a rising DLL clock signal, and a falling DLL clock signal generating block that receives and combines the rising clock signal, the falling clock signal, and the delayed falling clock signal, and outputs a falling DLL clock signal. | 12-11-2008 |
20100134169 | Delay Circuit - A delay circuit includes a ring oscillator and a control circuit. The control circuit includes an edge detector that outputs a first control signal in response to a rising edge or a falling edge of an input signal, and a counter that counts the number of pulses of an output pulse signal output from the ring oscillator and outputs a second control signal upon reaching a predetermined count number. The control circuit performs control to make the ring oscillator oscillate in response to the first control signal and to output the input signal in response to the second control signal. | 06-03-2010 |
20110084749 | METHOD AND APPARATUS FOR GENERATING A MODULATED WAVEFORM SIGNAL - A semiconductor device comprising timer logic for generating a first modulated waveform signal, and delay logic, operably coupled to the timer logic and arranged to provide a first delay in a rising edge of the first modulated waveform signal generated by the timer logic; and provide a second delay in a falling edge of the first modulated waveform generated by the timer logic. The first delay and second delay of the first modulated waveform forms a second, refined modulated waveform signal that comprises a higher frequency resolution than a frequency resolution of the first modulated waveform signal. | 04-14-2011 |
20110109366 | Method and Apparatus to Limit Circuit Delay Dependence on Voltage for Single Phase Transition - A delay circuit receives a data input having an input transition and that generates a data output having an output transition. The delay circuit is powered by a voltage source having a voltage. A first delay element is configured to generate a first data signal with a first edge that has a relatively constant delay relative to the input transition irrespective of the voltage of the voltage source. A second delay element is configured to generate a second data signal with a second edge that has a delay relative to the input transition as a function of the voltage of the voltage source. A selection element causes the output transition at the data output to correspond to a latest selected one of the first edge and the second edge. The delay circuit may be employed in a pulse generating circuit. | 05-12-2011 |
20130038368 | SEMICONDUCTOR DEVICE - A semiconductor device including a common delay circuit configured to delay an input signal in response to a delay control code to output a first delayed input signal and a second delayed input signal; a first delay circuit configured to delay the first delayed input signal in response to the delay control code and to output a first output signal; and a second delay circuit configured to delay the second delayed input signal in response to the delay control code and to output a second output signal. | 02-14-2013 |
20130076424 | SYSTEM AND METHOD FOR REDUCING CROSS COUPLING EFFECTS - A device includes a plurality of driver circuits coupled to a plurality of bus lines. A first driver circuit of the plurality of driver circuits is coupled to a first bus line of the plurality of bus lines. The first driver circuit includes one of a skewed inverter, a level shifter, a latch, and a sense amplifier configured to produce an output signal that transitions after a first delay in response to a first digital value transition of an input signal from high to low and transitions after a second delay in response to a second digital value transition of the input signal from low to high. The first delay is different from the second delay by an amount sufficient to reduce power related to transmission of signals over the first bus line and over a second bus line in close physical proximity to the first bus line. | 03-28-2013 |
20130076425 | INTEGRATED CIRCUIT DEVICE TIMING CALIBRATION - Techniques for performing timing calibration for an integrated circuit (IC) device are described. During operation, a first integrated circuit device transmits a first calibration pattern having differently delayed rising edge transitions with respect to a timing reference. The first integrated circuit device additionally transmits a second calibration pattern having differently delayed falling edge transitions with respect to the timing reference. Next, the first integrated circuit generates a timing offset for transmitting data from the first integrated circuit device. This timing offset is derived from information received from a second integrated circuit device sampling the first calibration pattern and the second calibration pattern. | 03-28-2013 |
20140070862 | TIMING CALIBRATION FOR ON-CHIP INTERCONNECT - One embodiment sets forth a timing calibration technique for on-chip source-synchronous, complementary metal-oxide-semiconductor (CMOS) repeater-based interconnect. Two transition patterns may be applied to calibrate the delay of an on-chip data or clock wire. Calibration logic is configured to apply the transition patterns and then trim the delays of the clock and data wires based on captured calibration patterns. The trimming adjusts the delay of the clock and data wires using a configurable delay circuit. Timing errors may be caused by crosstalk, power-supply-induced jitter (PSIJ), or wire delay variation due to transistor and wire metallization mismatch. Chip yields may be improved by reducing the occurrence of timing errors due to mismatched delays between different wires of an on-chip interconnect. | 03-13-2014 |
