Entries |
Document | Title | Date |
20080197901 | Multiple Pulse Width Modulation - A method of generating a MPWM signal for a portable device such as a cellular telephone. For a first duty cycle that includes a MPWM frequency having N magnitude levels, the method generates a first waveform comprising a first and a second On pulse during a first MPWM frequency period. The first and second On pulses are separated by an Off period. | 08-21-2008 |
20080197902 | METHOD AND APPARATUS TO REDUCE PWM VOLTAGE DISTORTION IN ELECTRIC DRIVES - Methods and apparatus are provided for reducing voltage distortion effects at low speed operation in electric drives. The method comprises receiving a first signal having a duty cycle with a range between minimum and maximum achievable duty cycles, producing a second duty cycle based on the minimum achievable duty cycle if the duty cycle is within a distortion range and less than a first clipping value, producing a second duty cycle based on the closer of minimum and maximum pulse widths if the duty cycle is within the distortion range and between the first and a second clipping value, producing a second duty cycle based on the maximum achievable duty cycle if the duty cycle is within the distortion range and greater than the second clipping value, and transmitting a second signal to the voltage source inverter having the second duty cycle. | 08-21-2008 |
20080197903 | Clock Pulse Duty Cycle Control Circuit for a Clock Fanout Chip - A clock pulse duty cycle control circuit for receiving an input clock signal and for providing an output clock signal having a desired duty cycle. An error signal generator includes a differential integrator that is connected to receive the output clock signal. The differential integrator integrates the output clock signal to produce a time-varying DC error signal representative of a difference between the output clock signal duty cycle and the desired duty cycle. A duty cycle corrector includes a differential integrator connected to receive the input clock signal and the error signal. The differential integrator integrates the input clock signa to produce a correction stage clock signal. The differential integrator causes the slopes of the input clock signal edges to be adjusted as a function of the error signal. A buffer including a high gain amplifier is connected to receive the correction stage clock signal and squares the edges of the clock signal to produce the output clock signal. | 08-21-2008 |
20080204097 | INVERTER BASED DUTY CYCLE CORRECTION APPARATUSES AND SYSTEMS - Apparatuses, circuits, and methods to reduce duty cycle errors are disclosed. Embodiments generally comprise buffer circuits coupled with error detection circuits and correction feedback circuits that sense duty cycles errors in output signals from the buffer circuits, generate error signals, and couple the error signals back to the inputs to correct or reduce the duty cycle errors. The error circuits may comprise active low pass filters in various embodiments, while amplifiers generally comprise inverter buffers or other simple buffers which alter or affect the input signals to the buffer circuits in order to reduce the duty cycle errors. In many system and apparatus embodiments, the error circuits comprise a resistor-capacitor circuit coupled with an inverter buffer. The error detection circuits generally function as active low pass filters and generate error signals for the feedback circuits. | 08-28-2008 |
20080204098 | Current sharing for multiphase power conversion - Current sharing scheme based on input power and/or the power efficiency for a power stage with multiple phases and/or paralleled modules is described. According to the scheme, duty cycles of different phases/modules may be adaptively adjusted until the minimum input power and/or the maximum power efficiency is achieved. For certain input voltages, the minimum input power exists at the minimum total input current. Thus, input power and/or the input current may be used as an indicator of the maximized power efficiency of the power stage and hence be used to track the optimal current sharing ratio among the multiple phases/modules. | 08-28-2008 |
20080204099 | Clock generator and clock duty cycle correction method - A clock duty cycle correction (DCC) circuit for correcting a clock duty cycle of an external clock includes a phase comparator for comparing a phase of a rising clock with that of a falling clock to thereby output comparing signal; a DCC controller for outputting a DCC enable signal and a weight selection signal in response to the comparing signal and a first and a second lock state signal; a DCC mixing block for blending the rising clock and the falling clock in response to the DCC enable signal and the weight selection signal to thereby generate a rising and a falling pre-clock signals; and a clock selector for selectively output the rising and the falling pre-clock signals in response to the weight selection signal. | 08-28-2008 |
20080231335 | 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. | 09-25-2008 |
20080238509 | BOUNDING A DUTY CYCLE USING A C-ELEMENT - A duty cycle bounding circuit for restoring the unbounded duty cycle of a periodic signal such as a forwarded clock signal. The duty cycle bounding circuit comprises a state holding logic element, such as a C-element, and a delay line. The delay line feeds back an inverted version of the output of the state holding logic element to an input of the state holding logic element. The periodic signal is applied to another input of the state holding logic element. | 10-02-2008 |
20080246523 | PULSE WIDTH MODULATION WAVE OUTPUT CIRCUIT - A pulse width modulation (PWM) wave output circuit that efficiently and accurately outputs dual PWM waves includes two comparators, an OR circuit, and an AND circuit. A voltage generator supplies the comparators with ramp voltages having the same wave height and shifted phases. The comparator compares the ramp voltages with the reference voltage and provides the comparison results to the OR circuit and the AND circuit. The OR circuit outputs a first modulation wave, and the AND circuit generates a second modulation wave. Accordingly, modulation waves having different duties are output based on ramp voltage having different phases. | 10-09-2008 |
20080246524 | Duty Cycle Correction Circuit Whose Operation is Largely Independent of Operating Voltage and Process - A Duty Cycle Correction (DCC) circuit is provide in which pairs of field effect transistors (FETs) in known DCC circuit topologies are replaced with linear resistors coupled to switches of the DCC circuit such that when the switch is open, the input signal is routed through the linear resistors. The linear resistors are more tolerant of process, voltage and temperature (PVT) fluctuations than FETs and thus, the resulting DCC circuit provides a relatively smaller change in DCC correction range with PVT fluctuations than the known DCC circuit topology that employs FETs. The linear resistors may be provided in parallel with the switches and in series with a pair of FETs having relatively large resistance values. The linear resistors provide resistance that pulls-up or pulls-down the pulse width of the input signal so as to provide correction to the duty cycle of the input signal. | 10-09-2008 |
20080252349 | DUTY CYCLE CORRECTING CIRCUIT - A duty cycle correcting circuit includes a duty ratio control signal generating block that detects a duty ratio of input clock signals and generates a duty ratio control signal comprising a plurality of bits, a power supply block that supplies a voltage to output nodes, and a signal processing block that controls voltage levels of the output nodes to correspond to voltage levels of the input clock signals in response to the plurality of bits of duty ratio control signals. | 10-16-2008 |
20080252350 | CIRCUIT AND METHOD FOR CORRECTING DUTY CYCLE - A circuit for correcting a duty cycle includes a duty ratio digital conversion block configured to output duty ratio information of an input clock signal as plural-bit digital signals, a duty ratio information analyzing block configured to analyze the duty ratio information of the input clock signal, generate edge control signals, and select any one of a plurality of delayed clock signals, and a duty ratio control block configured to control duty ratios of a selected delayed clock signal and the input clock signal in response to the edge control signals. | 10-16-2008 |
20080252351 | Generating a Pulse Signal with a Modulated Duty Cycle - Generating an output pulse signal (Y), which has an output signal period (T | 10-16-2008 |
20080258787 | Power Supply Controller - A parallel circuit | 10-23-2008 |
20080265961 | CLOCK SIGNAL GENERATION CIRCUIT AND SEMICONDUCTOR DEVICE - In a semiconductor device capable of radio communication, a stable clock signal is generated even if a reference clock signal for generating a clock signal has varied frequencies in each cycle. A clock signal generation circuit includes an edge detection circuit that detects an edge of an input signal and generates a synchronization signal, a reference clock signal generation circuit that generates a clock signal which functions as reference, a counter circuit that counts the number of edges of rise of the reference clock signal in accordance with the synchronization signal, a duty ratio selection circuit that selects a duty ratio of a clock signal from a count value, and a frequency division circuit that generates the clock signal having the selected duty ratio. | 10-30-2008 |
20080272814 | PARALLEL MULTIPLEXING DUTY CYCLE ADJUSTMENT CIRCUIT WITH PROGRAMMABLE RANGE CONTROL - A receive interface circuit includes a duty cycle adjustment circuit that adjusts the duty cycle of a reference clock signal based, at least in part, on a selected number of duty cycle adjustment units and a selected range of duty cycle adjustment. The duty cycle adjustment circuit may select as the reference clock signal one of a clock signal and at least a lower version of the clock signal in parallel with the duty cycle adjustment. | 11-06-2008 |
20080272815 | DUTY CYCLE CORRECTION CIRCUITS INCLUDING A TRANSITION GENERATOR CIRCUIT FOR GENERATING TRANSITIONS IN A DUTY CYCLE CORRECTED SIGNAL RESPONSIVE TO AN INPUT SIGNAL AND A DELAYED VERSION OF THE INPUT SIGNAL AND METHODS OF OPERATING THE SAME - A duty cycle correction circuit is operated by maintaining a state of a duty cycle corrected signal, generating a first transition in the state of the duty cycle corrected signal responsive to an input signal, and generating a second transition in the state of the duty cycle corrected signal responsive to a delayed version of the input signal. | 11-06-2008 |
20080278209 | METHOD OF PULSE WIDTH MODULATION SIGNAL PROCESSING AND DEVICE INCLUDING SIGNAL PROCESSING FOR PULSE WIDTH MODULATION - A method and system process a signal for PWM modulation. An amplitude control signal adjusts the amplitude of an input signal, and an offset is added to the amplitude-adjusted signal to produce an offset-adjusted signal. The offset is selected according to the amplitude adjustment applied to the input signal. The offset-adjusted signal is pulse-width modulated the to produce a pulse-width modulated signal, and the pulse-width modulated signal is filtered to reduce high frequency components thereof. | 11-13-2008 |
20080284479 | METHOD OF FORMING A PWM CONTROLLER AND STRUCTURE THEREFOR - In one embodiment, a PWM controller is configured to form a drive signal that has an operating frequency that varies around a center by a percentage of the center frequency. | 11-20-2008 |
20080290920 | DUTY CYCLE CORRECTION CIRCUIT AND METHOD THEREOF - A duty cycle correction circuit comprises a frequency divider, a duty cycle detector and a delay circuit. The frequency divider receives a first clock signal and divides the frequency of the first clock signal to generate a second clock signal. The duty cycle detector receives the second clock signal and a correction clock signal and generates a control signal according to the second clock signal and the correction clock signal. The delay circuit receives the first clock signal and the control signal and adjusts a delay time of a falling edge of the first clock signal according to the control signal to generate the correction clock. | 11-27-2008 |
20080315929 | AUTOMATIC DUTY CYCLE CORRECTION CIRCUIT WITH PROGRAMMABLE DUTY CYCLE TARGET - A duty cycle correcting circuit for an integrated circuit memory automatically corrects the duty cycle of an input clock by measuring the relative difference between the high time and low time of the input signal and using this measurement to achieve a same-frequency, duty cycle adjusted output signal. The duty cycle correcting circuit includes a duty cycle adjust circuit that uses two series-connected N-channel transistors to control the pull-up slew rate of a signal and another N-channel transistor to control the pull-down slew rate of the same signal, two dual-slope integrator circuits, and input and output signal buffering. | 12-25-2008 |
20080315930 | DUTY CYCLE ERROR CALCULATION CIRCUIT FOR A CLOCK GENERATOR HAVING A DELAY LOCKED LOOP AND DUTY CYCLE CORRECTION CIRCUIT - A system and method for generating a correction signal for correcting duty cycle error of a first clock signal relative to a second complementary clock signal. Changes to a time difference between high- and low-portions of the first clock signal are detected and the correction signal is generated in response to and accordance with the detected changes. | 12-25-2008 |
20090002042 | System and method for conditioning differential clock signals and integrated circuit load board using same - A system and method of conditioning differential clock signals iteratively adjusts the duty cycles and phases of the clock signals. The duty cycles of the clock signals are adjusted by comparing respective voltage corresponding to the duty cycles of respective clock signals in each of the differential pairs. The result of the comparison is used to adjust the duty cycles of the clock signal until the magnitudes of the voltages are substantially equal. The phases of the clock signals are adjusted by selecting two sets of two clock signals each that are assigned relative phases that differ from each other by the same amount. The selected sets of clock signals are processed so that the duty cycles of resulting signals correspond to the phases of the clock signals. The duty cycle of these signals is measured as described above and used to adjust the phases of the clock signals. | 01-01-2009 |
20090002043 | System, Method and Apparatus Having Improved Pulse Width Modulation Frequency Resolution - Using a combination of frequency dithering of a PWM counter and a variable time delay circuit yields improved PWM frequency resolution with realizable circuit components and clock operating frequencies. A controllable time delay circuit lengthens a PWM signal during the first PWM cycle. During the second PWM cycle, the PWM period is increased beyond the desired amount, but the delay is reduced during this second PWM cycle to achieve the correct (desired) PWM signal period. The dithering of the PWM signal period enables the time delay circuit to be “reset” so that an infinite delay circuit is not required. The time delay circuit provides short term (one cycle) frequency adjustment so that the resulting PWM cycle is not dithered and has a period at the desired frequency resolution. | 01-01-2009 |
20090015305 | DIGITIZED METHOD FOR GENERATING PULSE WIDTH MODULATION SIGNALS - A digitized method for generating pulse width modulation (PWM) signals is disclosed. In the digitized method, multiphase PWM signals are generated by altering the reference levels so that fully on duty cycle or fully off duty cycle of each phase PWM signal can be achieved. Therefore, the digitized PWM signal generation method in the present invention can be applied to any application apparatus having boost/buck converter. | 01-15-2009 |
20090033393 | METHOD AND APPARATUS FOR REGULATING A DIODE CONDUCTION DUTY CYCLE - A power converter control method and apparatus is disclosed. A control circuit for use in a power converter according to aspects of the present invention includes a clock signal generator coupled to generate a clock signal to control switching of a power switch to be coupled to the control circuit. Feedback circuitry is coupled to receive a feedback signal, which is representative of an output of a power converter during a feedback portion of an off time of the power switch. The feedback circuitry is coupled to respond to the feedback signal to control the clock signal generator to regulate a duty cycle of the feedback portion of the off time of the power switch as a proportion of a total power switch switching cycle period. | 02-05-2009 |
20090051398 | METHOD AND DELAY CIRCUIT WITH ACCURATELY CONTROLLED DUTY CYCLE - A delay locked loop includes a storage element coupled to a data bus and produces a data synchronization signal. A phase detector receives a data clock signal and the data synchronization signal and produces a delay control signal. A first delay circuit produces a signal which is delayed relative to the data clock signal according to the delay control signal. A second delay circuit receiving the delayed signal produces a control signal coupled to a control input of the storage element by delaying the delayed signal an amount which causes the control signal to have a predetermined duty cycle. | 02-26-2009 |
20090058481 | Semiconductor memory device and method for driving the same - A semiconductor memory device has a duty cycle correction circuit capable of outputting a duty cycle corrected clock and its inverted clock having substantially exactly 180° phase difference therebetween. The semiconductor memory device includes a duty cycle corrector configured to receive a first clock and a second clock to generate a first output clock and a second output clock whose duty cycle ratios are corrected in response to correction signals, and a clock edge detector configured to generate the correction signals corresponding to an interval between a reference transition timing of the first output clock and a reference transition timing of the second output clock. | 03-05-2009 |
20090058482 | Duty detection circuit - Semiconductor memory device with duty correction circuit includes a clock edge detector configured to generate first and second detection pulses in response to a transition timing of a common clock signal in an initial measurement operation; a duty detector configured to compare the first and second detection pulses to output comparison result signals; and a code counter configured to control the duty detector based on the comparison signals outputted from the duty detector in the initial measurement operation. | 03-05-2009 |
20090058483 | DUTY CYCLE CORRECTING CIRCUIT AND METHOD - A duty cycle correcting circuit includes a duty detector that detects a duty ratio of an output clock signal to output a duty detection signal, a variable delay unit that outputs a delay clock signal obtained by variably delaying a input signal according to the duty detection signal, and a pulse width modulating unit that generates a first clock signal that is at a high level when both the input clock signal and the delay clock signal are at a high level and generates a second clock signal that is at a high level when any of the input clock signal and the delay clock signal is at a high level, wherein the pulse width modulating unit selectively outputs the first clock signal or the second clock signal as the output clock signal. | 03-05-2009 |
20090066382 | Digital Pulse-Width-Modulator with Discretely Adjustable Delay Line - A hybrid digital pulse width modulator (DPWM) with digital delay-locked loops (DLLs) is provided. In this implementation, the digital pulse-width-modulator is synthesizable and includes a digital delay-locked loop around a delay-line to achieve constant frequency clocked operation. In this implementation, the resolution of the modulator is consistent over a wide range of process or temperature variations. The DPWM may implement trailing-edge, leading-edge, triangular, or phase-shift modulation. In an implementation suitable for DC-DC converters with synchronous rectifiers, for example, the DPWM may include two or more outputs for programmable dead-times. In another implementation, a digital pulse-width-modulator with a digital phase-locked loop is also provided. | 03-12-2009 |
