Abstract: A transceiver for sending and receiving data from a controller area network (CAN) bus is disclosed. The transceiver includes a microcontroller port, a transmitter and a receiver, wherein the transceiver is configured to determine bit timings from a data frame received by the receiver. The transceiver is further configured to detect attempts to introduce a signal glitch in a predetermined portion of the data frame and upon detection of the signal glitch, the transceiver is configured to invalidate the data frame on a transmission line and/or disable the transmitter for a predetermined period.

Abstract: A semiconductor package may include a base layer; a first semiconductor chip disposed over and spaced apart from the base layer; a second semiconductor chip stack disposed between the base layer and the first semiconductor chip, the second semiconductor chip stack including a plurality of second semiconductor chips that are stacked in a vertical direction; a bridge die stack disposed between the base layer and the first semiconductor chip and disposed to be spaced apart from the second semiconductor chip stack, the bridge die stack including a plurality of bridge dies that are stacked in the vertical direction and electrically connecting the first semiconductor chip and the base layer to supply power; and a vertical interconnector disposed between the base layer and the first semiconductor chip and disposed to be spaced apart from the second semiconductor chip stack and the bridge die stack, the vertical interconnector electrically connecting the first semiconductor chip and the base layer to transmit a signa

Abstract: A signal modulation apparatus, a memory storage apparatus, and a signal modulation method are disclosed. The signal modulation apparatus includes an observation circuit, a signal modulation circuit, and a phase control circuit. The signal modulation circuit is configured to generate a second signal according to a first signal and a reference clock signal. A frequency of the first signal is different from a frequency of the second signal. The phase control circuit is configured to obtain an observation information via the observation circuit. The observation information reflects a process variation of at least one electronic component in the signal modulation apparatus. The phase control circuit is further configured to control an offset between the first signal and the reference clock signal according to the observation information.

Abstract: A clock synthesizer is provided. The Clock synthesizer includes a Phase Locked Loop (PLL) configured to generate a clock signal based on a reference signal. A clock buffer is connected to the PLL. The clock buffer stores the clock signal. A Duty Cycle Controller and Phase Interpolator (DCCPI) circuit is connected to the clock buffer. The DCCPI circuit receives the clock signal from the clock buffer, adjusts a duty cycle of the clock signal to substantially equal to 50%, performs phase interpolation on the clock signal, and provides the clock signal as an output after adjusting the duty cycle substantially equal to 50% and performing the phase interpolation.

Abstract: A variable delay circuit includes at least one first delay circuit and a second delay circuit. The first delay circuit includes multiple first delay elements connected in series and is configured to output a delay signal from a first stage first delay element that is a first stage of the first delay circuit. The second delay circuit includes at least one second delay element and multiple third delay elements connected in series. The second delay circuit is configured to output a delay signal from a first stage second delay element that is a first stage of the second delay circuit. The first stage first delay element and the first stage second delay element are connected in series. A delay signal obtained by delaying an input signal received at one circuit among the first delay circuit and the second delay circuit for a predetermined time duration is output from another circuit.

Abstract: The disclosure provides a delay estimation device and a delay estimation method. The delay estimation device includes a pulse generator, a digitally controlled delay line (DCDL), a time-to-digital converter (TDC), and a control circuit. The pulse generator receives a reference clock signal, outputs a first clock signal in response to a first rising edge of the reference clock signal, and outputs a second clock signal in response to a second rising edge of the reference clock signal. The DCDL receives the first clock signal from the pulse generator and converts the first clock signal into phase signals based on a combination of delay line codes. The TDC samples the phase signals to generate a timing code based on the second clock signal. The control circuit estimates a specific delay between the first clock signal and the second clock signal based on the timing code.

Abstract: An electronic system may include one or more units of processing circuitry configured to implement a main intellectual property (IP), a checker IP, and an error detection circuit. The main IP includes a first data path and a first control signal path. The checker IP includes a second control signal path. The error detection circuit is configured to detect an error of data by performing error correction code (ECC) decoding of output data that is output by the main IP to the error detection circuit through the first data path, and detect an error of a control signal based on a first signal that is output by the main IP to the error detection circuit through the first control signal path, and a second signal that is output by the checker IP to the error detection circuit through the second control signal path.

