Abstract: A semiconductor memory device includes a clock input block suitable for generating first and second internal clocks in response to an external clock, a clock correction block suitable for generating a data clock by correcting a duty ratio of the first and second internal clocks in response to a signal activated in an initial operation mode of the semiconductor memory device, and a data control block suitable for controlling data in synchronization with the data clock.

Abstract: Sequential logic elements may consume less static power in response to a first state of a clock signal than in response to a second state of a clock signal (the first and second state may be either low or high depending on the type of sequential logic). This can be exploited to reduce static power consumption of an integrated circuit by controlling the level of a clock signal so that is in the first state for a greater amount of time than the second state.

Abstract: A scan test circuit includes: a pulse generator, for generating differential pulses according to a system clock signal; a functional path, including: a D-type latch clocked by the differential pulses; a test path, including: a scan latch clocked by a test clock signal; and a tri-state inverter. When a test enable signal is enabled, the generation of the differential pulses is disabled.

Abstract: According to one embodiment, there is provided a duty cycle correction circuit including an input inverter, an output inverter, a charge distribution unit, and a drawing-off unit. The input inverter includes a PMOS transistor and an NMOS transistor and receives a clock signal. The output inverter outputs a clock signal according to a signal transmitted via a signal line from the input inverter. The charge distribution unit distributes, when one transistor of the PMOS transistor and the NMOS transistor is turned on, charge to capacitance elements selected from among one or more first capacitance elements placed on side of the signal line and among a plurality of second capacitance elements disposed on side of source of the one transistor. The drawing-off unit draws off the distributed charge from the selected capacitance elements while the one transistor is maintained to be on.

Abstract: An integrated circuit (IC) includes a reference voltage generator, a voltage regulator, a reset controller, and a voltage monitoring circuit. The reference voltage generator generates first and second reference voltages, and the voltage regulator generates a supply voltage. The reset controller stabilizes the first and second reference voltages in a first predetermined time period, and generates a power down signal after the first predetermined time period. The voltage monitoring circuit compares a level of the supply voltage with a level of the second reference voltage after the first predetermined time period and generates a (low) voltage monitor signal. The reset controller also generates a (high) reset signal when the supply voltage is greater than the second reference voltage.

Abstract: A timing adjustment circuit includes a detection unit to generate a detection signal in response to a first clock having a duty cycle of 50% and a first frequency, a second clock having a duty cycle of 50% and a second frequency that is half the first frequency, and a third clock having a duty cycle of 50%, the second frequency, and a phase displacement of 90 degrees relative to the second clock, the detection signal indicating timing relationship between the first clock and the second and third clocks, a low-pass filter to receive the detection signal, and a variable-delay circuit to adjust relative timing relationship between the first clock and the second clock in response to an output of the low-pass filter such that a center point of a pulse of the first clock is aligned with a center point of a pulse of the second clock.

Abstract: A multi-phase signal generator and a multi-phase signal generating method thereof. The multi-phase signal generator includes a signal generator, a first comparator, a second comparator and a logic operation circuit. The signal generator generates a periodic signal. The first comparator receives the periodic signal and respectively compares the periodic signal with a first reference voltage and a second reference voltage to generate a first output signal. The second comparator receives the periodic signal and compares the periodic signal with a first threshold voltage to generate a second output signal. The logic operation circuit performs logic operations on the first output signal and the second output signal so as to generate a plurality of first phase output signals.

Abstract: A buffer circuit section receives an input clock, and outputs an output clock by wave-shaping the input clock, a measurement circuit section measures a first pulse width at a first potential level of the output clock and a second pulse width at a second potential level of the output clock, and an adjustment circuit section adjusts a ratio between the first pulse width and the second pulse width by varying a drive capability of the buffer circuit section on the basis of the measurement result of the measurement circuit section.

Abstract: The present disclosure regards adjusting a duty cycle, which includes generating a duty cycle signal having a voltage representing a duty cycle of a clock signal; adjusting a reference voltage generated by an adjustable reference voltage generator to match the duty cycle signal to produce a first matched value; inverting voltage sources of the reference voltage generator; adjusting, while the voltage sources are inverted, the reference voltage to produce a second matched value; and calculating a duty cycle value based on the first and second matched values.