20090066383 | Apparatus and method for generating clock signal - An apparatus, including: a circuit which operates according to a clock signal, the circuit operating with a delay, and a clock generator which generates the clock signal with a duty ratio, the duty ratio being adapted to the delay. | 03-12-2009 |
20090072873 | Circuit Arrangement and Method for the Provision of a Clock Signal with an Adjustable Duty Cycle - The circuit arrangement ( | 03-19-2009 |
20090085624 | FLIP-FLOP CIRCUIT AND DUTY RATIO CORRECTION CIRCUIT USING THE SAME - A flip-flop circuit includes a first unit configured to receive a reference clock signal and a reset signal, and a second unit configured to change an output node to a first level in response to the reference clock signal and change the output node to a second level by precharging the output node in response to a signal output from the first unit according to the reset signal. | 04-02-2009 |
20090091364 | Semiconductor circuit - A semiconductor circuit according to the present invention includes: a differential input section to receive input differential signals; a load resistance section to output a voltage according to a current output by the differential input section; differential signal output terminals to output a differential signal corresponding to the voltage output from the load resistance section; a low-pass filter to extract a direct-current component of the differential signal output from the differential signal output terminals; and a load adjustment section to feed back the direct-current component extracted by the low-pass filter to adjust a resistance value of the load resistance section. | 04-09-2009 |
20090091365 | METHODS FOR GENERATING PWM-SIGNALS - In a method for generating a PWM-signal to drive the power transistors of a half-bridge of a converter with the aid of a digital circuit, a digital reference value is compared to the counter content of a digital counting ramp, and a logic state of the PWM-signal is dependent upon whether the reference value is greater than the counter content of the counting ramp. In this context, at least two counters count counter contents of the counting ramp following one another in alternation, and the logic state of the PWM-signal is dependent upon whether the reference value is greater than the counter contents of counting ramps of each of the at least two counters. | 04-09-2009 |
20090102529 | SHIFTING INACTIVE CLOCK EDGE FOR NOISE REDUCTION - An integrated circuit and a design structure are disclosed. An integrated circuit may comprise: multiple clocked elements; a clock signal source providing clock signals to the multiple clocked elements; and a clock shifting means coupled between the clock signal source and each of the multiple clocked elements; wherein the clock shifting means shifts clock signals of the multiple clocked elements such that the clock signals of the multiple clocked elements have aligned active edges and misaligned inactive edges to reduce the clock noise generated by the inactive edges of the clock signals. | 04-23-2009 |
20090115480 | Clock control circuit and data alignment circuit including the same - A clock control circuit can prevent a malfunction that occurs when a rising strobe signal and a falling strobe signal change in pulse width and thus overlap each other. The clock control circuit which includes a first clock control unit configured to receive a rising strobe signal and a falling strobe signal and output an adjusted rising strobe signal, an enable pulse width of which does not overlap an enable pulse width of the falling strobe signal. | 05-07-2009 |
20090121763 | ADJUSTABLE DUTY CYCLE CIRCUIT - Techniques are disclosed for adjusting and programming the duty cycle of a signal generated by a circuit. In an embodiment, parallel transistors are coupled between a NAND gate and a supply voltage. Selectively enabling the parallel transistors adjusts the switching point of the NAND gate, thereby allowing control of the pulse width of the output signal. In an alternative embodiment, the size of the PMOS versus the NMOS transitors in the NAND gate is selectively varied to achieve the same effect. Further disclosed are applications of the techniques to calibrating the receiver to minimize measured second-order inter-modulation products and/or residual sideband. | 05-14-2009 |
20090128206 | Apparatus and Method for Obtaining Desired Phase Locked Loop Duty Cycle without Pre-Scaler - An apparatus and method for obtaining a desired phase locked loop (PLL) duty cycle without a pre-scaler are provided. The PLL circuit of the illustrative embodiments utilizes two separate loops that simultaneously operate on the VCO. One loop ensures the frequency and phase lock while the other loop ensures the duty cycle lock. The VCO is modified to have an additional control port to adjust the duty cycle. Thus, the VCO has one control port for performing frequency adjustment and one control port for duty cycle adjustment. As a result, both the duty cycle and the frequency may be controlled using the VCO of the PLL circuit of the illustrative embodiments so as to achieve any desired duty cycle output without requiring a VCO pre-scaler circuit or duty cycle correction circuit. | 05-21-2009 |
20090128207 | Clock Circuitry for Generating Multiple Clocks with Time-Multiplexed Duty Cycle Adjustment - Clocking circuitry includes a first clock generator to generate a first clock signal and having a first duty cycle correction input, and a second clock generator to generate a second clock signal and having a second duty cycle correction input. Some embodiments have more than two clock generators. A multiplexer selects between the clock signals from the clock generators. The multiplexer has a first input coupled to the first clock signal and has a second input coupled to the second clock signal, and has a clock output coupled to a clock input of a duty cycle circuit. The duty cycle circuit receives the selected clock signal from the multiplexer and generates a duty cycle correction signal. | 05-21-2009 |
20090128208 | APPARATUS AND METHOD FOR DETECTING DUTY RATIO OF SIGNALS IN SEMICONDUCTOR DEVICE CIRCUIT - Apparatus for detecting duty ratio of signals in semiconductor device circuit includes a circuit for detecting a duty ratio of signals in a semiconductor device includes a comparing unit which compares a duty cycle of first and second input clock signals input differentially and generates a first output signal and a second output signal, a latching unit which stores the first and second output signals and generates a detected signal corresponding to the first and second output signals, and an adjusting unit which receives the first and the second output signals, and transmits the first and the second output signals to the latching unit based on a voltage level difference of the first and second output signals. | 05-21-2009 |
20090140785 | Duty detector and duty cycle corrector including the same - A duty detector includes a clock converter, a hold pulse generator, a first logic operator, and an up/down counter. The clock converter receives a clock signal to generate an up clock signal and a down clock signal having phases opposite to each other. The hold pulse generator generates a hold pulse signal that is deactivated during a counting interval corresponding to first through (N−1)-th period intervals of the clock signal and is activated during a holding interval corresponding to an N-th period interval. The first logic operator outputs a counting clock signal by performing a first logic operation on the hold pulse signal and a sampling clock signal. The up/down counter determines a logic level of the up clock signal and a logic level of the down clock signal at an edge timing of the counting clock signal, increases or decreases a counting value in response to the determination result, and outputs duty information of the clock signal, based on a final counting value. | 06-04-2009 |
20090146715 | DUTY CYCLE CALIBRATION FOR RECEIVER CLOCK - Embodiments of the invention are generally directed to systems, methods, and apparatuses for the direct duty cycle calibration of a receiver clock. In some embodiments, an integrated circuit includes a receive (RX) data path, a RX clock path, and a control path. In some embodiments, the control path uses RX latches, a majority detector, and digital duty cycle control logic to calibrate the duty cycle of the clock signal. Other embodiments are described and claimed. | 06-11-2009 |
20090153208 | Pulse Width Modulation Driver for Electroactive Lens - An electroactive lens driver generates a variable root-mean-square drive voltage for controlling an electroactive lens by controlling the duty cycle of a modified square wave. | 06-18-2009 |
20090160515 | Auto-tracking clock circuitry - A system and method for generating a clock signal is disclosed. In various embodiments of the invention disclosed herein, a global clock signal is generated and provided as an input to local clock circuitry operable to generate a local clock signal therefrom. The local clock circuitry comprises logic components that are susceptible to negative bias thermal instability (NBTI) effects resulting in degradation of the local clock signal. Clock propagation adjustment circuitry is used to modify the duty cycle of the global clock signal to compensate for the degradation resulting from NBTI effects thereby providing an optimized local clock signal. | 06-25-2009 |
20090160516 | DUTY CYCLE CORRECTION CIRCUIT FOR HIGH-SPEED CLOCK SIGNALS - The present invention implements an apparatus for correcting duty cycle distortion in high speed clock signals. The apparatus includes delay cells that delay each of first and second differential initial clock signals. The apparatus further includes a latch that generates an output clock signal based on the delayed first and second differential initial clock signals. The apparatus further includes a differential feedback buffer that converts the output clock signal into first and second differential feedback signals. The apparatus further includes a feedback circuit that adjusts the delay cells based on the first and second differential feedback signals. | 06-25-2009 |
20090195282 | Semiconductor integrated circuit device having standard cell including resistance element - A standard cell includes an input terminal, an output terminal, first and second inverters coupled in series between the input and output terminals, the first inverter including a first transistor of a first conductivity type and a second transistor of a second conductivity type, the first transistor being coupled between a first power source terminal and a first node, and the second transistor being coupled between a second node and a second power source terminal, and a plurality of resistance elements which are used to provide a conductivity path between the first and second nodes, in order to adjust a duty ratio of a signal which passes the standard cell. | 08-06-2009 |
20090195283 | DELAY LOCKED LOOP - The digital duty cycle correction circuit according to the present invention includes a first conversion circuit for buffering an internal clock output from a delay locked loop (DLL), converting the buffered internal clock into first and second clocks through first and second terminals, delaying the second clock according to voltage supplied to the second terminal through a capacitor, converting the delayed second clock into a first signal, and converting the first clock into a third clock, which rises at a falling edge of the first clock and falls at a rising edge of the first signal; and a second conversion circuit for converting the third clock into an output clock, which rises at a falling edge of the third clock and falls at a rising edge of the third clock. | 08-06-2009 |
20090206900 | DUTY CYCLE CORRECTION CIRCUIT AND METHOD FOR CORRECTING DUTY CYCLE - A duty cycle correction circuit capable of reducing current consumption and that includes a back-bias voltage supply circuit for supplying back-bias voltages, wherein a duty cycle of an input clock is reflected on the back-bias voltages; and a buffer for adjusting the duty cycle of the input clock and configured to receive the back-bias voltages. | 08-20-2009 |
20090206901 | DUTY CYCLE CORRECTION CIRCUIT WITH REDUCED CURRENT CONSUMPTION - A duty cycle correction circuit includes a signal generating unit including a first signal generating unit coupled to a power supply voltage terminal and configured to output a complementary output signal of an output signal in response to a clock signal, and a second signal generating unit coupled to the power supply voltage terminal and configured to output the output signal in response to a complementary clock signal of the clock signal; a variable resistor unit coupled between the first and second signal generating units configured to vary an amount of current flowing into the signal generating unit according to a duty correction control signal, the duty correction control signal having a voltage level determined based on a voltage level of the output signal; and a current source coupled between the variable resistor unit and a ground voltage terminal configured to supply current to the signal generating unit. | 08-20-2009 |
20090243684 | METHOD AND DEVICE FOR GENERATING A DIGITAL DATA SIGNAL AND USE THEREOF - In an embodiment, the present invention relates to an integrated circuit comprising at least one data signal input (data | 10-01-2009 |
20090243685 | SIGNAL PROCESSING DEVICE - A signal processing device includes a correction circuit configured to correct the distortion of the duty cycle in a data signal having different occurrence probabilities of 0 and 1. | 10-01-2009 |
20090251184 | DUTY CYCLE CORRECTION CIRCUIT APPARATUS - A duty cycle correction circuit apparatus includes a flip-flop, a feedback unit connected between an input node and an output node of the flip-flop to invert an output signal of the flip-flop and to output the inverted signal as an output signal of the feedback unit, and a selection unit to select and output one of a first clock signal and a second clock signal to the flip-flop in response to the output signal of the feedback unit, wherein the first clock signal has a half-period phase difference with respect to the second clock signal. Using clock signals with a half-period phase difference therebetween and a simple digital circuit, the duty cycle correction circuit can correct a duty ratio to 50:50 regardless of an initial condition. | 10-08-2009 |
20090261877 | Duty cycle correction circuit with wide-frequency working range - A duty cycle correction circuit with wide-frequency working range utilizes a pulse generator having adjustable pulse width function to adjust the width of the pulse and outputs a clock signal with the duty cycle of 50%. The pulse generator includes a NAND gate, a modulation device, and an inverter. The inverter is coupled between the second input end of the NAND gate and the modulation device. The modulation device modulates the low-level status of the input clock signal and accordingly outputs to the inverter. The first input end of the NAND gate receives the input clock signal. The NAND gate operates NAND calculation to the signals received on the input ends of the NAND gate and accordingly outputs a periodic low-level pulse signal. | 10-22-2009 |
20090273382 | CIRCUIT AND METHOD FOR CORRECTING DUTY CYCLE - A circuit configured to correct a duty cycle includes a clock dividing unit configured to delay an input clock signal by a specified delay amount and to generate a plurality of delayed clock signals, a clock selection unit configured to output any one among the plurality of delayed clock signals as a selected delayed clock signal in response to duty ratio information of the input clock signal, an edge control unit configured to generate a falling clock signal by controlling a falling edge of the selected delayed clock signal and to generate a rising clock signal by controlling a falling edge of the input clock signal based on information regarding a difference between lengths of a high duration and a low duration of the input clock signal, and a phase mixing unit for mixing phases of the falling clock signal and the rising clock signal and generating an output clock signal. | 11-05-2009 |
20090284293 | DUTY CORRECTION CIRCUIT - A duty correction circuit includes a duty ratio sensor for controlling a duty ratio sensing speed by a sensing speed control signal and outputting a correction signal by sensing a duty ratio of a clock, and a duty ratio corrector for controlling the duty ratio of the clock in response to the correction signal. | 11-19-2009 |
20090289679 | Duty correction circuit - A duty correction circuit is formed using at least one delay circuit, which is constituted of a first inverter including three transistors of different conduction types and a second inverter including three other transistors of different conduction types and which delays and adjusts an input clock signal at the leading-edge/trailing-edge timing so as to convert it into an output clock signal based on a first or second bias voltage produced by a bias circuit detecting the duty ratio of the output clock signal. The duty correction circuit decreases the high-level period of the output clock signal having a high duty ratio based on the first bias voltage. Alternatively, the duty correction circuit increases the high-level period of the output clock signal having a low duty ratio based on the second bias voltage. | 11-26-2009 |
20090289680 | SEMICONDUCTOR DEVICE - A semiconductor device includes a first duty determining circuit ( | 11-26-2009 |
20090295446 | DUTY CYCLE CORRECTING CIRCUIT AND METHOD OF CORRECTING A DUTY CYCLE - A duty cycle correcting circuit includes a duty ratio control unit configured to alternately change logical values of a plurality of bits of a pull-up control signal and a plurality of bits of a pull-down control signal in response to a duty ratio detection signal, a duty ratio correcting unit configured to adjust driving abilities of a first driver and a second driver in response to the plurality of bits of the pull-up control signal and the plurality of bits of the pull-down control signal to output a correction clock signal, and a duty ratio detecting unit configured to detect a duty ratio of the correction clock to generate the duty ratio detection signal. | 12-03-2009 |
20090302912 | DUTY CYCLE CORRECTION CIRCUIT OF SEMICONDUCTOR MEMORY APPARATUS - A duty cycle correction circuit of a semiconductor memory apparatus includes a duty ratio correcting unit configured to correct a duty ratio of a clock signal according to levels of a first reference voltage and a second reference voltage, and to output the clock signal as a correction clock signal, a duty ratio detecting unit configured to count first and second counting signals in response to a duty ratio of the correction clock signal when a pump enable signal is enabled, a pump enable signal generating unit configured to generate the pump enable signal in response to the duty ratio of the correction clock signal, and a reference voltage generating unit configured to generate the first and second reference voltages in response to the first and second counting signals. | 12-10-2009 |
20100007393 | Method and Apparatus for Achieving 50% Duty Cycle on the Output VCO of a Phased Locked Loop - Described herein are methods and apparatuses for achieving a desired duty cycle on an output of a PLL. According to one embodiment, a method is described, including generating a single ended clock signal from a differential common mode clock signal using a limiting differential amplifier, wherein the single ended clock signal has a duty cycle, generating a differential bias current signal in response to the duty cycle of the single ended clock signal, and correcting the duty cycle of the single ended clock signal to a desired duty cycle by applying the differential bias current signal to the limiting differential amplifier. According to another embodiment, a CML-to-CMOS converter circuit is described, including a limiting differential amplifier for generating a single ended clock signal from a differential common mode clock signal, wherein the single ended clock signal has a duty cycle, a low-pass filter for generating a measurement of the duty cycle of the single ended clock signal, and a second differential amplifier for (i) comparing the measurement with a reference voltage and (ii) generating a differential bias current signal in response to the comparison. | 01-14-2010 |