Abstract: An initialization circuit of a delay locked loop (DLL) includes a sense circuit and a control circuit. The sense circuit receives an enable signal, a reference clock signal, and various delayed reference clock signals, and outputs another enable signal. The control circuit receives the two enable signals and outputs and provides a control signal to a loop filter of the DLL to control a delay value associated with the DLL. The control signal is provided to the loop filter such that the delay value associated with the DLL equals a predetermined delay value for a predetermined time duration. Further, after a lapse of the predetermined time duration, the delay value associated with the DLL increases until a difference between a time period of the reference clock signal and the delay value equals a threshold value.

Abstract: A digital phase-locked loop (DPLL) includes a time-to-digital converter (TDC) to generate a multi-bit code based on a phase error between a reference clock and a feedback clock, a digital loop filter (DLF) coupled to the TDC, a digitally-controlled oscillator (DCO) circuit coupled to the DLF and to generate an output signal that is convertible to the feedback clock, and a logic component coupled to an input of the DCO circuit. The logic component is to: trigger, in response to detecting a power on of the DPLL circuit, a switch to decouple the DLF from the DCO circuit; determine, from the reference clock, a target frequency; measure a frequency of the feedback clock; and iteratively generate, based on the frequency during each iteration, a set of digital bits to the input of the DCO circuit that successively causes the frequency to converge towards the target frequency.

Abstract: Embodiments relate to a circuit implementation for controlling a delay of a clock signal. The clock delay control circuit includes a sensing circuit and a phase interpolator controlled by the sensing circuit. The sensing circuit generates a first control signal that increases when a level of a supply voltage increases, and decreases when the level of the supply voltage decreases. Moreover, the sensing circuit generates a second control signal that decreases when the level of the supply voltage increases, and increases when the level of the supply voltage decreases. The phase interpolator includes multiple paths, each having a different propagation delay. The coupling between each path and the output node of the phase interpolator is controlled by the control signals generated by the sensing circuit.

Abstract: The systems and methods described herein involve a device that may receive a plurality of commands and generate a common command indicative of matching data signals between each of the plurality of commands. The device may include a first latch that receives a shifted flag and outputs a shifted command in response to a first enable signal. The device may include shifters, where a first shifter may receive the common command, and a last shifter may couple to the first latch. The last shifter may receive a shifter common command and may generate the first enable signal using the shifted common command.

Abstract: A semiconductor circuitry includes an oscillator configured to output an oscillation signal whose frequency depends on a first input signal, a counter configured to count a number of cycles of the oscillation signal, first circuitry configured to output a first digital signal based on a first number of cycles counted by the counter within one of a clock cycle of a clock signal, wherein the first input signal is digitally converted into the first digital signal, and a second circuitry configured to output a second digital signal based on a second number of cycles counted by the counter in a period from a reference timing of the clock signal to an input timing of a second input signal within the one of the clock cycle of the clock signal, wherein the period is digitally converted into the second digital signal.

Abstract: Duty cycle adjustment circuitry includes a first stage, a second stage, and decoder circuitry. The first stage includes a first strength tuning circuit having first inverter branches, and a first fine tuning circuit having second inverter branches. The first strength tuning circuit and the first fine tuning circuit are coupled in parallel. The second stage includes a second strength tuning circuit having third inverter branches, and a second fine tuning circuit having fourth inverter branches. The second strength tuning circuit and the second fine tuning circuit are coupled in parallel. Further, the second stage is electrically coupled to the first stage. The decoder circuitry is electrically coupled to the first stage and the second stage. The decoder circuitry controls the first strength tuning circuit independently from the first fine tuning circuit to adjust the duty cycle of an input signal received by the duty cycle adjustment circuitry.

Abstract: A DLL circuit that has a programmable output frequency is provided. The DLL circuit uses a single delay line to produce the multiple frequencies. In various embodiments, the delay line is configured to receive an input clock defining an input clock period. The delay line comprises delay stages, each configured to generate a corresponding output clock having a phase relative to the input clock based on a delay of the delay line. In those embodiments, a control circuit is configured to change the delay of the delay line so as to cause a phase difference between the input clock and a sensed output clock to be substantially equal to the input clock period. An edge combiner is configured to generate a DLL output clock based on the output clocks of the delay stages and presents an equal schematic load for each of the output clocks of the delay stages.

Abstract: A device includes a control circuit, a scope circuit, and a time-to-current converter. The control circuit is configured to receive a voltage signal from a voltage-controlled oscillator, delay the voltage signal for a delay time to generate a first control signal, and to generate a second control signal according to the first control signal and the voltage signal. The scope circuit is configured to generate a first current signal in response to the second control signal and the voltage signal. The time-to-current converter is configured generate a second current signal according to the first control signal, the voltage signal, a first switch signal, and a test control signal.