20140111265 | DELAY CIRCUIT - A delay circuit for receiving an input signal and generating a delayed output signal. The delay circuit includes a first delay module and a second delay module. The first delay module includes a first delay unit for generating a first delayed signal according to an input signal and a first logic unit, coupled to the first delay unit, for generating a first delayed output signal according to the first delayed signal and the input signal. The second delay module includes a second delay unit for generating a second delayed signal according to the first delayed output signal and a second logic unit, coupled to the second delay unit, for generating the delayed output signal according to the second delayed signal and the input signal. | 04-24-2014 |
327264000 | Having specific active circuit element or structure (e.g., FET, complementary transistors, etc.) | 9 |
20080290922 | DELAY CIRCUIT - A delay circuit respectively delays rising and falling edges of an input signal. The delay circuit comprises first and second delay lines, a control circuit, and first and second logic circuits. The first delay line delays the first input signal the first delay time to output the first delay output signal. The second delay line delays the first input signal the second delay time to output the second delay output signal. The control circuit outputs the control signal according to the first input signal. The first logic circuit receives the first delay output signal and outputs the first output signal according to the control signal and the first input signal. The second logic circuit receives the second delay output signal and outputs the second output signal according to the control signal and the first input signal. The first and second delay times are different. | 11-27-2008 |
20090322396 | CIRCUIT TO REDUCE DUTY CYCLE DISTORTION - A method and a circuit for correcting duty cycle distortion. A delay insertion gate corrects data dependent delay distortion that is generated by CMOS flip-flop circuits. The delay insertion gate includes two field effect transistors and a current mirror. The two transistors each respectively receive an input signal from an upstream circuit. At least one of the transistors is coupled to an output node. The output node temporarily holds a voltage state within the delay insertion gate, correcting any distortion in the duty cycle of the input signals. | 12-31-2009 |
20100085098 | DIGITAL DELAY LINE DRIVER - Improved digital delay line driver is described. A delay line driver circuit includes elements to drive the delay line in one or multiple locations to provide a dynamic, adjustable slew rate on the output signal. The delay line driver circuit may also include active elements coupled to the transistors of the delay line to deactivate the delay line transistors substantially simultaneously, rather than cascading in series. Shutting off the delay line transistors substantially simultaneously reduces or eliminates crowbar or shoot through current on an edge transition of the output signal. | 04-08-2010 |
20110304372 | METHOD AND APPARATUS FOR AMPLIFYING A TIME DIFFERENCE - A time amplifier circuit has first and second inverters and first and second pull-down paths. Each inverter includes a first NMOS transistor and a first PMOS transistor. A source of the first NMOS transistor is coupled to a ground node directly or through a first additional NMOS transistor having a gate coupled to a respective input node. The first and second inverters are coupled to first and second input nodes and to first and second output nodes, respectively. The first pull-down path is from the first output node to the ground node and is enabled in response to the first input signal and the second output signal being high. The second pull-down path is from the second output node to ground and is enabled in response to the second input signal and the first output signal being high. | 12-15-2011 |
20130069703 | UNIFORM-FOOTPRINT PROGRAMMABLE-SKEW MULTI-STAGE DELAY CELL - Described embodiments provide a delay cell for a complementary metal oxide semiconductor integrated circuit. The delay cell includes a delay stage to provide an output signal having a programmable delay through the delay cell. The delay cell has a selectable delay value from a plurality of delay values and a selectable output skew value from a plurality of output skew values, where the cell size and terminal layout of the delay cell are relatively uniform for the plurality of delay values and the plurality of output skew values. The delay stage includes M parallel-coupled inverter stages of stacked PMOS transistors and stacked NMOS transistors. The stacked transistors have configurable source-drain connections between a drain and a source of each transistor, wherein the selectable delay value corresponds to a configuration of the configurable source-drain connections to adjust a delay value of each of the M inverter stages and an output skew value of the delay cell. | 03-21-2013 |