20100045353 | SELECTIVE EDGE PHASE MIXING - Electronic apparatus, systems, and methods to implement selective edge phase mixing are disclosed. A selective edge phase mixing system includes a processor and memory device configured to perform operations in synchronization with transitions of an externally provided clock signal. A selective edge phase mixing unit for the memory device may include a first logic gate that receives the clock signal at an input port and receives first control signals, and pull-up circuits in communication with an output of the first logic gate and first control signals. A second logic gate receives the clock signal at the input port and receives second control signals. Pull-down circuits are coupled to the second logic gate and the second control signals, wherein the pull-up circuits and the pull-down circuits are coupled to the output port to provide a duty cycle corrected clock signal to the memory device. Additional apparatus, systems, and methods are disclosed. | 02-25-2010 |
20100073057 | DUTY CYCLE CORRECTOR AND CLOCK GENERATOR HAVING THE SAME - A duty cycle corrector includes a delay unit configured to adjust an input clock and an inverted input clock with a delay value controlled in response to one or more control signals and to generate a positive clock and a negative clock, and a duty detector configured to receive the positive clock and the negative clock, to detect duty ratios of the positive clock and the negative clock and to generate the one or more control signals. | 03-25-2010 |
20100073058 | CLOCK/DATA RECOVERY CIRCUIT - A clock/data recovery circuit includes a data duty correction circuit ( | 03-25-2010 |
20100073059 | Duty control circuit and semiconductor device having the same - A duty control circuit including a clock input unit connected to a first node and a second node, the clock input unit receiving an input clock signal through the first node and changing a voltage of the second node to one of a first voltage level and a second voltage level in response to respective low and high logic levels of the input clock signal, a slew controller connected to the second node, the slew controller including one or more switches controlled by respective control signals, the one or more switches providing one of the first voltage level and the second voltage level to the second node in response to the control signals such that a slew rate of a signal at the second node is varied, and a clock output unit, the clock output unit outputting an output clock signal having a duty that varies. | 03-25-2010 |
20100079181 | SAMPLE-POINT ADJUSTMENT IN A SWITCHING CONVERTER - An apparatus and method of generating a drive signal for a switch in a switching converter having input terminals for applying an input voltage, output terminals for providing an output signal, and at least one inductive storage element coupled to the switch. The method includes sampling the output signal to provide a sampled output signal, and generating a pulsewidth modulated drive signal having a duty cycle that is dependent on the sampled output signal, wherein the output voltage is sampled at sampling times that are dependent on the duty cycle. | 04-01-2010 |
20100079182 | METHOD AND APPARATUS FOR COUNTER-BASED CLOCK SIGNAL ADAPTATION - A method and apparatus to implement clock signal adaptation is provided to characterize an input clock signal that is to be adapted and in response, generate adaptation updates at each subsequent clock cycle of the input clock signal. In a first embodiment, clock signal adaptation occurs through duty cycle correction (DCC) to substantially achieve a 50% duty cycle. In an alternate embodiment, clock signal adaptation occurs through a multiplication operation that is applied to the clock signal to be adapted, whereby the multiplication operation is parameterizable to allow odd/even multiplication. In an alternate embodiment, clock signal adaptation occurs through a phase-shift operation that is applied to the clock signal to be adapted, whereby the phase-shift operation is parameterizable to allow all possible fractions and percentages of phase shifts. | 04-01-2010 |
20100085097 | Pulse-Elimination Pulse-Width Modulation - Instead of reducing the pulse widths of all pulses simultaneously in order to reduce the output power of a switched-mode amplifier linearized by a pulse-width modulator, the width of every other (or every n-th) pulse is reduced. When the widths of the selected pulses have been reduced to zero, the amplifier's output power can be further reduced by selecting further pulses from the remaining non-zero-width pulses, and reducing the widths of those pulses. For example, after every other pulse of an original output signal has been removed, every other pulse of the remaining pulses can be reduced to obtain still lower amplifier output power. In this way, the number of pulses (and thus the number of switching transitions) is reduced for small signals, and therefore the amplifier's switching losses are reduced and efficiency is improved. | 04-08-2010 |
20100097112 | DUTY CYCLE CORRECTION CIRCUITS HAVING SHORT LOCKING TIMES THAT ARE RELATIVELY INSENSITIVE TO TEMPERATURE CHANGES - A duty cycle correction circuit includes a duty cycle correction portion that is configured to output a correction signal that is obtained by correcting a duty cycle of an input signal and to output a delayed signal that is obtained by delaying the correction signal, a complementary portion that is configured to output a complementary signal that is the complement of the delayed signal, and a phase interpolator that is configured to phase interpolate the complementary signal and the correction signal. | 04-22-2010 |
20100109729 | DUTY DETECTING CIRCUIT AND DUTY CYCLE CORRECTOR INCLUDING THE SAME - A duty cycle corrector includes a duty adjusting unit configured to adjust a duty cycle of an input clock in response to a duty correction code and generate an output clock, a duty detecting unit configured to measure a difference between a high pulse width and a low pulse width of the output clock and output a difference value, and an accumulating unit configured to accumulate the difference value to generate the duty correction code. | 05-06-2010 |
20100109730 | PWM CONTROL CIRCUIT HAVING ADJUSTABLE MINIMUM DUTY CYCLE - A pulse width modulated (PWM) controller includes a triangle wave generation circuit generating a triangle wave signal to oscillate between an upper limit voltage and a lower limit voltage. The upper limit voltage and the lower limit voltage are adjustable in response to changes in the power supply voltage. A pulse generation circuit is coupled to the triangle wave generation circuit and a minimum duty cycle setting voltage, and is configured to generate a PWM pulse signal with a minimum duty cycle determined by the relative magnitude of the triangle wave signal and the minimum duty cycle reference voltage. In an embodiment, the minimum duty cycle is increased when the power supply voltage is lower than a predetermined reference voltage. | 05-06-2010 |
20100109731 | APPARATUS AND METHOD FOR DUTY CYCLE CORRECTION - There is provided an apparatus for duty cycle correction. The apparatus for duty cycle correction comprises a moving sum unit performing a moving sum calculation with respect to the square-wave signal and outputting the moving sum signal subjected to moving sum calculation, a comparison unit comparing the moving sum signal with a predetermined threshold voltage, outputting a high signal or low signal, a mean value calculation unit calculating the mean value of an output signal outputted from the comparison unit, the output signal being included in a section having a period integer times greater than that of the square-wave signal, and a threshold voltage control unit comparing the mean value with a middle value, increasing the threshold voltage when the mean value is greater than the middle value, and decreasing the threshold voltage when the mean value is less than the middle value. | 05-06-2010 |
20100117702 | DUTY CYCLE CORRECTION APPARATUS AND SEMICONDUCTOR INTEGRATED CIRCUIT HAVING THE SAME - A duty cycle correction apparatus includes a fixed delay unit configured to set a fixed delay time to a DLL clock signal and generate a delay rising clock signal; a variable delay unit configured to delay the DLL clock signal in response to a control signal and generate a delay falling clock signal; a duty cycle correction unit configured to generate a correction rising clock signal and a correction falling clock signal that are toggled in conformity with edge timing of the delay rising clock signal and the delay falling clock signal; and a delay control unit configured to detect duty cycles of the correction rising clock signal and the correction falling clock signal and generate the control signal. | 05-13-2010 |
20100127744 | DUTY CORRECTION CIRCUIT, DUTY CORRECTION SYSTEM, AND DUTY CORRECTION METHOD - A duty correction circuit is provided which includes a level shifter receives complementary differential input signals having a duty ratio and controls levels of the differential input signals; a TrTf control circuit receives output signals of the level shifter and controls edge angles of the output signals; a waveform shaping circuit receives output signals of the TrTf control circuit and shapes waveforms of the output signals; a first common mode comparator extracts common modes of the output signals of the TrTf control circuit and compares the common modes; and a second common mode comparator extracts common modes of output signals of the waveform shaping circuit and compares the common modes. The level shifter controls the levels based on outputs of the first common mode comparator and the TrTf control circuit controls the edge angles based on outputs of the second common mode comparator. | 05-27-2010 |
20100134167 | COMPENSATION OF DEGRADATION OF PERFORMANCE OF SEMICONDUCTOR DEVICES BY CLOCK DUTY CYCLE ADAPTATION - The device degradation of integrated circuits may be compensated for by appropriately adapting the duty cycle of the clock signal. For this purpose, a correlation between the duty cycle and the overall performance characteristics of the integrated circuit may be established and may be used during the normal field operation of the device in order to modify the duty cycle. Hence, an efficient control strategy may be implemented since the duty cycle may be efficiently controlled, while at the same time a change of clock signal frequency and/or an increase of supply voltage may not be required. | 06-03-2010 |
20100134168 | SYSTEM, METHOD AND APPARATUS HAVING IMPROVED PULSE WIDTH MODULATION FREQUENCY RESOLUTION - Using a combination of frequency dithering of a PWM counter and a variable time delay circuit yields improved PWM frequency resolution with realizable circuit components and clock operating frequencies. A controllable time delay circuit lengthens a PWM signal during the first PWM cycle. During the second PWM cycle, the PWM period is increased beyond the desired amount, but the delay is reduced during this second PWM cycle to achieve the correct (desired) PWM signal period. The dithering of the PWM signal period enables the time delay circuit to be “reset” so that an infinite delay circuit is not required. The time delay circuit provides short term (one cycle) frequency adjustment so that the resulting PWM cycle is not dithered and has a period at the desired frequency resolution. | 06-03-2010 |
20100148835 | Duty control buffer circuit and duty correction circuit - The circuit includes a duty control buffer and a duty control voltage generator that receives outputs of the duty control buffer, detects a duty error, and generates control signals. The duty control buffer includes a differential stage including unbalanced first and second differential pairs each differentially receiving input signals, a load element pair connected between output pairs of the first and second differential pairs and a power supply, and a current source stage that supplies respective driving currents to the first and second differential pairs. | 06-17-2010 |
20100156492 | SYSTEM AND METHOD FOR THERMAL LIMIT CONTROL - This disclosure relates to a system and method for pulse generation. A system in accordance with the present disclosure may include a power dissipating element configured to receive power from a power source. At least one of the power source and the power dissipating element may be configured to generate a first signal. The system may further include a measuring instrument in communication with the power source. The measuring instrument may be configured to measure the first signal and to provide an input corresponding to a measured signal to a duty cycle limiter. The system may also include a pulse controller operatively connected to the power source. The pulse controller may be configured to control a duty cycle of the first signal and to receive a second signal from the duty cycle limiter. The pulse controller may be configured to disable at least one of the power source and the power dissipating element if the duty cycle limiter has determined that a maximum condition has been exceeded. Other embodiments are also within the scope of the present disclosure. | 06-24-2010 |
20100164580 | HIGH SPEED CLOCK SIGNAL DUTY CYCLE ADJUSTMENT - A clock signal duty cycle adjustment circuit includes a duty cycle correction circuit that receives a clock input signal that may need duty cycle correction. The duty cycle correction circuit may derive first and second differential clock signals from the clock input signal. The first and second differential clock signals may exhibit respective voltage offsets. The duty cycle correction circuit includes a voltage offset shift circuit that may shift the voltage offset that one of the first and second differential clock signals exhibits to adjust the effective duty cycle of a clock output signal. The duty cycle adjustment circuit derives the clock output signal from the voltage offset adjusted first and second differential clock signals in response to a duty cycle error signal. | 07-01-2010 |
20100164581 | PULSED WIDTH MODULATED CONTROL METHOD AND APPARATUS - A pulse width modulated (PWM) controller has an input terminal for receiving a pulsed input signal having a first duty cycle, a power supply terminal for receiving a power supply voltage. a minimum duty cycle reference voltage signal, and a control circuit for providing a pulse-width-modulated (PWM) output signal having a second duty cycle related to the first duty cycle of the pulsed input signal. The PWM output control signal having a minimum duty cycle that is adjustable in response to a change in the power supply voltage. In an embodiment, the second duty cycle and the first duty cycle are correlated in a substantially linear relationship. In an embodiment, the PWM control circuit also has a triangle wave generation circuit for generating a triangle wave signal configured to oscillate between an upper limit voltage and a lower limit voltage, which are adjustable in response to a change in the power supply voltage. | 07-01-2010 |
20100188126 | Voltage Controlled Duty Cycle and Non-Overlapping Clock Generation Implementation - A method, system and apparatus for controlling the duty cycle of a clock to optimize duty cycle correction and non over-lapping clock generation. The first system generates a reference voltage and one or more clock signals. A comparison is made between the DC level of an output clock and the reference voltage. A correct duty cycle of the clock signal is equal to a predetermined ratio of high time to low time, within an acceptable margin, wherein the ratio of high time to low time is derived from a first resistor and a second resistor. A second system is developed to generate non-overlap clock signals with non-overlap gap control, wherein a reference voltage of a first circuit network is the reference voltage of a second circuit network; thereby generating a single reference signal for the non-overlap circuit network. | 07-29-2010 |
20100207675 | Semiconductor device - A device includes a first circuit unit performing a detecting operation to detect a ratio of a first time period in which an input signal takes a first logic level to a second time period in which the input signal takes a second logic level. The first circuit unit includes a storing unit and storing a detection result of a detection thereby to the storing unit thereof. The device includes a first control circuit controlling the first circuit unit in response to the input signal. The device includes a current source circuit coupled to the first control circuit at a first circuit node thereof. The device includes an initialization circuit performing an initializing operation to initialize the detection result of the storing unit of the first circuit unit. The device includes a second control circuit controlling the first control circuit such that a voltage level of the first circuit node at a timing at which the initializing operation is terminated is equal to the voltage level of the first circuit node in the detecting operation following the initializing operation. | 08-19-2010 |
20100219870 | DUTY RATIO CORRECTION CIRCUIT AND DUTY RATIO CORRECTION METHOD - A duty ratio correction circuit includes a clock input buffer that receives a first clock signal, a clock duty adjuster that adjusts a duty ratio of a second clock signal output from the clock input buffer based on a correction signal and generates a third clock signal, a data input buffer that receives a first data signal, a data duty adjuster that adjusts a duty ratio of a second data signal output from the data input buffer based on the correction signal and generates a third data signal, and a duty comparator that generates the correction signal based on the third clock signal. | 09-02-2010 |
20100225372 | DUTY CYCLE CORRECTION SYSTEMS AND METHODS - Duty cycle correction systems and methods of adjusting duty cycles are provided. One such duty cycle correction system includes a duty cycle adjustor and a variable delay line coupled to the output of the duty cycle adjustor. First and second phase detectors have first inputs coupled to the output of the duty cycle adjustor through an inverter and second inputs coupled to the output of the variable delay line. The phase detectors cause the delay line to align rising or falling edges of signals at the output of the delay line with rising or falling edges, respectively, of signals at the output of the inverter. The controller simultaneously causes the duty cycle adjustor to adjust the duty cycle of the output clock signal until the rising and falling edges of signals at the output of the delay line are aligned with rising and falling edges, respectively, of signals at the output of the inverter. | 09-09-2010 |
20100253407 | APPARATUS AND METHOD OF GENERATING REFERENCE CLOCK FOR DLL CIRCUIT - An apparatus for generating a reference clock for a DLL circuit includes a buffering unit configured to buffer an external clock so as to generate a first reference clock and a second reference clock, and to invert the second reference clock so as to generate a negative second reference clock. A duty cycle compensating unit generates a reference clock from the first reference clock and the negative second reference clock. | 10-07-2010 |
20100259308 | Clock Circuit and Method for Pulsed Latch Circuits - Circuits and methods for providing a pulsed clock signal for use with pulsed latch circuits are described. A variable pulse generator is coupled to form a pulsed clock output responsive to a control signal and a clock input signal. A feedback loop is provided with a pulse monitor and a pulse control circuit. Samples of the pulsed clock signal are taken by the pulse monitor and an output is formed in the form of a pattern. The pulse control circuit receives the output of the monitor and determines whether it matches a predetermined pattern. Adjustments are made to the control signal to adaptively adjust the pulsed clock signal. The feedback loop may operate continuously. In alternative embodiments the feedback loop may be powered down. Methods for adaptively controlling a pulsed clock signal are disclosed. | 10-14-2010 |