Abstract: An apparatus includes control logic coupled to a phase detector circuit and an adjustable delay circuit. The control logic is configured to obtain a state of a first phase of an output signal of a phase interpolator relative to a second phase of a reference signal, and adjust a delay of the reference signal until the second phase matches the first phase. The control logic is further configured to measure a total delay of the reference signal when the second phase matches the first phase, and determine integral non-linearity of the phase interpolator at the first code based on the total delay. The control logic may further calibrate a first code of a phase interpolator based, at least in part, on the integral non-linearity.

Abstract: A digitally controlled delay line (DCDL) includes an input terminal, an output terminal, and a plurality of stages configured to propagate a signal along a first signal path from the input terminal to a selectable return stage of the plurality of stages, and along a second signal path from the return stage of the plurality of stages to the output terminal. Each stage of the plurality of stages includes a first inverter configured to selectively propagate the signal along the first signal path, a second inverter configured to selectively propagate the signal along the second signal path, and a third inverter configured to selectively propagate the signal from the first signal path to the second signal path. Each of the first and third inverters has a tunable selection configuration corresponding to greater than three output states.

Abstract: A delay locked loop circuit includes a first delay locked loop and a second delay locked loop having different characteristics. The first delay locked loop performs a delay-locking operation on a reference clock signal to generate a delay locked clock signal. The second delay locked loop performs a delay-locking operation on the delay locked clock signal to generate an internal clock signal.

Abstract: A timing detection circuit includes: a delay circuit in which a plurality of cascade connected delay elements are arranged in a matrix; a plurality of odd-numbered row column lines provided in each column for each set by dividing odd-numbered rows into a plurality of sets; a plurality of even-numbered row column lines provided in each column for each set by dividing even-numbered rows into a plurality of sets; a first logical operation circuit performs a logical operation on levels of the odd-numbered row column lines and outputs a first operation result to a second latch; a second logical operation circuit performs a logical operation on levels of the plurality of even-numbered row column lines and outputs a second operation result to a third latch; and a control circuit given the first operation result and controls charging of the odd-numbered and even-numbered row column lines based on the second clock.

Abstract: A delay line structure and a delay jitter correction method thereof are provided. The delay line structure comprises N delay units and N selectors. An output end of the N?1th delay unit is connected to a first input end of the N?1th selector and an input end of the Nth delay unit respectively, the N?1th selector inputs the N?1th selection signal, an output end of the Nth delay unit is connected to a first input end of the Nth selector, an output end of the Nth selector is connected to a second input end of the N?1th selector, and the Nth selector inputs the Nth selection signal. The time delay units and the selectors are stacked forwards according to the above-mentioned rule until the input ends of the first time delay units are connected with input signals and the output ends of the first selectors are connected with output signals.

Abstract: A nonvolatile memory device includes a memory cell array and an computation output circuit. The memory cell array includes a plurality of nonvolatile memory elements configured to store a plurality of weights respectively and a plurality of bit lines coupled to the plurality of nonvolatile memory elements according to a plurality of input signals. The computation output circuit is configured to generate a computation signal from voltages induced at the plurality of bit lines according to the plurality of input signals.

Abstract: A semiconductor device includes an internal clock generation circuit configured to generate an internal clock; a plurality of unit circuits configured to have a first unit circuit and a second unit circuit operating while being synchronized with an internal clock; a plurality of transfer circuits including a first transfer circuit configured to provide a first transfer path having a first delay time, and a second transfer circuit configured to provide a second transfer path having a second delay time different from the first delay time; and a delay compensation circuit configured to compare a first clock input to the first unit circuit through the first transfer path with a second clock input to the second unit circuit through the second transfer path, and to adjust the second delay time so that the adjusted second delay time matches the first delay time.

Abstract: A phase detection circuit may include an edge trigger circuit, a strobe generation circuit and a phase detector. The edge trigger circuit generates a falling clock signal and a rising clock signal based on a reference clock signal and a target clock signal. The strobe generation circuit generates a falling strobe signal and a rising strobe signal having pulse widths varying based on a phase relationship between the reference clock signal and the target clock signal. The phase detector generates a phase detection signal based on the falling clock signal, the rising clock signal, the falling strobe signal and the rising strobe signal.

