Abstract: All embodiments of the present invention basically include an upper transistor and a lower transistor connected in series between a power supply and ground. The upper transistor and the lower transistor have a shared source (or drain) terminal which becomes a single bidirectional node. They further comprise a sensing gate and a logic gate. The sensing inverter has a function of sensing a voltage at the single bidirectional node and comparing it with an input transition voltage since an input terminal of the sensing inverter is connected to the single bidirectional node. An initial voltage at the single bidirectional node of the filter-based lock-in circuit is almost the same as the input transition voltage of the sensing inverter, where the input transition voltage is an input voltage which causes an output voltage to be V DD 2 .

Abstract: Data is recovered in an asynchronous environment where a sampling clock is generated internally, and is not externally frequency locked, by using programmable delay modules each providing a number of delay tap outputs. To recover data, two of the delay modules are used with a first delay module designated as a monitor delay module to monitor the clock edge transitions, while a second delay module is designated as a data delay module that provides a data output. A controller provides for incrementing or decrementing the tap delay of both delay modules to assure clock data falls at the center of the monitoring window as determined using the monitor delay module. The controller further selects between the two delay modules as to which provides data and which is used as for clock edge monitoring when the clock edge transitions drifts to an edge of the monitoring window.

Abstract: Provided are a circuit and a method of detecting clock delay where the circuit to detect clock delay includes a delay detection circuit and a clock forwarding circuit, the delay detection circuit detects a delay between a predetermined output clock signal and an input clock signal, if the detected delays are identical to one another, the circuit generates an initial parameter corresponding to the delay and if the detected delays are not identical to one another, continuously detects the delay until the detected delays are identical to one another, and generates a reset control signal in response to a system reset signal or a predetermined internal reset signal; the clock forwarding circuit loads and unloads the input data in response to the initial parameter, the circuit to detect clock delay can automatically detect the clock delay necessary for setting the initial parameter of the clock forwarding circuit and reset a master circuit and an external circuit that interfaces with the master circuit, thus perfor

Abstract: A clock and data recovery circuit includes even and odd latches, a detection module, a clock recovery module, a compensating module, and a data recovery module. The even and odd latches are operably coupled to latch even and odd bits of a digital stream of data based on a recovered clock to produce even and odd latched bits. The detection module is operably coupled to produce a phase representative pulse stream based on the even and odd latched bits. The clock recovery module is operably coupled to produce the recovered clock based on the phase representative pulse stream. The compensating module is operably coupled to adjust biasing of the even and odd latches based on operating parameter changes of the clock and data recovery circuit. The data recovery module is operably coupled to produce recovered data from the even and odd latched bits based on the recovered clock.

Abstract: A cascade comparator and a control method thereof are provided. By applying multi-phase clock signals to a plurality of comparators when the plurality of comparators are cascaded together so that each comparator is regenerated before the preceding comparator is reset, a hold switch does not need to be provided between the comparators. Therefore, it is possible to reduce the size and parasitic components of a circuit, operate the circuit at a high speed, remove a glitch caused by any hold switch, and accordingly improve system linearity.

Abstract: A pulse width modulation circuit of the present invention changes a voltage of a charging circuit based on an input signal voltage and in synchronization with a first switching signal; changes, during a predetermined second period following a first period during which the voltage of the charging unit is changed, the voltage of the charging unit in an opposite direction to a direction in which the voltage is changed during the first period, based on a constant bias current; detects time starting from when the second period starts to when the voltage of the charging unit reaches a predetermined reference voltage; and generates, based on the detected time which is repeatedly output each time the first switching signal is output, a pulse signal having a pulse width of the time.