20100271098 | LOW-OFFSET CHARGE PUMP, DUTY CYCLE STABILIZER, AND DELAY LOCKED LOOP - A charge pump circuit can include a first pair of transistors having connected sources and gates configured to receive a first pump signal and an inverse first pump signal and a second pair of transistors having connected drains and gates configured to receive a second pump signal and an inverse second pump signal, sources of the second pair of transistors being connected to drains of the first pair of transistors at first and second connection nodes, wherein the first and second pair of transistors are all of the same transistor type and provide an output current in response to the first and second pump signals. The charge pump circuit can also include a voltage stabilizer circuit connected to the second connection node and configured to regulate the second connection node to have a voltage within a predetermined range about a selectable voltage. Duty cycle stabilizers and control loops such as delay locked loops can include the charge pump circuit. | 10-28-2010 |
20100277214 | DEVICE AND METHOD FOR SIGNAL GENERATION - A signal generator and a method thereof for generating signals are provided. The signal generator includes a pulse width signal generation module and a signal generating module. The pulse width signal generation module generates a first pulse width signal according to a first pulse signal and a second pulse signal. A first signal with a first duty ratio is generated by the signal generating module based on the first pulse width signal. The first duty ratio is equal to a product of a duty ratio of the first pulse signal and a duty ratio of the second pulse signal. | 11-04-2010 |
20100283522 | ALL-DIGITAL SELECTABLE DUTY CYCLE GENERATION - All-digital techniques for generating periodic digital signals having selectable duty cycles. In one aspect, a computation block is provided for computing the product of a selected duty cycle and a discrete ratio between a reference clock period and a high-frequency oscillator period. The computation block may be coupled to a pulse width generator for generating signals having pulse widths that are integer multiples of the high-frequency oscillator period. In another aspect, a pulse width generator may also accommodate mixed fractional multiples of high-frequency oscillator periods by tapping the individual inverter stages of a delay line matched to the individual inverter stages of a ring oscillator exemplary embodiment of the high-frequency oscillator. | 11-11-2010 |
20100289547 | PULSE-WIDTH MODULATION (PWM) WITH INDEPENDENTLY ADJUSTABLE DUTY CYCLE AND FREQUENCY USING TWO ADJUSTABLE DELAYS - A pulse width modulation circuit may generate an adjustable output signal that periodically transitions between a first and a second state with an adjustable duty cycle. A first pulse generator circuit may be configured to generate a first pulse signal that periodically transitions at an adjustable delay with respect to a periodic reference signal. A second pulse generator circuit may be configured to generate a second pulse signal that periodically transitions at an adjustable delay with respect to the periodic reference signal. A logic circuit may be configured to generate the adjustable output signal based on both the first and the second pulse signals. | 11-18-2010 |
20100301913 | CMOS Clock Receiver with Feedback Loop Error Corrections - A system for correcting duty cycle errors in a clock receiver that includes a differential amplifier having inputs for a pair of differential clock signals. A duty cycle error detector has inputs for a pair of amplified clock signals and an output for a duty cycle error correction signal. A signal conditioner is also provided with the differential amplifier having an input for the duty cycle error correction signal. Furthermore, the signal conditioner adjusts the differential clock signals in response to the duty cycle error correction signal. Also, a system for correcting cross point errors in a clock receiver that includes a differential amplifier having inputs for a pair of differential clock signal. A cross point error detector has inputs for a pair of amplified clock signals and an output for a cross point error correction signal. A signal conditioner is also provided with the differential amplifier having an input for the cross point error correction signal. Furthermore, the signal conditioner adjusts the differential clock signals in response to the cross point error correction signal. | 12-02-2010 |
20100315143 | CIRCUIT AND METHOD FOR REDUCING POPPING SOUND - A circuit for reducing popping sound comprises a waveform generator, a voltage accumulator, and a comparator. The waveform generator is configured for generating a periodic waveform, and the voltage accumulator is configured for generating an increased voltage. The comparator is configured for comparing the periodic waveform with the increased voltage for generating a successive pulse signal. A percentage of a duty cycle in the successive pulse signal is increased gradually. | 12-16-2010 |
20100327929 | PREDETERMINED DUTY CYCLE SIGNAL GENERATOR - Techniques for generating a signal having a predetermined duty cycle. In an exemplary embodiment, a first counter is configured to count a first number of cycles of an oscillator signal, and a second counter is configured to count a second number of cycles of the oscillator signal, with the second number being greater than the first number. The output of the second counter is used to reset the first and second counters, while the outputs of the first and second counters further drive a toggle latch for generating the signal having predetermined duty cycle. Further aspects include techniques for accommodating odd and even values for the second number. | 12-30-2010 |
20110001532 | SEMICONDUCTOR DEVICE - A semiconductor device includes a phase division unit, a clock delay unit, a duty cycle correction clock generation unit, and a duty cycle correction voltage generation unit. The phase division unit is configured to divide a phase of a source clock to generate a first division clock. The clock delay unit is configured to delay the first division clock by a delay amount corresponding to a voltage level of a duty cycle correction voltage to output a second division clock. The duty cycle correction clock generation unit is configured to generate a duty cycle correction clock whose logic level changes at respective edges of the first division clock and the second division clock. The duty cycle correction voltage generation unit is configured to generate the duty cycle correction voltage whose voltage level changes depending on a duty cycle of the duty cycle correction clock. | 01-06-2011 |
20110006824 | WAKE-UP RECEIVER AND WAKE-UP METHOD USING DUTY CYCLING AND POWER OFF TECHNIQUE - Provided is a low-power wake-up receiver that is sensitive to electric waves, by which power consumed by a radio frequency (RF) transceiver of a sensor node in a ubiquitous sensor network (USN) is minimized. A wake-up receiver waking up a main transceiver includes a duty cycle signal generation unit controlling a duty cycle of a duty cycle signal; a burst signal detection unit receiving an input signal including a burst signal and a data signal based on the duty cycle signal, amplifying the input signal, and, if the amplified input signal is the burst signal, outputting a control signal; and a data signal detection unit re-amplifying the amplified input signal based on the control signal, and, if the re-amplified input signal is the data signal, outputting a wake-up signal. Power supplied to the duty cycle signal generation unit is interrupted based on the control signal and power is re-supplied to the duty cycle signal generation unit based on the wake-up signal. | 01-13-2011 |
20110025392 | Duty cycle correction method and its implementing circuit - A duty cycle correction method comprises detecting independently a relative delay time of two input differential signals; equating the sum of two relative delay time with the cycle of the input differential signals; and adjusting the two delay time to the same value. A corresponding implementation circuit comprises two time delay units; two correlation phase detectors connecting simultaneously with each of the two time delay units; a charge pump connecting with the output of each of the two correlation phase detectors, with its output connecting to the two time delay units in order to form a loop; and a synthesis output unit connecting with both the time delay units, thereby generating output signals. The adjusting range of duty cycle becomes much wider. The implementation circuit is absolutely symmetrical, so a duty cycle with high accuracy can be obtain. | 02-03-2011 |
20110050307 | CIRCUITS AND METHODS FOR CLOCK SIGNAL DUTY-CYCLE CORRECTION - Duty-cycle correction circuits, clock distribution networks, and methods for correcting duty-cycle distortion are disclosed, including methods and apparatus for correcting duty-cycle distortion of differential output clock signals provided from a clock distribution network. In one such method, a single-ended clock signal is generated from differential input clock signals for distribution over a clock distribution network and from which the differential output clock signals are generated. A delay of a model delay path is matched to a propagation delay of the clock distribution network, and the single ended clock signal is adjusted to compensate for duty-cycle distortion. | 03-03-2011 |
20110063007 | DELAY CIRCUIT WITH DELAY EQUAL TO PERCENTAGE OF INPUT PULSE WIDTH - A delay circuit with a delay equal to the percentage of the input pulse width is described. In one embodiment, the ratio of the discharge current to the charge-up current of a timing capacitor is used to determine the percentage of the input pulse width used for the output delay. In a first timing phase, the input pulse width is stored as a voltage on the timing capacitor. In a second timing phase, the output is delayed by a percentage of the input pulse width. In a third timing phase, the circuit is restored to the trip point to remove sensitivity to process variation or applied conditions variation such as voltage or temperature (P-V-T variation), and be ready for the next timing cycle. | 03-17-2011 |
20110089986 | METHOD AND APPARATUS FOR PULSE WIDTH MODULATION - An apparatus and method of providing a pulse width modulated signal that is responsive to a current are disclosed. A circuit according to aspects of the present invention includes a capacitor to convert a first current to a first voltage on the capacitor during a first time duration and to discharge a second current from the capacitor to change the first voltage to a second voltage during a second time duration. A comparator is also included and is coupled to an output of the capacitor to compare a voltage on the capacitor to a reference voltage during the second time duration to change a pulse width of a periodic output signal in response to an input current. | 04-21-2011 |
20110102038 | DUTY RATIO CONTROL APPARATUS AND DUTY RATIO CONTROL METHOD - There are provided a duty ratio control apparatus for altering a duty ratio of a clock signal to output an altered clock signal, including a first variable delay section that outputs a first delayed clock signal generated by delaying the clock signal by a predetermined first delay time, and a phase comparing section that compares, in terms of phase, an edge of the clock signal and an edge of the first delayed clock signal and generates the altered clock signal having a pulse width determined by a phase difference obtained by the comparison, and a duty ratio control method. | 05-05-2011 |
20110102039 | APPARATUS AND METHOD FOR CORRECTING DUTY CYCLE OF CLOCK SIGNAL - A clock correction circuit includes a delay locked loop (DLL) configured to delay an external clock signal and to generate an internal clock signal, a first duty cycle correction (DCC) unit configured to correct a duty cycle of the external clock signal in response to a first duty cycle code, a second DCC unit configured to correct a duty cycle of the internal clock signal in response to a second duty cycle code, and a duty cycle code generation unit configured to select an output of from outputs of the first and second DCC Units and to generate the first and second duty cycle codes by detecting a duty cycle ratio of the selected output. | 05-05-2011 |
20110102040 | SEMICONDUCTOR DEVICE - A semiconductor device includes: a voltage-control-type clock generation circuit having a plurality of stages of first delay elements and whose oscillation frequency is controlled according to a control voltage applied to the first delay elements; a delay circuit having a plurality of stages of second delay elements connected serially; and a selection circuit selecting one from pulse signals output by the plurality of stages of respective second delay elements. The first delay elements and the second delay elements have a same structure formed on a same semiconductor substrate, and a delay amount of the second delay elements is adjusted according to the control voltage. | 05-05-2011 |
20110128059 | DUTY CORRECTION CIRCUIT - A duty correction circuit is presented for use in compensating for a duty rate error brought about when a malfunction of a clock signal generator or a failure of a signal transmission line occurs. The duty correction circuit is configured to select one of differential signals as an input signal according to a duty rate. The duty correction circuit is also configured to combine the input signal and a signal obtained by delaying the input signal by a delay time adjusted in accordance to the duty rate. The duty correction circuit is also configured to generate the combined signal as a duty correction signal. | 06-02-2011 |
20110163789 | DUTY CYCLE CORRECTION CIRCUIT AND METHOD FOR CORRECTING DUTY CYCLE AND SEMICONDUCTOR DEVICE INCLUDING THE DUTY CYCLE CORRECTION CIRCUIT - Provided are a duty cycle correction circuit and method for correcting a duty cycle, and a semiconductor device including the duty cycle correction circuit. The duty cycle correction circuit includes a code generator configured to generate a first and a second duty code for adjusting the duty cycle of a clock to a target duty cycle, and a duty cycle corrector including a plurality of inverter circuits connected in series and whose driving capabilities are adjusted in response to the first and second duty code, wherein the duty cycle corrector is configured to correct the duty cycle of the clock based on the driving capabilities of the inverter circuits and to output a corrected clock. | 07-07-2011 |
20110175657 | DUTY CYCLE CORRECTION CIRCUIT FOR MEMORY INTERFACES IN INTEGRATED CIRCUITS - Circuits and a method for correcting duty cycle distortions in an integrated circuit (IC) are disclosed. The IC includes a splitter circuit that is coupled to receive a clock signal. The clock signal is split into two different clock signals. One of the clock signals is an inverted version of the other. A delay circuit is coupled to each of the clock signals. Each of the delay circuits generates a delayed version of the corresponding clock signal. A corrector circuit is coupled to receive both the delayed versions of the clock signals. The corrector circuit generates a clock output signal with a corrected duty cycle. | 07-21-2011 |
20110193605 | DUTY TRANSITION CONTROL IN PULSE WIDTH MODULATION SIGNALING - A pulse width modulation (PWM) signal generator generates a PWM signal with an adjustable PWM duty based on a programmable or otherwise adjustable value. In response to a change or update to this value, the PWM signal generator initiates a duty transition process that generates a series of groups of PWM cycles that gradually transition from the original duty to the new duty. Each group includes a corresponding set of a predetermined number of PWM cycles that is repeated one or more times over a predetermined duration for the group. Each set has a certain proportion of PWM cycles having the new duty to PWM cycles having the original duty, whereby the proportion increases for each successive group of the series. This gradual transition in the PWM signal from the original duty to the new duty effectively provides an effective higher duty resolution for the PWM signal generator during the duty transition. | 08-11-2011 |
20110204948 | DUTY CYCLE CORRECTION SYSTEMS AND METHODS - Duty cycle correction systems and methods of adjusting duty cycles are provided. One such duty cycle correction system includes a duty cycle adjustor and a variable delay line coupled to the output of the duty cycle adjustor. First and second phase detectors have first inputs coupled to the output of the duty cycle adjustor through an inverter and second inputs coupled to the output of the variable delay line. The phase detectors cause the delay line to align rising or falling edges of signals at the output of the delay line with rising or falling edges, respectively, of signals at the output of the inverter. The controller simultaneously causes the duty cycle adjustor to adjust the duty cycle of the output clock signal until the rising and falling edges of signals at the output of the delay line are aligned with rising and falling edges, respectively, of signals at the output of the inverter. | 08-25-2011 |
20110227623 | DUTY CYCLE CORRECTING CIRCUIT AND DUTY CYCLE CORRECTING METHOD - A duty cycle correcting circuit includes a first duty ratio correcting unit that widens a high-level period of an input clock in response to a detection signal, thereby correcting a duty ratio of the input clock to output a first corrected clock. A second duty ratio correcting unit narrows the high-level period of the input clock in response to the detection signal, thereby correcting the duty ratio of the input clock to output a second corrected clock. A clock selecting unit selectively outputs the first corrected clock or the second corrected clock as an output clock in response to the detection signal. A duty ratio detecting unit detects a duty ratio of the output clock, thereby generating the detection signal. | 09-22-2011 |
20110227624 | DUTY CYCLE CORRECTION CIRCUIT - A duty cycle correction circuit comprises first and second pulse generators, a clock dividing unit, a detecting unit, and a pulse width control unit. The first pulse generator is configured to generate a first edge of a first pulse signal in synchronization with a first edge of a first clock signal, and the second pulse generator is configured to generate a first edge of a second pulse signal in synchronization with a second edge of the first pulse signal. The clock dividing unit is configured to generate a second clock signal by dividing the frequency of the first clock signal. The detecting unit is configured to generate a detecting signal according to the second clock signal and a time interval between the first edge of the first pulse signal and a second edge of the second pulse signal. In particular, pulse widths of the first and second pulse signals are the same and are adjustable according to a control signal from the pulse width control unit. | 09-22-2011 |
20110267123 | CLOCK DUTY CORRECTION CIRCUIT - A clock duty correction circuit includes a first current sourcing unit that sources a current to a current path in response to a clock signal, a first current sinking unit that sinks the current of the current path in response to the clock signal, a second current sourcing unit that sources a current to the current path in response to a delay clock signal obtained by delaying the clock signal by a predetermined time, a second current sinking unit that sinks the current of the current path in response to the delay clock signal, a current adjustment unit that adjusts an amount of the current flowing through the current path according to a voltage level of a control voltage, and a clock output unit that outputs an output clock signal having a voltage level corresponding to the amount of the current flowing through the current adjustment unit. | 11-03-2011 |