Abstract: An automatic frequency calibration and lock detection circuit includes a frequency error generator circuit, an automatic frequency calibration signal generator circuit, and a lock flag generator circuit. The frequency error generator circuit generates a frequency error signal based on a reference frequency signal and an output frequency signal. The frequency error signal represents a difference between a frequency of the output frequency signal and a target frequency. The automatic frequency calibration signal generator circuit generates an automatic frequency calibration output signal and an automatic frequency calibration done signal based on the frequency error signal and a first clock signal. The lock flag generator circuit generates a lock done signal based on the frequency error signal, the automatic frequency calibration done signal and a second clock signal.

Abstract: A semiconductor apparatus receives a first clock signal and a second clock signal. The semiconductor apparatus configured to perform a training operation internally, the training operation being an operation of internally correcting a phase difference between the first clock signal and the second clock signal by dividing the first clock signal to generate multi-phase signals, detecting phase difference between the second clock signal and the multi-phase signals, and adjusting phases of the multi-phase signals according to a result of the detecting of the phase difference.

Abstract: Digital delay lock circuits and methods for operating digital delay lock circuits are provided. A phase detector is configured to receive first and second clock signals and generate a digital signal indicating a relationship between a phase of the first clock signal and a phase of the second clock signal. A phase accumulator circuit is configured to receive the digital signal and generate a phase signal based on values of the digital signal over multiple clock cycles. A decoder is configured to receive the phase signal and generate a digital control word based on the phase signal. A delay element is configured to receive the digital control word. The delay element is further configured to change the relationship between the phase of the first clock signal and the phase of the second clock signal by modifying the phase of the second clock signal according to the digital control word.

Abstract: Disclosed herein are methods for promoting neuronal outgrowth in a subject with a neuronal lesion in their CNS by administering effective amounts of a pro-regenerative OPN fragment, optionally with IGF1 and/or BDNF. A voltage gated potassium channel blocker can also be administered. Pharmaceutical compositions, devices for administration, and kits are also disclosed.

Abstract: Described is an apparatus comprising: a multi-modulus divider; and a phase provider to receive a multiphase periodic signal and operable to rotate phases of the multiphase periodic signal to generate an output which is received by the multi-modulus divider.

Abstract: A phase mixing circuit includes a first driver comprising 2n inverters configured to drive a first clock signal, where n is a positive integer, and a first selection circuit configured to couple each of the 2n inverters of the first driver to a first mixing node, on the basis of a weight having first to 2nth bits. The phase mixing circuit also includes a second driver comprising 2n inverters configured to drive a second clock signal and a second selection circuit configured to couple each of the 2n inverters of the second driver to the first mixing node, on the basis of an inverted signal of the weight.

Abstract: A clock generator can include a Fin Field Effect Transistor (FinFET) oscillator and a phased-locked loop (PLL). The FinFET oscillator can generate a FinFET signal. The PLL can generate an output clock signal based on a reference clock signal and the FinFET signal.

Abstract: A clock locking method of a memory device, may include performing an initial locking operation in a delay locked loop circuit before an internal voltage is stabilized, monitoring clock skew between a reference clock and a feedback clock using a window detection circuit after the internal voltage is stabilized, and performing a re-locking operation in the delay locked loop circuit using a dynamic delay control corresponding to the clock skew.

Abstract: A deskew system can be used to adjust signal characteristics such as pulse width and edge timing. In an example, a deskew system can include multiple timing control cells and each cell can operate in one of multiple different modes according to respective mode control signals. The modes can include at least a signal delay mode and a signal pulse width adjustment mode. In an example, a first cell in a deskew system can be configured to receive a test input signal at a first input node and, in response, provide a deskew output signal at a first output node. The deskew output signal can be based on the test input signal, a pulse width adjustment provided by the first cell, and on a delayed signal, corresponding to the input signal, that is provided by a subsequent cell in the series.

Abstract: Some examples described herein provide for an on-die virtual probe in an integrated circuit structure for measurement of voltages. In an example, an integrated circuit comprises a voltage-controlled frequency oscillator circuitry and a processor circuitry. The voltage-controlled frequency oscillator circuitry comprises a plurality of circuitry components and is configured to generate a signal having a frequency related to a supply voltage. The voltage-controlled frequency oscillator circuitry is disposed at a location of the integrated circuit proximal to the supply voltage being monitored. The processor circuitry is configured to identify a relationship between the frequency of the signal and the supply voltage. The processor circuitry is also configured to determine a value of the supply voltage associated with the signal based on the identified relationship. The processor circuitry further monitors on-die transient voltages at the location of the integrated circuit based on the value of the supply voltage.