Abstract: A methodology is disclosed that enables the delay stages of an analog delay locked loop (DLL) or phase locked loop (PLL) to be programmed according to the operating condition, which may depend on the frequency of the input reference clock. The resulting optimized delay stages allow for a broad frequency range of operation, fast locking time over a wide range of input clock frequencies, and a lower current consumption at high clock frequencies. Better performance is achieved by allowing the number of analog delay stages active during a given operation to be flexibly set. The deactivation or turning off of unused delay stages conserves power at higher frequencies. The high frequency range of operation is increased by using a flexible number of delay stages for various input clock frequencies. Because of the rules governing abstracts, this abstract should not be used to construe the claims.

Abstract: Method and apparatus for a bimodal source synchronous interface for a receiver module is described. A first input cell with a first delay chain and a first register block is provided for receipt of a forwarded clock signal by the first delay chain. A second input cell with a second delay chain and a second register block is provided for receipt of a data signal by the second delay chain. The second input cell is configured such that output from the second delay chain is coupled to a data input of the second register block. The first input cell and the second input cell may be operated in either a first modality or a second modality. The first modality may be for interfacing to a synchronous integrated circuit interface. The second modality may be for interfacing to a synchronous network/telecommunications interface.

Abstract: A pulse generation apparatus has an encoder that outputs an encoder signal in a cycle corresponding to each driven operation of a driving target medium by a drive amount per unit. The pulse generation apparatus generates a pulse on the basis of the encoder signal that is outputted by the encoder. The amplitude of the signal changes in a cyclic manner. The pulse generation apparatus has a switching unit that receives the encoder signal and then switches either the amplitude of the signal or a threshold depending on the driven speed of the driving target medium so as to change the number of signal waves that exceed the threshold depending on the driven speed of the driving target medium. The pulse generation apparatus also has a pulse generating unit that generates a pulse having the same cycle as that of the signal wave that exceeds the threshold.

Abstract: A clock recovery system includes a sampler that is configured to sample an input data signal in synchronization with a modulated clock signal to generate a sample of the input data signal. A phase comparator is configured to compute a position of a transition edge of the input data signal using the sample data signal, and to compare the computed position with a position of an edge of the modulated clock signal to generate a comparison result. An edge counter is configured to count transition edges of the sample data signal. A controller is configured to generate first and second control signals based on the comparison result and the count of the transition edges. A clock phase modulator is configured to generate the modulated clock signal by adjusting a phase of an input clock signal responsive to the first and second control signals, such that the phase is increased in response to the first control signal and reduced in response to the second control signal.

Abstract: A communication system, reception apparatus and method, recording medium and program are provided. A technique is provided wherein, even where means for synchronizing a reception clock with a transmission clock is not available, data transmitted can be received accurately with a high transmission capacity assured. The frequency of a transmission clock used by an apparatus of the sender side of data is set equal to that of a reception frequency used by an apparatus on the receiver side. If a sampling timing and a changing point of the value of transmission data do not coincide with each other, then the value of 1 or 0 of a noticed bit is decided from a sample value. However, if they coincide with each other, then the sample value assumes an intermediate value different from 1 and 0, and the value of the noticed bit is decided as a value opposite to the value of the immediately preceding bit.

Abstract: A phase-locked loop (PLL) circuit includes a phase/frequency detector (PFD), a charge pump, a loop filter, a control circuit, a VCO, and a feedback circuit. The control circuit generates a digital control signal in response to the up signal, the down signal, and the oscillation-control voltage. The VCO generates an output signal of which a frequency is changed in response to the oscillation-control voltage and the digital control signal. Accordingly, the PLL circuit can automatically tune the frequency of the output signal of a VCO using a digital circuit having a simple structure.

Abstract: The phase locked loop (PLL) with adjustable phase shift is described. The PLL includes a voltage controlled oscillator which is capable of generating multiple phase shifted output signals, and multiple phase detectors capable of determining the phase differences between the output signals and a reference clock. The PLL further includes a weighting device capable of weighting the phase differences and generating a control signal for the voltage controlled oscillator.