Abstract: There are provided an apparatus for sensing capacitance, a method for sensing capacitance, and a touch screen apparatus. The apparatus for sensing capacitance includes; a first integration circuit unit including a first capacitor charged by a change in capacitance occurring in a sensing electrode; a comparison circuit unit comparing a level of an output signal of the first integration circuit unit with a predetermined reference level; and a noise removal unit including a plurality of switches operating according to an output of the comparison circuit unit, wherein the comparison circuit unit controls an operation of each of the plurality of switches to discharge charges charged in the first capacitor when the level of the output signal of the first integration circuit unit is higher than the reference level.

Abstract: A duty cycle correction circuit may include an error booster suitable for amplifying an input clock duty error, a driver suitable for driving an output clock based on the input clock, and a duty corrector suitable for correcting the output clock duty based on the duty error amplified by the error booster.

Abstract: There are provided a power factor correction device and a method for controlling power factor correction using the same. The power factor correction device includes a power factor correction circuit and a control circuit. The power factor correction circuit includes first and second inductors connected to an input power source stage and first and second main switches performing a switching operation on the first and second inductors, respectively. The control circuit may provide control signals to the first and second main switches, respectively, and when phase currents flowing in the respective first and second inductors are unbalanced, the control circuit may change a phase of at least one of the first and second main switches to correct an imbalance of the phases.

Abstract: 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.

Abstract: An operation clock generation circuit performs calculation on the basis of the frequency errors of a fundamental clock and the clock pulses of the fundamental clock, and generates an operation clock obtained by correcting the frequency errors at first intervals. A correction clock generation circuit converts a lower-bit value that is a value represented by the bits lower than the predefined bit used for judging the change of the state of the operation clock into a count number of the clock pulses of a second clock whose frequency is higher than that of the operation clock, generates a correction clock obtained by correcting the operation clock on the basis of a time required for counting the count number of the clock pulses and the clock pulses of the operation clock.

Abstract: Data channels are sorted into an order in terms of an exponent E, where E is defined in the equation: segment interval=C*2E, in which segment interval is a number of the slots between instances of a given data channel, and the data channels are assigned to ones of the slots in terms of the order. Subsequent to the assigning data channels, the control channel is assigned to ones of the slots on the data line. Optionally assigning the data channels assigns all data channels to ones of the slots on the data line to reduce the number of unassigned slots.

Abstract: A pulse generation circuit (12) includes a PWM waveform outputting part (20) which outputs a PWM waveform having a duty ratio in which one linear PWM pulse is defined with a first number of bits, an input connector (22) which receives as an input a control signal indicating a duty ratio defined with a second number of bits larger than the first number of bits, and a setting part (24) which sets a PWM waveform to be output from the PWM waveform outputting part (20) based on the control signal input to the input connector (22) with one cycle being made up of a set comprised of a plurality of consecutive linear PWM pulses according to the second number of bits.

Abstract: A digital duty-cycle correction circuit may include an adjustment unit that may be configured to adjust a duty cycle of an oscillating signal based on an adjust signal to generate an adjusted oscillating signal and a sampling unit that may be configured to sample the adjusted oscillating signal. The circuit may also include a counting unit that may be configured to generate an indication of a number of samples of the adjusted oscillating signal that are at the low and high level and to adjust the indication using a selectable duty cycle modify signal based on a desired duty cycle of the adjusting oscillating signal. The circuit may also include a comparing and filtering unit that may be configured to generate the adjust signal based on a comparison of the indication with a comparison count. The indication may be adjustable such that the oscillating signal's duty cycle is adjustable.

Abstract: One embodiment relates to a method of calibrating duty cycle distortion. A data rate of a physical layer interface is changed from a lower rate to a higher rate, and a data rate of one or more transceivers associated with the physical layer interface is changed from the lower rate to the higher rate. An electrical idle state is maintained after changing the data rate of the transceiver. Duty cycle distortion calibration for one or more transceivers associated with the physical layer interface is then performed during the electrical idle state. Other embodiments and features are also disclosed.

Abstract: 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.

Abstract: A circuit and method for improving signal integrity characteristics of a non-full rate transmitter are disclosed herein. The circuit comprises an actuator block having an input for receiving a differential clock signal, the differential clock signal comprising a positive clock signal and a negative clock signal, the actuator configured to adjust a difference between the positive and negative clock signals; a sensing block, for sensing a difference between positive and negative signals of a differential signal, the differential signal being related to the clock signal; and a calibration block for providing a control signal to the actuator based on the sensed difference between the positive and negative signals.