Abstract: A signaling system is disclosed. The signaling system includes a first integrated circuit (IC) chip to receive a data signal and a strobe signal. The first IC includes circuitry to sample the data signal at times indicated by the strobe signal to generate phase error information and circuitry to output the phase error information from the first IC device. The system further includes a signaling link and a second IC chip coupled to the first IC chip via the signaling link to output the data signal and the strobe signal to the first IC chip. The second IC chip includes delay circuitry to generate the strobe signal by delaying an aperiodic timing signal for a first time interval and timing control circuitry to receive the phase error information from the first IC chip and adjust the first time interval in accordance with the phase error information.

Abstract: Apparatuses and methods for adjusting a phase mixer circuit are disclosed. An example apparatus includes a shift register that includes a plurality of registers coupled in series to one another. The plurality of registers are grouped into a first group of registers and a second group of registers. The first group of registers includes first and second registers. The second group of registers includes a third register. The first and second registers of the first group of registers are configured to receive in common an output of the third register of the second group of registers so that both the first and second registers store the output of the third register responsive to a shift clock.

Abstract: The present disclosure relates to adjusting a reading speed of a memory system. A method for adjusting a reading speed of a memory system, including: generating an alternating sequence signal in which high levels and low levels appear alternately, associated with an output delay of the memory system; generating a reference signal having a predetermined frequency and a reference delay; generating a comparison result signal indicating a range of a difference between an output delay and the reference delay based on an alternating sequence signal and a reference signal; and determining whether a value indicated by a comparison result signal is a predetermined value, so as to adjust the reading speed of the memory system based on a determination result.

Abstract: A phase detection circuit includes a first phase detection path having a first input to receive a first signal, and a second input to receive a second signal. Asynchronous transition detection circuitry detects an early/late relationship between the first signal and the second signal when at least one of the first signal and the second signal transitions from a first state to a second state. Output circuitry generates a control signal with a value based on the early/late relationship.

Abstract: The systems and methods for bus ownership in a system power management interface (SPMI) bus may include two or more masters on the SPMI bus, and bus ownership may be passed between masters. The current owner of the bus is responsible for providing a clock signal on the clock line of the SPMI bus. To avoid problems caused by ringing of the clock signal being sent on a conductor that exceeds the SPMI specification, the original master (from whom bus ownership is being transferred) holds the clock line of the SPMI bus at a logical low for a clock delay value that is based on conductor length.

Abstract: Digital low-dropout micro voltage regulator configured to accept an external voltage and produce a regulated voltage. All active devices of the voltage regulator are digital devices. All signals of the voltage regulator, except the first voltage and the regulated voltage, may be characterized as digital signals. Some active devices of the voltage regulator may be physically separated from other active devices of the voltage regulator by active devices of non-voltage regulator circuitry.

Abstract: A delay chain circuit with series coupled delay elements receives a reference clock signal and outputs phase-shifted clock signals. A multiplexer circuit receives the phase-shifted clock signals and selects among the phase-shifted clock signals for output as in response to a selection signal. The selection signal is generated by a control circuit from a periodic signal having a triangular wave profile. A sigma-delta modulator converts the periodic signal to a digital signal, and an integrator circuit integrates the digital signal to output the selection signal. The selected phase-shifted clock signal is applied as the reference signal to a phase locked loop which generates a spread spectrum clock signal.

Abstract: A phase interpolating (PI) system includes: a phase-interpolating (PI) stage configured to receive first and second clock signals and a multi-bit weighting signal, and generate an interpolated clock signal, the PI stage being further configured to avoid a pull-up/pull-down (PUPD) short-circuit situation by using the multi-bit weighting signal and a logical inverse thereof (multi-bit weighting_bar signal); and an amplifying stage configured to receive and amplify the interpolated clock signal, the amplifying stage including a capacitive component; the capacitive component being tunable; and the capacitive component having a Miller effect configuration resulting in a reduced footprint of the amplifying stage.