Abstract: A methodology is disclosed that enables the delay stages of an analog delay locked loop (DLL) or phase locked loop (PLL) to be programmed according to the operating condition, which may depend on the frequency of the input reference clock. The resulting optimized delay stages allow for a broad frequency range of operation, fast locking time over a wide range of input clock frequencies, and a lower current consumption at high clock frequencies. Better performance is achieved by allowing the number of analog delay stages active during a given operation to be flexibly set. The deactivation or turning off of unused delay stages conserves power at higher frequencies. The high frequency range of operation is increased by using a flexible number of delay stages for various input clock frequencies. Because of the rules governing abstracts, this abstract should not be used to construe the claims.

Abstract: A terminal is wirelessly connected to a base station. The terminal has a timer and a controller. The timer has a register for storing a beacon interval as a comparison value. The timer also includes a beacon counter for counting timer clocks. The timer also includes a comparator for generating an interrupt signal when an output value of the register and a count value of the counter match. The controller causes the counter to start counting when it receives a beacon for the first time. The controller causes the register to store the count value of the beacon counter when it receives a beacon next time. Since the beacon interval is measured using the timer clock in the terminal, instead of using the beacon interval information included in the beacon, it is unnecessary to strictly match the clock precision of the base station and the terminal, and therefore the cost of the system decreases.

Abstract: The claimed subject matter provides systems and/or methods that facilitate controlling timing dependencies in a mixed signal circuit. Timing performance associated with a horizontal scanner and an analog to digital converter (ADC) can be monitored. Moreover, data related to the monitored timing performance can be leveraged to modify timing parameter(s) of clocks that coordinate operations of the horizontal scanner and the ADC (e.g., and/or digital component(s) included in the mixed signal circuit). For example, the clocks associated with the horizontal scanner and the ADC can be independently tuned to optimize mixed signal circuit performance.

Abstract: System and method for synchronizing multiple devices coupled to a system timing module (STM) via respective first transmission media, wherein two or more of the respective first transmission media have different respective transmission times. The STM and devices share a common clock, in phase and with respect to a common reference. Each device is configured to transmit respective signals to the STM within a common clock cycle. Respective delays corresponding to the devices are determined based on the respective transmission times, where the respective delays are applicable to respective signals received from the devices to synchronize received corresponding pulses in the signals to within a common clock cycle. The respective delays are applied to respective signals received from the plurality of devices to synchronize received corresponding pulses in the signals to within the common clock cycle, after which the STM is operable to trigger the devices as a single device.

Abstract: There are provided, in a clock generator for generating a plurality of output clock signals, an apparatus and method for synchronizing the clock generator to an input reference clock in the presence of a jittery input clock provided to the clock generator from a PLL. The clock generator and the PLL each have a divider with the same ratio. The apparatus includes a synchronizer (205) and a state machine (210). The synchronizer receives the input reference clock and the jittery input clock, and generates there from a synchronized input clock signal with respect to the jittery input clock. The state machine receives the synchronized input clock signal and the jittery input clock, synchronizes with the synchronized input clock signal using the jittery input clock, and abstains from a re-synchronizing operation when the jittery input clock has a jitter of up to a pre-defined maximum number of clock widths.

Abstract: The ability to change from a first bus ratio to a second bus ratio without draining the transaction queues of a processor.

Abstract: A semiconductor integrated circuit includes a memory circuit, an oscillator circuit which generates an internal clock signal, based on control information held in the memory circuit, and a logic circuit which generates control information that causes the frequency of the internal clock signal to coincide with the frequency of an external clock signal. The internal clock signal is used for a synchronous operation of an internal circuit. Even if an error (undesired variation) occurs in the oscillation characteristic of the oscillator circuit due to process variations, it is possible to cause an internal clock signal frequency to coincide with an external clock signal frequency corresponding to a target frequency without the need for external attachment of a crystal oscillator and the input of an external clock signal.