20110267124 | CLOCK SIGNAL DUTY CORRECTION CIRCUIT - A clock signal duty correction circuit includes: a first transition timing control unit configured to generate a first control signal for controlling a rising timing of a duty correction clock signal by using a clock signal; a second transition timing control unit configured to generate a second control signal for varying a falling timing of the duty correction clock signal by using the clock signal according to a code signal; and a differential buffer unit configured to generate the duty correction clock signal, whose rising time or falling time is adjusted, in response to the first control signal and the second control signal. | 11-03-2011 |
20110273211 | CIRCUIT AND METHOD FOR PROVIDING A CORRECTED DUTY CYCLE - A duty cycle correction circuit comprises a duty cycle detector, a filter, an amplifier, a charge pump, a control circuit, and a duty cycle corrector. The duty cycle detector is configured to generate a first pair of control signals according to a pair of internal clock signals. The filter is configured to obtain average voltages of the first pair of control signals. The amplifier is configured to compare output voltages of the filter for generating an enable signal, and the control circuit is configured to generate a selection signal according to the enable signal. The charge pump is configured to generate a second pair of control signals according to the enable signal and the selection signal, and the duty cycle corrector is configured to receive a pair of external clock signals, the first pair of control signals, and the second pair of control signals for generating the pair of internal clock signals with a corrected duty cycle. | 11-10-2011 |
20110273212 | SELECTIVE EDGE PHASE MIXING - Electronic apparatus, systems, and methods to implement selective edge phase mixing are disclosed. A selective edge phase mixing system includes a processor and memory device configured to perform operations in synchronization with transitions of an externally provided clock signal. A selective edge phase mixing unit for the memory device may include a first logic gate that receives the clock signal at an input port and receives first control signals, and pull-up circuits in communication with an output of the first logic gate and first control signals. A second logic gate receives the clock signal at the input port and receives second control signals. Pull-down circuits are coupled to the second logic gate and the second control signals, wherein the pull-up circuits and the pull-down circuits are coupled to the output port to provide a duty cycle corrected clock signal to the memory device. Additional apparatus, systems, and methods are disclosed. | 11-10-2011 |
20110279159 | CIRCUITS AND METHODS FOR CLOCK SIGNAL DUTY-CYCLE CORRECTION - Duty-cycle correction circuits, clock distribution networks, and methods for correcting duty-cycle distortion are disclosed, including methods and apparatus for correcting duty-cycle distortion of differential output clock signals provided from a clock distribution network. In one such method, a single-ended clock signal is generated from differential input clock signals for distribution over a clock distribution network and from which the differential output clock signals are generated. A delay of a model delay path is matched to a propagation delay of the clock distribution network, and the single ended clock signal is adjusted to compensate for duty-cycle distortion. | 11-17-2011 |
20110285441 | CLOCK ADJUSTMENT CIRCUIT, SHIFT DETECTION CIRCUIT OF DUTY RATIO, IMAGING DEVICE AND CLOCK ADJUSTMENT METHOD - A clock adjustment circuit includes: first and third switching elements to be in a conductive state when in-phase and reverse-phase clock signals in a high level are applied to input terminals, respectively; second and fourth switching elements whose input terminals are connected to output terminals of the first and third switching elements, respectively, which become in the conductive state when the in-phase and reverse-phase clock signals in a low level are applied to output terminal, respectively; first and second capacitor elements whose one terminal is connected to an output terminal of the first and third switching element, respectively; and a shift detection unit detecting potential difference between the output terminals of the first and third switching elements and outputs the detection signal as a signal for adjusting a duty ratio of the clock signal. | 11-24-2011 |
20110291724 | DUTY CYCLE CORRECTION CIRCUIT - A duty cycle correction circuit for correcting the duty cycle of a clock signal generated by a clock generator includes a complementary buffer chain, level shifter circuits and a self-bias circuit. A clock signal with a distorted duty cycle and its complement are provided to the level shifter circuits. The level shifter circuits reduce the magnitude of voltage of the clock signal and the complement and generate level shifted signals. The level shifted signals are provided to a differential amplifier that generates a control signal indicating the magnitude of distortion in the duty cycle. The control signal is used to correct the duty cycle of the clock signal. The self-bias circuit is used to bias the differential amplifier. | 12-01-2011 |
20110291725 | DUTY DETECTION CIRCUIT AND DUTY CYCLE CORRECTION CIRCUIT INCLUDING THE SAME - A duty cycle correction circuit includes a duty adjustment circuit configured to generate an output clock by adjusting a duty cycle of an input clock in response to a duty adjustment code, a duty detection circuit configured to measure a difference between a width of a high pulse and a width of a low pulse of the output clock at each update period, and generate a duty detection code corresponding to the measured value, an accumulation circuit configured to generate the duty adjustment code by accumulating a value of the duty detection code outputted at each update period, and a toggling number adjustment circuit configured to adjust a toggling number of the output clock, which adjustment determines the update period, according to a frequency of the output clock. | 12-01-2011 |
20110291726 | DUTY CORRECTING CIRCUIT, DELAY-LOCKED LOOP CIRCUIT INCLUDING THE CIRCUIT, AND METHOD OF CORRECTING DUTY - A duty correcting circuit includes a duty steerer circuit, a differential clock generator, and a charge pump circuit. The duty steerer circuit corrects a duty cycle of an input clock signal in response to a duty control signal and generates an output clock signal. The differential clock generator generates two internal clock signals having a phase difference of 180° from each other based on the output clock signal. The charge pump circuit performs a charge pump operation in a differential mode in response to the internal clock signals to generate a duty control signal. | 12-01-2011 |
20110298513 | DUTY CORRECTING CIRCUIT, DELAY-LOCKED LOOP CIRCUIT AND METHOD OF CORRECTING DUTY - The duty correcting circuit includes a duty cycle corrector, a duty detector and a duty correction code generator. The duty cycle corrector corrects a duty cycle of an input clock signal to generate an output clock signal. The duty detector adjusts a delay time of the output clock signal to generate a sampling clock signal, samples the output clock signal in response to the sampling clock signal to generate sample data, and detects a duty of the output clock signal based on logic states of the sample data. Therefore, the duty correcting circuit precisely detects and corrects a duty of the output clock signal. | 12-08-2011 |
20110304371 | INTEGRATED CIRCUITS WITH DUAL-EDGE CLOCKING - Integrated circuits that support dual-edge clocking are provided. Integrated circuits may include phase-locked loops that generate square-wave clock signals. The clock signals may be provided from off-chip equipment through input-output pins. The clock signals may be routed through a clock distribution network to provide local clock signals to pulse generators that generate clock pulses on rising and falling clock edges. The pulse generators may generate clock pulses that are triggered by the rising and falling clock edges with a common pulse width for optimum performance. Duty cycle distortion introduced by the clock network may be minimized for optimum performance. Adaptive duty cycle distortion circuitry may be used to control the pull-up/pull-down drive strengths of the clock buffer so that the high clock phase of the local clock signals is approximately a half clock cycle. | 12-15-2011 |
20110309869 | DUTY CYCLE CORRECTION IN A DELAY-LOCKED LOOP - Circuits, methods, and apparatus that provide duty-cycle error correction for clock and other periodic signals. One example provides a duty-cycle correction that can be used to improve the duty cycle of a clock signal that is received by, or generated by, a delay-locked loop. This example receives an input clock signal and uses a variable delay element to construct an improved duty-cycle output clock signal. The duty cycle of the output clock is examined to determine if the delay element is providing excess or insufficient delay. The delay of the delay element is then adjusted. To improve response times, a successive approximation technique is used to determine the most significant bits of a count that adjusts the delay through the delay element. To improve accuracy, a linear technique is used to adjust the least significant bits of the count. | 12-22-2011 |
20110316603 | DUTY COMPENSATION CIRCUIT - A duty compensation circuit including a duty detection circuit, a duty adjustment signal generator for generating a control signal from a detected duty, and a duty adjustment circuit, in which the duty detection circuit executes sampling of a clock at sampling timing obtained by causing the clock to be delayed by a variable delay circuit, thereby detecting a duty. Thereby, duty compensation is enabled without preparing a clock higher in operating speed than a clock before compensation. | 12-29-2011 |
20120007647 | DUTY CYCLE CORRECTION CIRCUIT - A duty cycle correction (DCC) circuit includes a duty signal generating unit configured to compare a high duration of an output clock with a low duration of the output clock in a clock cycle to generate a duty signal, a counting unit configured to count and output a preliminary code after a duty cycle correction (DCC) operation starts, a duty code generating unit configured to generate a duty code by selectively inverting or transferring without inversion the preliminary code in response to an initial value of the duty signal, and a duty cycle correcting unit configured to output the output clock by driving an input clock to a pull-up driving capacity and a pull-down driving capacity which are determined in response to the initial value of the duty signal and the duty code. | 01-12-2012 |
20120019299 | Clock Signal Correction - In one embodiment, a method includes generating two or more clock signals, sequentially selecting each one of the clock signals, and adjusting the respective clock duty cycle of the selected one of the clock signals until it substantially matches a predetermined clock duty cycle. The adjustment of the respective clock duty cycle includes generating a control signal based on the respective clock duty cycle, generating a duty-cycle-distortion (DCD) correction signal based on the control signal, adjusting the respective clock duty cycle of the selected one of the clock signals based on the DCD correction signal, and adjusting the control and DCD correction signals and re-adjusting the respective clock duty cycle of the selected one of the clock signals until the respective clock duty cycle of the selected one of the clock signals substantially matches the predetermined clock duty cycle. | 01-26-2012 |
20120038404 | DUTY CYCLE BASED PHASE INTERPOLATORS AND METHODS FOR USE - Duty cycle based phase interpolators, and methods for implementing duty cycle based phase interpolators are disclosed. One such phase interpolator includes a first pulse width modulator configured to generate a first duty cycle signal, and a second pulse width modulator configured to generate a second duty cycle signal. The phase interpolator further includes a logic unit configured to merge the first duty cycle signal and the second duty cycle signal to produce a periodic digital signal with a controllable phase depending on the first and second duty cycle signals. | 02-16-2012 |
20120081163 | RF DUTY CYCLE CORRECTION CIRCUIT - A duty-cycle correction circuit comprises a plurality of AC-coupled, independently-biased inverter stages connected in series. A periodic signal is applied to an input of the plurality of inverter stages. Each inverter stage comprises an inverter with a resistive element connected in feedback between its output and input nodes. Each inverter stage is AC-coupled to a prior stage via a capacitor. The AC-coupling allows the signal to pass between inverter stages, but DC-isolates each inverter stage from adjacent stages, allowing each stage to maintain an independent DC bias of the signal at that stage. By virtue of the feedback resistive element, each stage defines a transition point between high and low signal states. Due to non-zero rise and fall times of the periodic signal, the independent DC bias of each stage is operative to incrementally shift the transition point of the periodic signal at each stage towards a desired duty-cycle. | 04-05-2012 |
20120086488 | DIFFERENTIAL AMPLIFIERS, CLOCK GENERATOR CIRCUITS, DELAY LINES AND METHODS - A differential amplifier may be configured to have a duty cycle and/or gain that is adjustable, such as by adjusting the switch points of circuitry in the differential amplifier. The differential amplifier may alternatively or additionally have a hysteresis function by, for example, using a signal feedback from the output of the amplifier to adjust the switch points of circuitry in the differential amplifier. The differential amplifier may be used for a variety of purposes, such as in an input buffer or delay line, either of which may be used, for example, in a clock generator circuit. | 04-12-2012 |
20120086489 | ADAPTIVE QUADRATURE CORRECTION FOR QUADRATURE CLOCK PATH DESKEW - Quadrature clocking schemes are widely used in modern communications systems, but often suffer from phase imbalance. Conventional solutions that attempt to address this phase imbalance, however, are generally large and use a substantial amount of power. Here, however, a correction circuit is provided that can locally correct for phase imbalance without the need for bulky and high power consuming circuitry. | 04-12-2012 |
20120105122 | DUTY CYCLE CORRECTION CIRCUIT OF SEMICONDUCTOR MEMORY APPARATUS - A duty cycle correction circuit of a semiconductor memory apparatus includes a duty correction unit configured to determine a duty correction range in response to a duty correction range control signal, correct a duty of an inputted clock in response to duty correction codes to fall in the determined duty correction range, and generate a duty corrected clock; a duty detection unit configured to detect a duty of the duty corrected clock and output duty information; and a duty correction code generation unit configured to generate the duty correction codes based on the duty information. | 05-03-2012 |
20120112811 | GENERATION OF ADJUSTABLE PHASE REFERENCE WAVEFORM - One embodiment provides a system for generating a reference waveform. The system can include a first pulse-width modulation (PWM) channel configured to provide a first PWM waveform having a first duty cycle and a first frequency. A second PWM channel is configured to provide a second PWM waveform having a second duty cycle and the first frequency. Combinational logic is configured to combine the first PWM waveform and the second PWM waveform to generate a phase-shifted reference PWM waveform having the first frequency and a phase shift that is based on the first duty cycle and the second duty cycle. | 05-10-2012 |
20120146696 | PULSE-WIDTH MODULATION CIRCUIT, A DEVICE INCLUDING THE SAME AND A METHOD FOR PULSE-WIDTH MODULATION - A PWM circuit comprises: a charge and discharge circuit to receive a initial signal and, according to the initial signal, increase a voltage at an output end of thereof linearly or decrease the voltage; a comparator with a positive input end to receive a control signal and a negative input end connected to the output end of the charge and discharge circuit; a voltage transmission circuit with a first input end to receive the initial signal and a second input end to receive an output of the comparator, the voltage transmission circuit is configured to transmit the initial signal to an output end of the voltage transmission circuit when the output of the comparator is digital 1, and output digital 0 when the output of the comparator is digital 0. | 06-14-2012 |
20120154005 | PULSE WIDTH MODULATED SIGNAL GENERATION METHOD AND APPARATUS - Various embodiments associated with methods, apparatuses and systems, digital pulse width modulator (DPWM) comprising a counter logic, including a bitwise negator, and a delay-locked loop (DLL), are disclosed herein. The embodiments may potentially have a shorter processing delay, smaller footprint and/or less power consumption. Other embodiments be also be disclosed or claimed. | 06-21-2012 |
20120154006 | DUTY CYCLE CORRECTION CIRCUIT - A duty cycle correction circuit includes a duty cycle control unit configured to generate a corrected clock signal by correcting a duty cycle of an input clock signal in response to a control signal, a duty cycle detection unit configured to detect a duty cycle of the corrected clock signal and output a detection signal, and a control signal generation unit configured to generate the control signal in response to the detection signal. | 06-21-2012 |
20120194244 | SEMICONDUCTOR MEMORY APPARATUS AND METHOD FOR CORRECTING DUTY THEREOF - A semiconductor memory apparatus may comprise a duty cycle correction circuit configured to perform a duty correction operation with respect to an input clock signal when a delay locked signal is activated, and perform the duty correction operation with respect to the input signal when a precharge signal is activated, to generate a corrected clock signal. | 08-02-2012 |
20120194245 | PULSE WIDTH MODULATOR - Disclosed herein are pulse width modulator (PWM) solutions with comparators not relying on a variable reference to adjust duty cycle. In accordance with some embodiments, a pulse width modulator having a comparator with an applied adjustable waveform to generate a bit stream with a controllably adjustable duty cycle is provided. | 08-02-2012 |
20120200331 | DIGITAL CONTROL UNIT HAVING A TRANSIENT DETECTOR FOR CONTROLLING A SWITCHED MODE POWER SUPPLY - A switched mode power supply (SMPS) comprising a feedback unit, voltage feed forward (VFF) compensation signal generator and a transient detector. A VFF compensation signal is only applied to the output of the feedback unit when a transient is detected by the transient detector on the input voltage of the SMPS, thereby saving power and computation time. The transient detector comprises a first comparator to detect that a positive transient has occurred if a difference signal is greater than a positive threshold level; a second comparator to determine if the difference signal is within a predetermined range of positive values and output a result that indicates if the difference signal is within the predetermined range of positive values; and a first calculator to detect that a positive transient has occurred if, out of a first predetermined number of consecutive results of the output of the second comparator, there is at least a second predetermined number of results indicating that the difference signal is within the predetermined range of positive values. The transient detector comprises further features for similarly detecting a negative transient. | 08-09-2012 |
20120206180 | LEVEL-UP SHIFTER CIRCUIT - A level-up shifter circuit is suitable for high speed and low power applications. The circuit dissipates almost no static power, or leakage current, compared to conventional designs and can preserve the signal's duty cycle even at high data rates. This circuit can be used with a wide range of power supplies while maintaining operational integrity. | 08-16-2012 |