20140203859 | SEMICONDUCTOR DEVICE - To provide a semiconductor device capable of adjusting the timing of a clock signal or a high-quality semiconductor device. The semiconductor device includes a first transistor and a circuit including a second transistor. A channel of the first transistor is formed in an oxide semiconductor layer. A first signal is input to one of a source and a drain of the first transistor. The other of the source and the drain of the first transistor is electrically connected to a gate of the second transistor. A first clock signal is input to the circuit. The circuit outputs a second clock signal. The timing of the second clock signal is different from that of the first clock signal. | 07-24-2014 |
20150091628 | GLITCH-FREE INPUT TRANSITION DETECTOR - A circuit for detecting a signal transition on an input signal includes a mirror delay circuit and an input blocking circuit to prevent signal glitches or undesired signal pulses from being passed to the output signal node, thereby preventing signal distortions from being detected as a valid signal transition. The input transition detection circuit generates stable and correct transition detection pulses having a consistent pulse width. | 04-02-2015 |
327265000 | With counter | 1 |
20100295590 | TIME TO DIGITAL CONVERTER - A time to digital converter includes: a delay circuit having a plurality of delay stages that delay an input clock signal in multiple stages, at least one of the delay stages being a variable delay stage; a plurality of flip flops that capture outputs of the delay stages corresponding thereto in a one-to-one relation in response to input of a reference signal; an edge detecting circuit that detects changing edges of respective outputs of the flip flops; a counter circuit that counts a number of edges detected by the edge detecting circuit; and a control circuit that controls a delay amount of the variable delay stage according to the number of edges counted by the counter circuit. | 11-25-2010 |
327266000 | Differential amplifier | 1 |
20100019817 | Current-controlled CMOS (C3MOS) fully differential integrated delay cell with variable delay and high bandwidth - Current-controlled CMOS (C3MOS) fully differential integrated delay cell with variable delay and high bandwidth. A novel implementation includes a wideband differential transistor pair and a cross-coupled differential transistor pair. The wideband differential transistor pair can be implemented with appropriate input and output impedances to extend its bandwidth for use in broadband applications. These two stages, (1) buffer stage (or data amplifier stage) and (2) cross-coupled differential pair stage, are both very fast operating stages. This design does not incur any increased loading to previous or subsequent stages in a device. In addition, there is no increase in the total amount of current that is required. | 01-28-2010 |
327268000 | Having specific passive circuit element or structure (e.g., RLC circuit, etc.) | 2 |
20120268183 | ELECTRONIC OSCILLATION SIGNAL GENERATION CIRCUIT - An electronic oscillation signal generation circuit includes an electronic oscillation circuit, a DC voltage source for providing a DC voltage to the electronic oscillation circuit, a switch for electrically connecting the electronic oscillation circuit to ground when the switch is turned on so as to generate an analog oscillation signal after the switch is turned off, a conversion circuit for converting the analog oscillation signal to a digital oscillation signal, a counter for generating a control signal when the digital oscillation signal reaches a predetermined number of periods, a delay unit for generating a delay signal a predetermined time after a falling edge of the digital oscillation signal is triggered, and a pulse signal generation circuit electrically connected to the counter and the delay unit for generating a pulse signal according to the control signal and the delay signal so as to turn on the switch. | 10-25-2012 |
20130300483 | METHODS AND DEVICES RELATING TO TIME-VARIABLE SIGNAL PROCESSING - Time-Mode Signal Processing (TMSP) offers a means for offsetting some of the challenges for analog circuit designs when exploiting CMOS circuit processes designed for digital applications. It would therefore be beneficial to provide a digital method for the storage, addition and subtraction of Time-Mode variables as these offer significant benefit to providing TMSP techniques and expanding their exploitation within devices, systems, and applications. Whilst driven by CMOS process challenges the TM circuits outlined may exploit essentially any digital circuit technology since they are based upon delay. The inventors present an approach to TM variables wherein a switched delay unit is exploited and adopted such that the instantaneous phase difference between two rising signal edges can be latched and used to perform various arithmetic operations. Beneficially, the technique allows analog sampled-data signal processing to be implemented within digital circuitry. | 11-14-2013 |