Abstract: A reference sampling Type-I fractional-N PLL directly samples the reference clock and therefore does not use a reference buffer. Here, a phase-detector is a passive sampling switch which neither consumes any power nor generates any noise. Therefore, all the major contributors of in-band phase-noise are eliminated by the reference sampling Type-I fractional-N divider. A double sampling phase-detector with a switched-capacitor passive voltage interpolator circuit is used to achieve fractional-N output. To achieve a high resolution of the voltage interpolator or the switched capacitor, a sigma-delta modulator is used.

Abstract: A delay circuit includes a coarse delay circuit, a header circuit, and a phase mixing circuit. The coarse delay circuit is configured to delay a reference clock signal to generate a first clock signal and a second clock signal and to change each phase of the first clock signal and the second clock signal by double a unit phase. The header circuit is configured to receive the first clock signal and the second clock signal and to generate a first phase clock signal and a second phase clock signal, between which a phase difference corresponds to half of the unit phase. The phase mixing circuit is configured to mix phases of the first phase clock signal and the second phase clock signal to generate an output clock signal.

Abstract: In described examples, a first clock generator generates an output clock signal in response to an input reference signal and in response to a feedback signal that is generated in response to the output clock signal. A code generator generates a code in response to the input reference signal. A loss detector generates an indication of a loss of the input reference signal in response to the feedback signal and at least two codes generated by the code generator.

Abstract: A clock distribution network includes a global driver configured to receive a pair of clock signals to generate a pair of global clock signals, a clock transmission driver configured to amplify the pair of global clock signals to generate a pair of transmission clock signals, a first boosting circuit configured to boost voltage levels of the pair of transmission clock signals to generate a pair of first boosted clock signals, a first local driver configured to shift voltage levels of the pair of first boosted clock signals to generate a pair of first local clock signals, a second boosting circuit configured to boost voltage levels of the pair of first boosted clock signals to generate a pair of second boosted clock signals, and a second local driver configured to shift voltage levels of the pair of second boosted clock signals to generate a pair of second local clock signals.

Abstract: A signal generator has a nominal frequency control input and a modulation frequency control input and comprises an oscillator, with a first set of capacitors at least partially switchably connectable for adjusting a frequency of the oscillator as part of a phase-locked loop, and a second set of capacitors comprised in a modulation stage of the oscillator, switchably connectable for modulating the frequency and controlled by the modulation frequency control input; a modulation gain estimation stage configured to determine a frequency-to-capacitor modulation gain; and a modulation range reduction module configured for clipping a modulation range of the oscillator to a range achievable using the second set of capacitors, using the modulation gain averaging out, in time, a phase error caused by the said clipping; and mimicking the said clipping, additively output to the nominal frequency control input to compensate said PLL for the said modulation.

Abstract: A delay locked loop circuit includes a first delay locked loop and a second delay locked loop having different characteristics. The first delay locked loop performs a delay-locking operation on a reference clock signal to generate a delay locked clock signal. The second delay locked loop performs a delay-locking operation on the delay locked clock signal to generate an internal clock signal.

Abstract: An eye width monitor (EWM) for a clock and data recovery (CDR) circuit includes a delay circuit, a first multiplexer (MUX) and a calibration circuit. The delay circuit includes an input terminal and an output terminal. The first MUX, coupled to the delay circuit, includes a first input terminal, a second input terminal and an output terminal. The first input terminal of the first MUX is coupled to a clock input terminal of the EWM. The second input terminal of the first MUX is coupled to the output terminal of the delay circuit. The output terminal of the first MUX is coupled to the input terminal of the delay circuit. The calibration circuit, coupled to the delay circuit, is configured to receive an oscillation clock from the delay circuit and receive a reference clock, and calibrate the oscillation clock with the reference clock.

Abstract: A memory device includes a delay locked loop (DLL), a clock compensating circuit, and a data input/output (I/O) circuit. The DLL outputs a first clock signal and a second clock signal. The clock compensating circuit adjusts a voltage level of an output node and generates an inner clock signal based on the voltage level of the output node. The data I/O circuit outputs data to an outside based on the inner clock signal. The clock compensating circuit includes first and second pulse adjusting circuits. The first pulse adjusting circuit connected to a first output node and outputs a first adjusting current based on the first clock signal and a voltage level of the first output node. The second pulse adjusting circuit connected to a second output node and outputs a second adjusting current based on the second clock signal and a voltage level of the second output node.

Abstract: A clock synchronization signal generator generates a dead time in which gates of both of two switching elements included in a switching circuit are in an off state, and generates the dead time for controlling a plurality of pulses having different widths to pulses having a constant width, which is output by the switching circuit.