20120242387 | ADVANCED REPEATER WITH DUTY CYCLE ADJUSTMENT - An advanced repeater with duty cycle adjustment. In accordance with a first embodiment of the present invention, an advanced repeater includes an output stage for driving an output signal line responsive to an input signal and a plurality of active devices for selectably adjusting a duty cycle of the signal. The advanced repeater may further include circuitry for producing a delayed version of the signal. | 09-27-2012 |
20120256669 | DUTY CYCLE CORRECTION - Method and circuitry for controlling duty cycle of an input signal towards a desired value comprising a sequence of at least two inverters arranged in series and feedback circuitry. A first inverter is arranged to receive the input signal and a last inverter is arranged to output a signal having the same frequency as the input signal. The output signal is an adjusted version of the input signal. The feedback circuitry is arranged to receive the output signal and comprises a comparing and supplying means. The comparing means compares the output signal with a reference signal indicative of a desired value and generates a feedback signal based on the comparison of the output and reference signal. The supplying means supplies the feedback signal to adjust operating conditions of at least one of the inverters, such that the duty cycle of the output signal is controlled towards the desired value. | 10-11-2012 |
20120256670 | Techniques for Reducing Duty Cycle Distortion in Periodic Signals - A transmitter circuit is operable to provide an output signal in response to a first periodic signal. A multiplexer circuit is operable to provide a second periodic signal as a selected signal during a first phase of operation. The multiplexer circuit is operable to provide the output signal of the transmitter circuit as the selected signal during a second phase of operation. A sampler circuit is operable to generate first samples of the selected signal during the first phase of operation. The sampler circuit is operable to generate second samples of the selected signal during the second phase of operation. A duty cycle control circuit is operable to adjust a duty cycle of the first periodic signal based on the first and the second samples. | 10-11-2012 |
20120256671 | SWITCH LEVEL CIRCUIT WITH DEAD TIME SELF-ADAPTING CONTROL - A switch level circuit ( | 10-11-2012 |
20120280732 | APPARATUS, SYSTEM, AND METHOD FOR VOLTAGE SWING AND DUTY CYCLE ADJUSTMENT - Described herein are an apparatus, system, and method for compensating voltage swing and duty cycle of a signal on an input-output (I/O) pad of a processor by adjusting the voltage swing and duty cycle of the signal. The apparatus comprises a driver to transmit a signal on an I/O pad, the signal on the I/O pad having a voltage swing and a duty cycle; and an adjustment unit, coupled to the driver, to receive the signal from the I/O pad transmitted by the driver and to generate voltage swing and duty cycle control signals for adjusting the voltage swing and duty cycle of the signal on the I/O pad respectively. Described herein is also an analog-to-digital (A2D) converter for measuring and/or calibrating various signal attributes including current, voltage, and time. | 11-08-2012 |
20120280733 | Adjusting circuit of duty cycle and its method - An adjusting circuit of duty cycle includes an edge detecting circuit, a flip-flop connected to the edge detecting circuit, a feedback control circuit connected to the flip-flop and a charge pump circuit connected to the feedback control circuit. The edge detecting circuit detects an edge of an inputted clock signal. The flip-flop sets an outputting terminal thereof at a first level according to a clock signal outputted by the edge detecting circuit. The charge pump circuit controls a duration of the first level outputted the outputting terminal of the flip-flop by charging and discharging a capacitor. The flip-flop sets the outputting terminal thereof at a second level contrary to the first level according to a clock signal outputted by the feedback control circuit. An adjusting method of duty cycle is also disclosed. The adjusting circuit of duty cycle has a simple structure, a stable performance and a fast speed. | 11-08-2012 |
20120280734 | METHOD AND APPARATUS FOR PULSE WIDTH MODULATION - An integrated control circuit according to aspects of the present invention includes an oscillator, a capacitor, and a logic gate. The oscillator generates a periodic timing signal that cycles between a first logic state for a first time duration and a second logic state for a second time duration. The capacitor receives a charge current in response to the periodic timing signal transitioning to the first logic state, where a voltage on the capacitor increases for the first time duration to an initial value. The logic gate generates a periodic output signal having a duty ratio that is responsive to a time that it takes the capacitor to discharge from the initial value to a reference voltage. A period of the periodic output signal is the period of the periodic timing signal. | 11-08-2012 |
20120293225 | DUTY CORRECTION CIRCUIT - A duty correction circuit includes a clock buffer configured to buffer an input clock and generate a buffer clock, a swing level conversion block configured to generate an internal clock, which transitions to levels of a sync voltage and a power supply voltage, in response to a voltage level of the buffer clock, a duty control block configured to generate duty information and frequency information by using a high pulse width and a low pulse width of the internal clock, and a current control block configured to control a time point, at which a logic value of the buffer clock transitions, in response to the duty information and the frequency information. The current control block includes a plurality of first current paths coupled in parallel to one another in order to control the time point at which the logic value of the buffer clock transitions. | 11-22-2012 |
20120306555 | Duty cycle adjusting system - A duty cycle adjusting system includes a detection circuit, a first clock signal adjusting circuit connected with the detection circuit, and a second clock signal adjusting circuit connected with the detection circuit, wherein the detection circuit detects a duty cycle of a first output signal outputted by the first clock signal adjusting circuit and a duty cycle of a second output signal outputted by the second clock signal adjusting circuit, and outputs a first detection signal and a second detection signal, the first and second output signals are a pair of differential clock signals, the first and second detection signals are adapted for respectively adjusting rising edges of the pair of differential clock signals. No peripheral circuit is needed to provide the bias in the duty cycle adjusting system. The duty cycle adjusting system has the simple structure and can be independently applied to the clock path. | 12-06-2012 |
20120326760 | PROGRAMMABLE DUTY CYCLE SELECTION USING INCREMENTAL PULSE WIDTHS - A method and device for generating a waveform according to programmable duty cycle control bits from a divided frequency reference signal. The device may include: a timing circuit that inputs a CLOCK signal having a 50% duty cycle to a divider, whose output varies over a plurality of divide-by-n settings; and a waveform generator. The waveform generator may, after a last low clock pulse is counted for a current evaluative cycle and before a beginning of a next evaluative cycle, shift a prior duty cycle waveform by ½ of a CLOCK cycle, to provide an incremented duty cycle for the waveform. Alternatively, the waveform generator may increment a gating signal from an adder, which determines an onset of an inoperative or low portion of the programmed duty cycle. | 12-27-2012 |
20130002323 | DUTY CYCLE CORRECTION CIRCUIT - A duty cycle correction circuit includes a duty correction block configured to generate a first pre-corrected signal and a second pre-corrected signal in response to a duty code and an input signal; a duty-corrected signal generation block configured to generate a duty-corrected signal in response to a first select signal, a second select signal, the first pre-corrected signal and the second pre-corrected signal; and a control block configured to generate the duty code, the first select signal and the second select signal in response to the duty-corrected signal and the input signal. | 01-03-2013 |
20130002324 | CIRCUITS AND METHODS FOR CLOCK SIGNAL DUTY-CYCLE CORRECTION - Duty-cycle correction circuits, clock distribution networks, and methods for correcting duty-cycle distortion are disclosed, including methods and apparatus for correcting duty-cycle distortion of differential output clock signals provided from a clock distribution network. In one such method, a single-ended clock signal is generated from differential input clock signals for distribution over a clock distribution network and from which the differential output clock signals are generated. A delay of a model delay path is matched to a propagation delay of the clock distribution network, and the single ended clock signal is adjusted to compensate for duty-cycle distortion. | 01-03-2013 |
20130033294 | COUNTING CIRCUIT OF SEMICONDUCTOR DEVICE AND DUTY CORRECTION CIRCUIT OF SEMICONDUCTOR DEVICE USING THE SAME - A counting circuit of a semiconductor device includes a plurality of counting units configured to count respective bits of counting codes in response to a plurality of counting clocks, respectively, and to control in a counting direction in response to a counting control signal; a clock toggling control unit configured to control the number of counting clocks that toggle among the plurality of counting clocks in response to clock control signals; and a counting operation control unit configured to compare a value of target codes and a value of the counting codes, and to determine a value of the counting control signal according to a comparison result. | 02-07-2013 |
20130069701 | PHASE INTERPOLATION CIRCUIT - A phase interpolation circuit including a first multiplexer, a second multiplexer, an interpolator and a duty-cycle repeater is provided. The first multiplexer receives a plurality of even order signals. The second multiplexer receives a plurality of odd order signals. The interpolator receives a first reference signal composed of one of the even order signals through the first multiplexer, and receives a second reference signal composed of one of the odd order signals through the second multiplexer. The interpolator divides a phase difference between the first reference signal and the second reference signal into a plurality of sub-phases according to a digital control signal, and selects one of the sub-phases to generate a differential input signal. The duty-cycle repeater adjusts the duty cycle of the differential input signal and accordingly generates a differential output signal with 50% duty cycle. | 03-21-2013 |
20130069702 | PWM SIGNAL OUTPUT CIRCUIT - A PWM-signal-output circuit includes a first output unit to output a PWM signal with a first duty cycle, in a first period in which a motor starts rotating, a second output unit to output the PWM signal whose duty cycle increases toward a second duty cycle and decreases from the second duty cycle in a period from a logic level change in speed signal until its subsequent logic level change, in a second period following the first, the speed signal having a period corresponding to a motor-rotation speed and a logic level changing alternately, and a third output unit to output the PWM signal whose duty cycle increases toward that of the input signal and thereafter decreases from that of the input signal in a period from a logic level change in the speed signal until its subsequent logic level change, after the second period elapses. | 03-21-2013 |
20130076420 | DIGITALLY CONTROLLED PULSE WIDTH MODULATOR UTILIZING REAL TIME CALIBRATION - A system and method for controlling pulse width for electronic devices in real time is disclosed. The system includes a Digital Pulse Width Modulator (DPWM), a real time calibration circuit and a delay line circuit. The real time calibration circuit is configured to ensure proper fractional delay is applied to yield correct duty cycle of the DPWM. The delay line circuit comprising a multiplexer delay line with built in decoders, modulates the pulse width for fractional clock cycle delay. | 03-28-2013 |
20130099840 | DUTY ADJUSTMENT CIRCUITS AND SIGNAL GENERATION DEVICES USING THE SAME - A duty adjustment circuit is provided. The duty adjustment circuit is used to adjust a duty cycle of a first driving signal. The duty adjustment circuit includes a filter, a first comparator, and a first duty adjustor. The filter receives a comparison result signal and filters the comparison result signal to generate a duty information signal. The duty information signal indicates a duty cycle of the comparison result signal. The first comparator receives the duty information signal and determines whether a direct-current (DC) level of the duty information signal falls into a predefined voltage range to generate a first adjustment signal. The first duty adjustor receives the first adjustment signal and the first driving signal and adjusts the duty cycle of the first driving signal according to the first adjustment signal. | 04-25-2013 |
20130106479 | HIGH-SPEED DUTY CYCLE CORRECTION CIRCUIT | 05-02-2013 |
20130120044 | DUTY CYCLE DISTORTION CORRECTION CIRCUITRY - Integrated circuits with clock generation and distribution circuitry are provided. Integrated circuits may include phase-locked loops configured to generate multiple clock signals that are delayed versions of one another. The clocks signal may be distributed to various regions on an integrated circuit using serially connected clock buffer blocks. Each buffer block may include bidirectional pairs of buffer circuits coupled in parallel. Each buffer circuit may have a first input configured to receive an input clock signal, an output at which a corrected version of the input clock signal is provided (e.g., an output at which an output clock signal with desired duty cycle is provided), a second input that receives a first delayed clock signal for setting the desired duty cycle for the output clock signal, and a third input that receives a second delayed clock signal that is high at least when the first delayed clock signal rises high. | 05-16-2013 |
20130141149 | APPARATUS AND METHOD FOR DUTY CYCLE CALIBRATION - An apparatus for duty cycle calibration includes an input calibration circuit, a delay chain, a first comparator, and a second comparator. The input calibration circuit calibrates an input clock signal according to a first control signal so as to generate an input calibration clock signal. The delay chain includes a plurality of delay units coupled in series, and delays the input calibration clock signal so as to generate a first delay clock signal and a second delay clock signal. At least two of the delay units each have an adjustable delay time which is controlled according to a second control signal. The first comparator compares the input calibration clock signal with the first delay clock signal so as to generate the first control signal. The second comparator compares the input calibration clock signal with the second delay clock signal so as to generate the second control signal. | 06-06-2013 |
20130169330 | DUTY CYCLE CONTROLLING CIRCUIT, DUTY CYCLE ADJUSTING CELL, AND DUTYCYCLE DETECTING CIRCUIT - A duty cycle controlling circuit for adjusting duty cycle of a target clock signal to a desired value, comprises: a first duty cycle adjusting cell, for receiving a first duty cycle control signal to adjust duty cycle of an input clock signal to generate a first output clock signal as the target clock signal; and a duty cycle detecting module, for generating the first duty cycle control signal according to the first output clock signal. | 07-04-2013 |
20130200934 | DUTY CYCLE ADJUSTMENT CIRCUIT - A duty cycle adjustment circuit includes a clock signal input node; a clock signal output node; a control voltage generation circuit coupled to the clock signal input node; and a first inverter configured to receive an inverter input signal comprising a sum of an input clock signal received at the clock signal input node and a control voltage received from the control voltage generation circuit, and to output an output clock signal at the clock signal output node, wherein variation of the control voltage is configured to vary a duty cycle of the output clock signal. | 08-08-2013 |
20130229216 | SIGNAL DUTY CYCLE DETECTOR AND CALIBRATION SYSTEM - A duty cycle detector and calibration system is disclosed. In some embodiments, a duty cycle calibration system includes a first tuning circuit operative to receive an input signal, tune a duty cycle of the input signal to within a first error range, and provide a first output signal. A second tuning circuit tunes a duty cycle of the first output signal to within a second error range and provides a second output signal, where the second error range has more precision than the first error range. A duty cycle detector provides a duty cycle detection signal indicative of a duty cycle of the second output signal, and logic controls the first and second tuning circuits based upon the duty cycle detection signal. | 09-05-2013 |
20130234769 | PWM DUTY CYCLE CONVERTER - A PWM duty cycle converter includes a PWM signal generator, a timing signal generator, a limit signal generator, and a duty cycle limiter. The PWM signal generator generates a first PWM signal by comparing a triangular carrier wave with a duty command from a signal source. The timing signal generator generates a timing signal synchronously with at least one of a maximum value and a minimum value of the amplitude of the carrier wave. The limit signal generator generates a limit signal in response to the timing signal. The limit signal sets at least one of an upper limit and a lower limit on a duty cycle of the first PWM signal. The duty cycle limiter combines the first PWM signal and the limit signal to output a second PWM signal having a limited duty cycle. | 09-12-2013 |
20130249614 | PWM Duty Cycle Synthesizer and Method with Adjustable Corner Frequency - A circuit is provided that includes summing circuit for comparing the PWM output signal to the PWM input signal and producing an increment signal if a value of the PWM input signal exceeds a corresponding value of the PWM output signal and producing a decrement signal if a value of the PWM input signal is less than a corresponding value of the PWM output signal. An integrator produces a duty cycle signal by producing an increase in value of the duty cycle signal in response to each increment signal and a decrease in value of the duty cycle signal in response to each decrement signal. A PWM generator produces the PWM output signal in response to the duty cycle signal to cause the duty cycle of the PWM output signal to equal the duty cycle of the PWM input signal with no loss of duty cycle resolution. | 09-26-2013 |
20130257499 | HIGH SPEED DUTY CYCLE CORRECTION AND DOUBLE TO SINGLE ENDED CONVERSION CIRCUIT FOR PLL - The present invention pertains to a high speed duty cycle correction and double to single ended conversion circuit for PLL, comprising a reshaper stage, a single-edge detection circuit and a duty cycle restorer. The present invention introduces a way to convert double-ended output of PLL VCO into single-ended signal and adjust duty cycle of PLL VCO's output waveform by 50%, so that the circuit can output single ended clock signal with 50% duty cycle. | 10-03-2013 |
20130265091 | IMPLEMENTING LOW DUTY CYCLE DISTORTION AND LOW POWER DIFFERENTIAL TO SINGLE ENDED LEVEL SHIFTER - A method and circuit for implementing low duty cycle distortion and low power differential to single ended level shifter, and a design structure on which the subject circuit resides are provided. The circuit includes an input differential amplifier providing positive and negative differential amplifier output signals coupled to an output amplifier providing a single ended output signal. The output amplifier amplifies and inverts the negative differential amplifier output signal. The output amplifier amplifies and superimposes the positive differential amplifier output signal with the amplified and inverted negative differential amplifier output signal, providing the single ended output signal with low duty cycle distortion. | 10-10-2013 |