Abstract: An integrated circuit (IC) includes a set of metastability-hardened storage circuits. Each metastability-hardened storage circuit may include: (a) a pulse width distortion circuit; (b) a first circuit powered by a nominal power supply voltage, and a second circuit powered by a higher-than-nominal supply voltage; (c) an inverter and a bias circuit, where the bias circuit provides a bias current based on an intermediate state of the inverter to resolve a metastable state of the inverter; or (d) a latch, and a dynamic bias circuit that causes current to be injected into the latch to resolve a metastable state of the latch.

Abstract: Methods and apparatuses featuring a multiplying injection-locked oscillator are described. Some embodiments include a pulse-generator-and-injector and one or more injection-locked oscillators. The outputs of the pulse-generator-and-injector can be injected into corresponding injection points of an injection-locked oscillator. In embodiments that include multiple injection-locked oscillators, the outputs of each injection-locked oscillator can be injected into the corresponding injection points of the next injection-locked oscillator. Some embodiments reduce deterministic jitter by dynamically modifying the loop length of an injection-locked oscillator, and/or by using a duty cycle corrector, and/or by multiplexing/blending the outputs from multiple delay elements of an injection-locked oscillator.

Abstract: 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.

Abstract: Exemplary embodiments are related to a clock doubler. A device may include a duty cycle correction circuit configured to receive an input clock signal and convey a corrected clock signal. The duty cycle correction circuit may include a first circuit to convey an output voltage during a first cycle of the input clock signal and correct a current mismatch of the first circuit during a second cycle of the input clock signal. The duty cycle correction circuit may also include a second circuit to convey the output voltage during the second cycle and correct a current mismatch of the second circuit during the first cycle. Further, the device may include a clock generator for receiving the corrected clock signal and generating an output clock.

Abstract: 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.

Abstract: 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.

Abstract: 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.

Abstract: A high-speed fully differential clock duty cycle calibration circuit applied to calibrating the clock duty cycle in a high-speed system. The circuit detects the duty cycle with a continuous time integrator, and directly adjusts the duty cycle on a clock transmission link so as to increase the working speed. Being of a fully differential circuit structure, the circuit can calibrate the duty cycle under a designated process within a higher and wider frequency range, and has relatively good constraining force for process mismatch and common mode noise. The circuit comprises adjustment level ADJ1 and ADJ2, a first buffer level BUF1, a second buffer level BUF2 and a duty cycle detection level DCD.

Abstract: A PWM signal generation circuit according to the present invention includes a duty setting unit (10) configured to generate a duty control signal designating a duty ratio corresponding to each period of a PWM signal on the basis of an initial duty setting signal, a target duty setting signal, a slope setting signal, and a clock signal, a period setting unit (20) configured to output a period setting value, and an output control unit (30) configured to generate the PWM signal having a period corresponding to the period setting value and having a duty ratio corresponding to a value of the duty control signal. The duty setting unit (10) increases the value of the initial duty ratio to the value of the target duty ratio each time the number of a clock pulse of the clock signal reaches the period setting value reaches the slope setting value.

Abstract: 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.

Abstract: 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.

Abstract: An integrated circuit includes a duty cycle detection circuit, a comparator circuit, and a tuning circuit. The duty cycle detection circuit receives a clock signal, such as a system clock signal, and detects the level of duty cycle distortion in the clock signal. The comparator circuit then generates an output based on the level of duty cycle distortion that is detected in the clock signal. The tuning circuit may accordingly adjust the clock signal based on the output generated by the comparator circuit to produce an adjusted clock output signal. As an example, the clock output signal produced by the tuning circuit after the adjustment may have a 50% (or significantly close to 50%) duty cycle.

Abstract: A pulse generator comprising: an input for receiving a trigger; an output node for outputting a signal; a delay line comprising one or more delay units and a plurality of taps; one or more pull-up devices each connected to the output node for increasing the output voltage on the output node; and/or one or more pull-down devices each connected to the output node for decreasing the output voltage on the output node; wherein the taps of the delay line are operably connected to the pull-up and/or pull-down devices such that a trigger passing along the delay line activates one or more of the pull-up and/or one or more of the pull-down devices more than once. Re-use of the pull-up and/or pull-down devices enables longer and more complex pulse shapes, such as high-order Gaussian pulse shapes to be produced while keeping the number of components low, thus reducing chip area, power requirements and parasitic capacitance.

Abstract: 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.