20130285725 | DUTY CYCLE DISTORTION CORRECTION CIRCUITRY - Integrated circuits with clock generation and distribution circuitry are provided. Integrated circuits may include phase-locked loops configured to generate multiple clock signals that are delayed versions of one another. The clocks signal may be distributed to various regions on an integrated circuit using serially connected clock buffer blocks. Each buffer block may include bidirectional pairs of buffer circuits coupled in parallel. Each buffer circuit may have a first input configured to receive an input clock signal, an output at which a corrected version of the input clock signal is provided (e.g., an output at which an output clock signal with desired duty cycle is provided), a second input that receives a first delayed clock signal for setting the desired duty cycle for the output clock signal, and a third input that receives a second delayed clock signal that is high at least when the first delayed clock signal rises high. | 10-31-2013 |
20130285726 | FORWARDED CLOCK JITTER REDUCTION - In some embodiments, a differential amplifier with duty cycle correction is provided. | 10-31-2013 |
20130300480 | DATA OUTPUT CIRCUIT AND DATA OUTPUT METHOD THEREOF - A data output circuit and a data output method thereof are provided. The data output circuit includes a delay locked loop, a duty ratio correction block, and an output unit. The delay locked loop corrects a duty ratio of a first internal clock. The delay locked loop includes a correction enable signal output unit configured to output a correction enable signal when the operation of correcting the duty ratio of the first internal clock is completed. The duty ratio correction block corrects the duty ratio of the first internal clock by using a duty ratio detection signal in response to the correction enable signal, and outputs the corrected first internal clock as an output clock. The output unit detects a duty ratio of the output clock, generates the duty ratio detection signal to the duty ratio correction block, and outputs a data strobe signal in response to the output clock. | 11-14-2013 |
20130300481 | EDGE SELECTION TECHNIQUES FOR CORRECTING CLOCK DUTY CYCLE - Circuits and methods are provided for generating clock signals and correcting duty cycle distortion in clock signals. A circuit for generating a clock signal includes a multiplexer circuit and an edge-triggered flip-flop circuit. The multiplexer circuit selectively outputs one of a plurality of input clock signals. The edge-triggered flip-flop detects a transitioning edge of the input clock signal that is selectively output from the multiplexer circuit, and in response to the detection, samples a logic level of a received data signal, and generates a transition of an output clock signal at an output port of the edge-triggered flip-flop. The multiplexer circuit selectively outputs one of the plurality of input clock signals to a clock signal port of the edge-triggered flip-flop, based on a logic level of the output clock signal at the output port of the edge-triggered flip-flop, which is input to a select control port of the multiplexer circuit. | 11-14-2013 |
20130307601 | COMMON MODE TRIMMING WITH VARIABLE DUTY CYCLE - A resistive divider circuit may be operatively coupled with a modulated resistor circuit, wherein the resistive divider circuit and the modulated resistor circuit for an effective resistor circuit providing an effective attenuation. A variable duty cycle signal modulates the modulated resistor circuit to control the effective attenuation. | 11-21-2013 |
20130314137 | DUTY CYCLE CORRECTOR - A duty cycle corrector includes an SR latch, a first switch and a second switch. The SR latch is configured to generate first and second control signals according to first and second clocks. The first switch is coupled between a work voltage and an output node, and selectively closes and opens according to the first control signal. The second switch is coupled between the output node and a ground voltage, and selectively closes and opens according to the second control signal. The output node is used to output an output clock. | 11-28-2013 |
20130328605 | Non-Overlapping Clock Generator - A non-overlapping clock generator including an enabling module and N pulse-generating modules connected as a ring is provided. When the ith input node has a high voltage level, the enabling module enables the ith pulse-generating module so as to trigger the ith pulse-generating module to discharge the ith input node. After the ith input node has been discharged to a low voltage level, the ith pulse-generating module charges the ith output node to the high voltage level. | 12-12-2013 |
20130328606 | INTEGRATED CIRCUITS WITH DUAL-EDGE CLOCKING - Integrated circuits that support dual-edge clocking are provided. Integrated circuits may include phase-locked loops that generate square-wave clock signals. The clock signals may be provided from off-chip equipment through input-output pins. The clock signals may be routed through a clock distribution network to provide local clock signals to pulse generators that generate clock pulses on rising and falling clock edges. The pulse generators may generate clock pulses that are triggered by the rising and falling clock edges with a common pulse width for optimum performance. Duty cycle distortion introduced by the clock network may be minimized for optimum performance. Adaptive duty cycle distortion circuitry may be used to control the pull-up/pull-down drive strengths of the clock buffer so that the high clock phase of the local clock signals is approximately a half clock cycle. | 12-12-2013 |
20130335126 | CLOCK GENERATOR - A clock generator includes a delay circuit to have 2N delays, in which a delay time from a first delay of the 2N delays to a last delay is set to a length of one cycle of an input; a first phase-detector to detect a first phase-difference between the input and an output from the last delay; a first charge-pump to generate a first current according to the first phase-difference; a first loop-filter to adjust a delay amount of each of the 2N delays, based on a voltage of the first current; a second phase-detector to detect a second phase-difference between the input and an output from an Nth delay; a second charge-pump to generate a second current according to the second phase-difference; and a second loop-filter to adjust a duty ratio of an output from each of the 2N delays, based on a voltage of the second current. | 12-19-2013 |
20130342252 | Real Time Automatic and Background Calibration at Embedded Duty Cycle Correlation - The present disclosure relates to a clock generation system. The system includes a clock source, a tuning buffer, an output buffer, a duty cycle measurement circuit and an automatic calibration component. The clock source generates a clock signal. The tuning buffer is configured to generate a corrected clock signal from the clock signal according to adjustment values. The output buffer is configured to generate an output clock signal from the corrected clock signal. The duty cycle measurement circuit is configured measure a duty cycle of the output clock signal. The automatic calibration component is configured to generate the adjustment values according to the duty cycle measurement and the specification values. | 12-26-2013 |
20140002156 | DUTY CYCLE CORRECTION WITHIN AN INTEGRATED CIRCUIT | 01-02-2014 |
20140002157 | DUTY CYCLE ERROR ACCUMULATION CIRCUIT AND DUTY CYCLE CORRECTION CIRCUIT HAVING THE SAME | 01-02-2014 |
20140002158 | HIGH-SPEED FULLY-DIFFERENTIAL CLOCK DUTY CYCLE CALIBRATION CIRCUIT | 01-02-2014 |
20140062559 | SYSTEM AND METHOD OF ADJUSTING A CLOCK SIGNAL - A method includes receiving an input clock signal at a programmable buffer. The method further includes filtering an output signal from the programmable buffer to generate a filtered signal having a voltage level, where the voltage level indicates a duty cycle of the output signal. The method further includes comparing the voltage level to a reference voltage. The method further includes modifying at least one operating parameter of the programmable buffer to adjust the duty cycle of the output signal. | 03-06-2014 |
20140084979 | SELF-ADJUSTING DUTY CYCLE TUNER - A duty cycle tuner measures high and low periods of a signal, calculates an actual duty cycle, generates duty control signals based on the actual duty cycle and a desired duty cycle, and adjusts the duty cycle responsive to the duty control signals. The high and low periods are measured using high-speed counters to provide a high count for the high period and a low count for the low period. The actual duty cycle value is then computed from the high and low counts, and compared to the desired duty cycle value to generate increment and decrement signals which may be positive or zero, to increase, decrease or maintain the actual duty cycle. In this manner, even if the high and low counts are subject to variations due to process, temperature or power supply voltage, their ratio is independent of such variations, so the tuner is immune to those effects. | 03-27-2014 |
20140103981 | COUNTING CIRCUIT OF SEMICONDUCTOR DEVICE AND DUTY CORRECTION CIRCUIT OF SEMICONDUCTOR DEVICE USING THE SAME - A counting circuit of a semiconductor device includes a plurality of counting units configured to count respective bits of counting codes in response to a plurality of counting clocks, respectively, and to control in a counting direction in response to a counting control signal; a clock toggling control unit configured to control the number of counting clocks that toggle among the plurality of counting clocks in response to clock control signals; and a counting operation control unit configured to compare a value of target codes and a value of the counting codes, and to determine a value of the counting control signal according to a comparison result. | 04-17-2014 |
20140118043 | PROGRAMMABLE DUTY CYCLE SETTER EMPLOYING TIME TO VOLTAGE DOMAIN REFERENCED PULSE CREATION - An improved programmable duty cycle generator and method of operation. In one aspect, the generated output signal duty cycle is not measured, but rather is generated based on a predetermined value. Saw tooth generator/Integrator schemes are used to create the saw type waveforms of the incoming frequency which in conjunction with DAC is used to create the desired duty cycle. The improved programmable duty cycle signal generator for placement in key pinch points of a critical path where precise duty cycle definition is needed. | 05-01-2014 |
20140118044 | DUTY CYCLE TUNING CIRCUIT AND METHOD THEREOF - A duty cycle tuning circuit and a method thereof are provided, in which the duty cycle tuning circuit includes multiple interpolation circuits, an edge detection circuit, and a delay chain. Each interpolation circuit receives multiple phase clocks, and interpolates an interpolation clock from two of the phase clocks. The phase clocks have the same frequency but different phases. The edge detection circuit is connected electrically to the delay chain, and generates an output clock according to an edge of the interpolation clock. | 05-01-2014 |
20140118045 | APPARATUS FOR CONTROLLING DUTY RATIO OF SIGNAL - Disclosed is an apparatus for controlling a duty ratio of a signal that includes a clock control unit configured to generate a plurality of control signals based on an input signal, a half-cycle generation unit configured to generate a multiplied signal by use of the input signal and a delay signal that is obtained by delaying the input signal based on a delay control voltage, and divide the multiplied signal to generate a first division signal and a second division signal that are in inverse relation to each other, a comparator unit configured to compare a pulse width of the first division signal with a pulse width of the second division signal based on the control signal provided by the clock control unit, and output a delay control signal corresponding to a result of the comparison, and a control voltage generation unit configured to output a delay control voltage. | 05-01-2014 |
20140125390 | APPARATUSES AND METHODS FOR DUTY CYCLE ADJUSTMENT - Apparatuses, duty cycle adjustment circuits, adjustment circuits, and methods for duty cycle adjustment are disclosed herein. An example duty cycle adjustment circuit may be configured to receive a signal and adjust a duty cycle of the signal a first amount using a coarse adjustment. The duty cycle adjustment circuit may further be configured, after adjusting the duty cycle of the signal a first amount, to adjust the duty cycle of the signal a second amount different from the first amount using a fine adjustment to provide a duty cycle adjusted signal. | 05-08-2014 |
20140125391 | DUTY CYCLE CORRECTION APPARATUS - Disclosed is a duty cycle correction apparatus. The apparatus of the present invention adjusts signal widths of an input signal, averages the widths of the signal, and inverts the signal, then averages the widths of the inverted signal, compares the two averaged signals, and outputs the difference between the two averaged signals. | 05-08-2014 |
20140139278 | Variable Frequency Ratiometric Multiphase Pulse Width Modulation Generation - Groups of phase shifted Pulse Width Modulation signals are generated that maintain their duty-cycle and phase relationships as a function of the period of the PWM signal frequency. The multiphase PWM signals are generated in a ratio-metric fashion so as to greatly simplify and reduce the computational workload for a processor used in a PWM system. The groups of phase shifted PWM signals may also be synchronized with and automatically scaled to match external synchronization signals. | 05-22-2014 |
20140152362 | Duty Cycle Adjusting Circuit and Adjusting Method - The present invention relates to a square wave generator circuit, an integrated circuit, a DC/DC converter and an AC/DC converter. The square wave generator circuit comprises a first mirror current branch which is connected with ground via a first switching element and a first capacitor in parallel with the first switching element, wherein the first switching element is operable to be opened or closed periodically under control of a first clock signal so as to generate a first sawtooth wave signal at a non-grounded terminal of the first capacitor; a second mirror current branch which is connected with ground via a second switching element and a second capacitor in parallel with the second switching element, wherein the second switching element is operable to be opened or closed periodically under control of a second clock signal synchronous with the first clock signal so as to generate a second sawtooth wave signal at a non-grounded terminal of the second capacitor; and a comparator, one input terminal of which is connected to the non-grounded terminal of the first capacitor and the other input terminal of which is connected to the non-grounded terminal of the second capacitor, so that a square wave signal can be outputted at an output terminal of the comparator, wherein a duty cycle of the square wave signal depends on a ratio of a capacitance of the second capacitor to a capacitance of the first capacitor. | 06-05-2014 |
20140176211 | SIGNAL COUPLING CIRCUIT AND ASSOCIATED METHOD - A signal coupling circuit for generating an output signal according to an input signal is provided. The signal coupling circuit includes: a coupling capacitor, configured to generate a coupling signal according to the input signal; a clock generating circuit, configured to generate a clock and determine a duty cycle of the clock by the coupling capacitor; a discharge circuit, configured to intermittently discharge the coupling capacitor according to the duty cycle of the clock; and an output circuit, coupled to the coupling capacitor, for generating the output signal according to the coupling signal. | 06-26-2014 |
20140184292 | DUTY CYCLE DETECTION AND CORRECTION CIRCUIT IN AN INTEGRATED CIRCUIT - A duty cycle detection and correction circuit includes a clock generator, a clock tree, and a duty cycle correction circuit. The clock generator is configured to generate a first clock signal and a second clock signal, and the first clock signal and the second clock signal have a predetermined phase difference. The clock tree is configured to receive the first clock signal and the second clock signal, to generate a first output clock signal based on the first clock signal and the set of control signals, and to generate a second output clock signal based on the second clock signal and the set of control signals. The duty cycle correction circuit is configured to receive the first output clock signal and the second output clock signal and to generate the set of control signal based on the first output clock signal and the second output clock signal. | 07-03-2014 |
20140184293 | PULSE SIGNAL GENERATION CIRCUIT AND OPERATING METHOD THEREOF - The present invention relates to a pulse signal generation circuit for changing a pulse width of an input pulse signal and outputting an output pulse signal having the changed pulse width. In an aspect, the pulse signal generation circuit may include a control signal generator configured to generate at least one control signal according to a pulse width of a input pulse signal and a pulse signal generator configured to control a pulse width of an input pulse signal in response to a control signal and to generate an output pulse signal with the controlled pulse width. The control signal controls the pulse width of the output pulse signal. | 07-03-2014 |
20140184294 | DUTY CYCLE CORRECTION CIRCUIT AND OPERATION METHOD THEREOF - A duty cycle correction circuit includes a clock adjustment unit configured to adjust a duty ratio of an input clock signal in response to a duty control signal and generate an output clock signal, a tracking type setting unit configured to generate an tracking type selection signal for setting a first or second tracking type based on a duty locking state of the output clock signal, and a control signal generation unit configured to generate the duty control signal, into which the first or second tracking type is incorporated, in response to the tracking type selection signal and the output clock signal. | 07-03-2014 |
20140210534 | PULSE WIDTH MODULATION SIGNAL GENERATION CIRCUIT AND PULSE WIDTH MODULATION SIGNAL GENERATION METHOD - The present invention discloses a PWM signal generation circuit and a PWM signal generation method. The PWM signal generation circuit includes: a reference signal generation circuit for generating a reference signal according to an input voltage; a variable ramp signal generation circuit for generating a variable ramp signal; and a comparator circuit for comparing the reference signal with the variable ramp signal to generate a PWM signal. A rising slope and/or a falling slope of the variable ramp signal is variable. | 07-31-2014 |
20140218088 | APPARATUS, SYSTEM, AND METHOD FOR RE-SYNTHESIZING A CLOCK SIGNAL - Described herein are apparatus, method, and system for re-synthesizing a clock signal. The apparatus comprises: a first logic unit to detect a rising edge of an input clock signal and for generating a rising edge of an output clock signal based on the detected rising edge of the input clock signal, the input clock signal having a non-50% duty cycle and a first period; and a second logic unit to compute a falling edge of the output clock signal according to the detected rising edge of the input clock signal, the falling edge of the output clock signal being near half of the first period. | 08-07-2014 |
20140253195 | OPEN-LOOP CORRECTION OF DUTY-CYCLE ERROR AND QUADRATURE PHASE ERROR - A Phase Interpolator (PI) may be employed as a precisely-controlled delay element in a transmit path, for example in clock forwarded serial links. Methods and circuits are disclosed for estimating a delay needed to correct duty-cycle/and or phase errors of the received clock. These corrections or delta values may be transmitted back to the transmitter side, preferably expressed directly in terms of PI phase codes, for convenient adjustment in the transmitter clock circuitry. Various techniques also are disclosed for measuring and mitigating the effects on PI integral non-linearity. | 09-11-2014 |