Abstract: A circuit for filtering narrow pulse and compensating wide pulse, including a signal shaping circuit, a filter circuit, and a pulse width compensating circuit. The signal shaping circuit processes an input signal and transmits the input signal to the filter circuit. The filter circuit filters off narrow pulses of the input signal. The pulse width compensating circuit compensates the wide pulses of the input signal and outputs an output signal.

Abstract: 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.

Abstract: 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.

Abstract: A circuit configuration for generating pulses within a time interval on the basis of an input signal includes a counting unit, a comparator unit and a first adder circuit; the time interval being predicted on the basis of at least two defined changes in input signals; the circuit configuration being configured for triggering at the beginning of the time interval by the first adder circuit on the basis of clock pulses, for generating and outputting pulses; for counting a number of generated and output pulses using the counting unit; for comparing the counted number to a setpoint value using the comparator unit; and for ending the generation and outputting of the pulses in response to the reaching of the setpoint value or the ending of the time interval.

Abstract: In various embodiments, systems and methods for generating high-precision pulse-width modulation include a delay-locked loop comprising multiple delay units having time-variable delays, control logic for selecting a subset S of the multiple delay units to thereby generate a time-invariant shift amount having a precision finer than that of a system clock and circuitry for applying the shift amount to rising and falling edges of a pulse-width modulation waveform to thereby generate a high-precision pulse-width modulation waveform.

Abstract: A driving circuit includes a first PWM driving module and a second PWM driving module. The first PWM driving module generates a first square-wave signal to drive a first illumination unit according to a first data signal of a data stream, wherein the first square-wave signal, having a rising edge located at the beginning of the display cycle, represents an illumination period of the first illumination unit in a display cycle. The second PWM driving module generates a second square-wave signal to drive a second illumination unit according to a second data signal of the data stream, wherein the second square-wave signal, having a falling edge located at the end of the display cycle and having a rising edge being behind the rising edge of the first square-wave signal, represents an illumination period of the second illumination unit in the display cycle.

Abstract: A modulation method is provided. The modulation method includes the steps of receiving multiple sinusoidal signals, obtaining the maximum value of the sinusoidal signals, obtaining the median value of the sinusoidal signals, and obtaining the minimum value of the sinusoidal signals within a period to generate a difference between the maximum value and the minimum value, generating a difference according to an upper limit and a lower limit of a predetermined comparison value, and comparing the two differences to generate an optimized modulation signal.

Abstract: 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.

Abstract: 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.

Abstract: 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.

Abstract: An example circuit includes a capacitance circuit, a regulator circuit, and a slew rate control circuit. The capacitance circuit is coupled between a first node and a second node. The regulator circuit is coupled to the capacitance circuit to regulate a supply voltage across the capacitance circuit with a charge current during a normal operation mode of the circuit. The slew rate control circuit is coupled to the capacitance circuit and the regulator circuit. The slew rate control circuit is coupled to lower a slew rate of a change in voltage over change in time between the first and second nodes during a power up mode of the circuit. The slew rate control circuit includes a transistor coupled between the first and second nodes to shunt excess current from the charge current.

Abstract: The present invention relates to a square wave generator circuit, an integrated circuit, a DC/DC converter and an AC/DC converter.

Abstract: 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.

Abstract: Exemplary embodiments are related to a clock doubler. A device may include a duty cycle correction circuit configured to receive an input clock signal and convey a corrected clock signal. The duty cycle correction circuit may include a first circuit to convey an output voltage during a first cycle of the input clock signal and correct a current mismatch of the first circuit during a second cycle of the input clock signal. The duty cycle correction circuit may also include a second circuit to convey the output voltage during the second cycle and correct a current mismatch of the second circuit during the first cycle. Further, the device may include a clock generator for receiving the corrected clock signal and generating an output clock.

Abstract: 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.

Abstract: A PWM signal generation circuit according to the present invention includes a duty setting unit (10) configured to generate a duty control signal designating a duty ratio corresponding to each period of a PWM signal on the basis of an initial duty setting signal, a target duty setting signal, a slope setting signal, and a clock signal, a period setting unit (20) configured to output a period setting value, and an output control unit (30) configured to generate the PWM signal having a period corresponding to the period setting value and having a duty ratio corresponding to a value of the duty control signal. The duty setting unit (10) increases the value of the initial duty ratio to the value of the target duty ratio each time the number of a clock pulse of the clock signal reaches the period setting value reaches the slope setting value.