20140266359 | CLOCK CYCLE COMPENSATOR AND THE METHOD THEREOF - One aspect of the present invention is to provide a method for compensating a system duty cycle of a system clock signal. The method in one embodiment comprises the following steps: locking a duty cycle center of the system duty cycle by a delay lock loop; detecting a current system duty cycle of the system clock signal; determining a duty cycle correction amount, wherein the duty cycle correction amount is a gap of the current system duty cycle from a target duty cycle; and changing a polarity of an input reference clock signal according to whether the duty cycle correction amount exceed a threshold amount or not. | 09-18-2014 |
20140266360 | DUTY CYCLE CORRECTOR - The duty cycle corrector for correcting a system clock signal comprises a duty cycle detector and a duty cycle adjuster. The duty cycle detector is configured for detecting a system duty cycle of the system clock signal and generating the first control signal and the second control signal, wherein the first control signal and the second control signal are complementary to each other. The duty cycle adjuster comprises an inverter and the duty cycle adjuster is configured for delaying a change in an input status of the inverter and adjusting of the inverter in accordance with the first control signal and the second control signal. | 09-18-2014 |
20140266361 | DUTY CYCLE CORRECTION CIRCUIT - In an embodiment, a duty cycle correction circuit comprises a first set of inverters connected in series, a first filter, a first feedback circuit and a second feedback circuit. A first inverter in the series is configured to receive a clock signal and a last inverter in the series is configured to provide a first output clock signal. The first filter is configured to generate a first direct current (DC) voltage signal at an output of the first filter. The first feedback circuit is configured to control a rise time of a signal transition at an output terminal of the first inverter to control a duty cycle of the first output clock cycle. The second feedback circuit is configured to control a fall time of the signal transition at the output terminal of the first inverter to control the duty cycle of the first output clock cycle. | 09-18-2014 |
20140266362 | DIGITAL DUTY CYCLE CORRECTION CIRCUIT - A digital duty cycle correction circuit includes a duty cycle controller and a digital duty control code generator. The duty cycle controller generates first and second output clock signals by compensating duty cycles of first and second input clock signals based on a digital duty control code. The digital duty control code generator generates the digital duty control code based on a frequency value obtained by converting duty cycle information of the first output clock signal and the second output clock signal. | 09-18-2014 |
20140285247 | SEMICONDUCTOR DEVICE - According to one embodiment, a semiconductor device includes a first differential amplifier and a second differential amplifier. The first differential amplifier charges the first output terminal with a second voltage different from a first voltage. The first differential amplifier uses a first clock signal, stopping the charging at the first output terminal, receives first complementary data of the first voltage at the rising edge of a second clock signal, and outputs the first complementary data at the second voltage. The second differential amplifier charges the second output terminal with the second voltage. The second differential amplifier uses a third clock signal, stopping the charging at the second output terminal, receives second complementary data of the first voltage at the rising edge of a fourth clock signal, and outputs the second complementary data at the second voltage. | 09-25-2014 |
20140333361 | EVENT-DRIVEN CLOCK DUTY CYCLE CONTROL - Duty cycle error vectors that indicate both the magnitude and direction of the duty cycle error relative to a desired duty cycle are generated within a duty cycle measurement circuit, enabling threshold-based determination of whether duty cycle adjustment is necessary, refraining from power-consuming adjustment and follow-up measurement in those cases where the duty cycle is within a target range. When duty cycle adjustment is deemed necessary, the magnitude of the duty cycle error indicated by the duty cycle error vector may be applied to effect proportional rather than incremental duty cycle adjustment, quickly returning the clock duty cycle to a target range. | 11-13-2014 |
20140347112 | VARIABLE PULSE WIDTH SIGNAL GENERATOR - The present invention concerns a signal generator circuit powered by a supply voltage and including flip flop means including a first input to which is connected a continuous input signal whose amplitude is defined, a second input to which is connected a clock signal whose duty cycle is defined, and a third, reset input, and outputting an output signal whose duty cycle is that of the clock signal and whose amplitude is that of the input signal, characterized in that said circuit further includes regulating means arranged to compare the output signal to a set point signal representative of the desired duty cycle and to deliver a control signal connected to the third input of the flip flop means so as to activate the reset to modify the duty cycle of the output signal. | 11-27-2014 |
20140368245 | DUTY RATE DETECTER AND SEMICONDUCTOR DEVICE USING THE SAME - A duty rate detection circuit includes a duty rate detection block suitable for outputting a duty rate detection signal by detecting a duty rate of a clock signal having a first logic duration and a second logic duration and an output control block suitable for comparing the number of the first logic duration and the number of the second logic duration for a detection period and controlling an output moment of the duty rate detection signal. | 12-18-2014 |
20150008968 | APPARATUSES AND METHODS FOR PHASE INTERPOLATING CLOCK SIGNALS AND FOR PROVIDING DUTY CYCLE CORRECTED CLOCK SIGNALS - Apparatuses and methods for phase interpolating clock signals and for providing duty cycle corrected clock signals are described. An example apparatus includes a first inverter configured to receive first and second clock signals and further includes a second inverter configured to receive the first and second clock signals. The first inverter is configured to provide to an output node an inverted first clock signal as controlled by the second clock signal. The second inverter is configured to provide to the output node an inverted second clock signal as controlled by the first clock signal. Another example apparatus includes a clock generator circuit to provide first and second clock signals responsive to an input clock signal, and further includes a duty phase interpolator circuit, a duty cycle adjuster and a duty cycle detector. | 01-08-2015 |
20150015315 | Method and Apparatus for Duty Cycle Distortion Compensation - A method and apparatus for duty cycle distortion compensation is disclosed. In one embodiment, an integrated circuit includes a differential signal transmitter having a main data path and a compensation data path. The main data path includes a first and second differential driver circuits each having output terminals coupled to a differential output. A transmission controller is configured to transmit data into the main and compensation data paths, the data corresponding to pairs of sequentially transmitted bits including an odd data bit followed by an even data bit, and further configured to determine respective duty cycle widths for each of the odd and even data bits as received by the transmission controller. The transmission controller is configured to cause the first and second driver circuits to equalize the respective duty cycle widths of the odd and even data bits, as transmitted, based their respective duty cycle widths as received. | 01-15-2015 |
20150097605 | DUTY CORRECTION CIRCUIT AND METHOD - A duty correction circuit includes a duty ratio control unit suitable for generating an output clock by adjusting the duty ratio of an input clock, a code generation unit suitable for detecting a duty of the output clock and generating a first duty ratio control code based on the detection result, and a code filter unit suitable for providing the duty ratio control unit with a second duty ratio control code corresponding to a target value when a value of the first duty ratio control code is within a predetermined critical range adjacent to the target value. | 04-09-2015 |
20150097606 | SIGNALING METHOD USING CONSTANT REFERENCE VOLTAGE AND DEVICES THEREOF - A semiconductor device includes a receiver configured to receive a reference voltage via a first input terminal, receive an input signal via a second input terminal, and generate an output signal by comparing the reference voltage to the input signal with each other. A termination circuit associated with the input signal terminal may be adjusted and a logic threshold voltage may be adjusted to accommodate the adjustment in the termination circuit. | 04-09-2015 |
20150137867 | APPARATUSES AND METHODS FOR DUTY CYCLE ADJUSTMENT - Apparatuses and methods for duty cycle adjustment are disclosed herein. An example apparatus may include a node, a phase mixer, and a duty cycle adjuster circuit. The phase mixer may have a first step duty cycle response and may be configured to provide a first output signal to the node in accordance with the first step duty cycle response. The duty cycle adjuster circuit may have a second step duty cycle response complementary to the first step duty cycle response and may be configured to provide a second signal to the node in accordance with the second step duty cycle response. | 05-21-2015 |
20150145574 | PWM SIGNAL GENERATION CIRCUIT AND PROCESSOR SYSTEM - A PWM signal generation circuit according to the present invention includes a duty setting unit ( | 05-28-2015 |
20150295564 | DUAL-COMPLEMENTARY INTEGRATING DUTY CYCLE DETECTOR WITH DEAD BAND NOISE REJECTION - A method for correcting the duty cycle of a clock signal uses two-dual-slope integrators with two comparators; each comparator is connected to both integrators and configured to include a “dead band” when the input pulse duty cycle is at or near 50%. One comparator detects when duty cycle is high and the other comparator detects when the duty cycle is low. When the duty cycle is within the “dead band” range, neither comparator goes valid. This provides an analog filter where the output comparators will not instantaneously switch between opposite duty cycle correction states. When the duty cycle is greater or less than 50%, the integrated voltages on the two integrators move in opposite directions producing twice the signal magnitude on differential inputs of the comparators, as compared with using a single integrator architecture. | 10-15-2015 |
20150303899 | APPARATUSES AND METHODS FOR DUTY CYCLE ADJUSTMENTS - Apparatuses and methods have been disclosed. One such apparatus includes a plurality of gates coupled together in series. A first pull-down circuit can be coupled to a node between two adjacent gates of the plurality of gates and controlled responsive to a first control signal. A second pull-down circuit can be coupled to an output of one of the gates and controlled responsive to a second control signal. A duty cycle of a signal provided by the plurality of gates can be increased responsive to the first control signal and can be decreased responsive to the second control signal. The plurality of gates and the first and second pull-down circuits can make up a duty cycle adjuster circuit that can adjust the duty cycle of the signal by adjusting only a single type of edges of the signal. | 10-22-2015 |
20150341021 | APPARATUSES, METHODS, AND CIRCUITS INCLUDING A DUTY CYCLE ADJUSTMENT CIRCUIT - Apparatuses, methods, and duty cycle correction circuits are described. An example apparatus includes a duty cycle correction (DCC) adjustment circuit configured to receive an input signal, and to adjust a duty cycle of the input signal to provide an output signal. The DCC circuit including a coarse adjust control circuit configured to adjust the duty cycle of the input signal by a first amount that is equal to one or more unit adjustments, and a fine adjust control circuit that is configured to adjust the duty cycle of the input signal responsive to a pulse signal by a second amount that is less than the unit adjustment. | 11-26-2015 |
20150358001 | WIDE-BAND DUTY CYCLE CORRECTION CIRCUIT - A duty cycle correction circuit includes a rising edge variable delay circuit and a falling edge variable delay circuit. The variable delay for each delay circuit depends upon an uncorrected duty cycle for an uncorrected clock signal being corrected by the duty cycle correction circuit into a corrected clock signal having a desired duty cycle. | 12-10-2015 |
20160013785 | DUTY CYCLE CORRECTION CIRCUIT AND SEMICONDUCTOR DEVICE | 01-14-2016 |
20160043709 | SIGNAL CONVERSION SYSTEM AND METHOD - A signal conversion system and method for converting an input signal to a pulse width modulated signal is disclosed. The signal conversion system includes a sample rate converter coupled with an associated pulse width modulation (PWM) module. A hardware and power efficient signal conversion system for resampling an audio input signal with an arbitrary sample rate to a pulse width modulated output audio signal for use in an audio processor and/or reproduction is disclosed. The signal conversion system may be particularly suitable for use in a battery operated consumer electronics device. | 02-11-2016 |
20160056807 | APPARATUS, SYSTEM, AND METHOD FOR RE-SYNTHESIZING A CLOCK SIGNAL - Described herein are apparatus, method, and system for re-synthesizing a clock signal. The apparatus comprises: a first logic unit to detect a rising edge of an input clock signal and for generating a rising edge of an output clock signal based on the detected rising edge of the input clock signal, the input clock signal having a non-50% duty cycle and a first period; and a second logic unit to compute a falling edge of the output clock signal according to the detected rising edge of the input clock signal, the falling edge of the output clock signal being near half of the first period. | 02-25-2016 |
20160094205 | DIGITAL OPEN LOOP DUTY CYCLE CORRECTION CIRCUIT - A duty cycle correction (DCC) circuit includes a master delay line that receives an input clock and determines a period of the input clock. A calibration module is coupled to the master delay line and generates a calibration code based on a desired duty cycle and the period of the input clock. A slave delay line generates a delayed input clock based on the input clock and the calibration code. A clock generation module generates an output clock, having the desired duty cycle, in response to the input clock and the delayed input clock. | 03-31-2016 |
20160105165 | DUTY CYCLE ERROR DETECTION DEVICE AND DUTY CYCLE CORRECTION DEVICE HAVING THE SAME - In a duty cycle error detection device, a first digital code generator is configured to generate high and low codes corresponding to a lengths of high level low level periods, respectively, of a clock signal, generate a sign signal representing the longer period between the high level period and the low level period, and output one of the high and low digital codes corresponding to the shorter period as a first digital code. A clock delay circuit is configured to generate a delay clock signal by delaying the clock signal for a time corresponding to the first digital code, and a second digital code generator is configured to generate a duty error digital code corresponding to a length from a start of the longer period of the delay clock signal to an end of the longer period of the clock signal based on the sign signal. | 04-14-2016 |
20160118972 | METHOD AND DEVICE FOR GENERATING PWM PULSES FOR MULTI-LEVEL INVERTER - A method and a device for generating PWM pulses for an inverter are provided. The three-phase inverter's characteristic of including high frequency complementary switches is used. Only three PWM peripheral units of a DSP control unit are used to output PWM high frequency signals, and a detection control unit determine for each phase two currently high frequency complementary switches according to the states of detected level signals outputted by a preset number of GPIO interfaces. The PWM high frequency signals are distributed for each phase to one of the two switches, and the PWM high frequency signals are inversed and then sent to the other one of the two switches. In addition, the states of other switches are maintained unchanged according to a preset correspondence between states of switches of a multi-level inverter and outputted level signals in different switching periods. | 04-28-2016 |
20160134263 | ASYMMETRIC HYSTERETIC CONTROLLERS - An asymmetric hysteretic controller comprises an analog comparator coupled with a fast slew rate DAC, or a digital comparator coupled with an ADC plus some digital control logic. The comparator, analog or digital, operates as a sequential windowed comparator having high and low limits. The sense parameter is compared to a high or a low limit and when the sense parameter reaches the selected high or low limit, the controlled device is turned off or on, respectively. When the hysteretic controller state comparison reversal occurs: (a) the comparator output may be blanked by the control logic, (b) the comparator polarity may be reversed by the control logic, (c) the control logic may command the other process limit to be selected for comparison with the sense parameter, and (d) then the comparator output may be re-enabled. | 05-12-2016 |
20160164500 | DIGITAL CURRENT SENSING IN POWER CONTROLLER - Some embodiments include apparatus and methods having a node to provide a signal, and a control unit arranged to control a value of an output voltage at an output node on an output path based on a duty cycle of the signal and a value of an input voltage. The control unit can also be arranged to cause a change in a resistance on the output path in order to determine a value of a current on the output path based at least on the change in the resistance. | 06-09-2016 |
20160164510 | APPARATUS AND METHOD FOR COMPENSATING FOR DUTY SIGNALS - An apparatus and method for compensating for duty signals are disclosed herein. The apparatus for compensating for duty signals includes a signal input unit, a signal control unit, a combined signal control unit, a determination unit, and a signal output unit. The signal input unit receives a first signal and a second signal. The signal control unit controls the timing of the first and second signals based on first and second control signals, and outputs a combined signal. The combined signal control unit outputs first and second logic operation signals. The determination unit generates the first and second control signals if the timing of the first signal does not match the timing of the second signal, outputs the generated first and second control signals, and applies a third control signal to the combined signal control unit. The signal output unit outputs the first and second signals. | 06-09-2016 |
20160182019 | DUTY CYCLE DETECTION CIRCUIT AND METHOD | 06-23-2016 |
20160191024 | IMPLEMENTING CLOCK RECEIVER WITH LOW JITTER AND ENHANCED DUTY CYCLE - A method and a clock receiver circuit for implementing low jitter and enhanced duty cycle, and a design structure on which the subject circuit resides are provided. The clock receiver circuit accepts single-ended complementary metal oxide semiconductor (CMOS) and differential clock signals. The clock receiver circuit includes input circuitry coupled to a differential pair that biasing a reference clock and allows for single-ended or differential clock signals. The differential pair uses multiple current mirrors for switching the polarity of the input signals to achieve enhanced jitter performance, and cross coupled inverters for retaining signal symmetry. | 06-30-2016 |
20160204769 | CIRCUIT AND METHOD FOR GENERATING AN OUTPUT SIGNAL HAVING A VARIABLE PULSE DUTY FACTOR | 07-14-2016 |