Abstract: A frequency synchronizing circuit includes a first raising unit configured to raise a received signal by a first power to obtain a first raised signal, a filter to suppress noise in the first raised signal to obtain a filtered signal, a second raising unit configured to raise the filtered signal by a second power to obtain a second raised signal, an estimating unit configured to estimate a frequency offset in the received signal based on the second raised signal to obtain an estimated value, and an offset-cancelling unit configured to cancel the estimated value from the received signal, to output an offset cancelled signal.

Abstract: A measuring apparatus having a frequency-swept heterodyne-type frequency converter equipped with a frequency-swept signal source and a multiplier includes means for detecting the timing of reference burst signals that have been subjected to frequency conversion by the frequency converter, with the frequency of the output signals of the frequency-swept signal source locked; means for generating periodic pulse signals; and means for adjusting the phase relationship between the pulse signals and the reference burst signals using the detected timing; and means for sweeping the frequency of the output signals of the frequency-swept signal source using pulse signals that have been subjected to a phase relationship adjustment.

Abstract: This invention discloses a system and method for dynamically managing voltage and frequency in an integrated circuit (IC), comprising a plurality of ring oscillators for generating a plurality of continuous pulses with frequencies reflecting the process parameter, operating voltage and temperature effects in the IC, a period generator for generating at least one gating period with a predetermined duration, a plurality of counters coupling to the plurality of ring oscillators as well as the period generator for counting the number of the continuous pulses in the gating period, at least one selector for selecting a predetermined number counted by the plurality of counters, and at least one voltage-and-frequency adjustment circuitry for adjusting one or more operating voltages or one or more clock frequencies in the IC based on the predetermined number selected by the selector, wherein the IC operating voltage or clock frequency correlates with the ring oscillator frequencies.

Abstract: A module includes a semiconductor device, a phase adjustment circuit generating a second clock so that a phase adjustment signal output from the semiconductor device and a first clock have a predetermined phase relationship, and an output circuit that is provided in the semiconductor device and generates the phase adjustment signal from the second clock.

Abstract: A sampling-error phase compensating device and a method thereof for sequentially sampling data signals and outputting sampled data signals.

Abstract: A methodology is disclosed that enables the delay stages of an analog delay locked loop (DLL) or phase locked loop (PLL) to be programmed according to the operating condition, which may depend on the frequency of the input reference clock. The resulting optimized delay stages allow for a broad frequency range of operation, fast locking time over a wide range of input clock frequencies, and a lower current consumption at high clock frequencies. Better performance is achieved by allowing the number of analog delay stages active during a given operation to be flexibly set. The deactivation or turning off of unused delay stages conserves power at higher frequencies. The high frequency range of operation is increased by using a flexible number of delay stages for various input clock frequencies. Because of the rules governing abstracts, this abstract should not be used to construe the claims.

Abstract: A circuit for balancing delays through true and complement phases of complementary drivers includes: a first driver; a second driver; a first delay device coupled to an input of the first driver and having an input coupled to an input signal node; a second delay device coupled to an input of the second driver and having an input coupled to the input signal node through a first inverter, wherein the first and second delay devices are clocked such that an input signal reaches the first driver simultaneously with an inverted input signal reaching the second driver.

Abstract: A method and system for synchronization between a transmitter and a receiver in a communication system is provided. The receiver receives a plurality of signals from the transmitter. According to this method, a frequency burst is detected in the received signal at the receiver. The detected frequency burst is then validated on the basis of a synchronization burst in the received signal. Finally, the frequency and timing information present in the received signal is acquired for synchronization with the transmitter. The frequency and timing information is acquired on the basis of the validated frequency burst.

Abstract: Apparatus, systems, and methods are disclosed that operate to generate a periodic output signal from a periodic input signal, obtain a plurality of samples of a phase difference between the output signal and the input signal, and to adjust a phase of the output signal based on the samples of the phase difference. Additional apparatus, systems, and methods are disclosed.

Abstract: Random number generators are used for entertainment in gambling, lotteries and video gaming devices. True Random Number Generators, as are now currently defined, must be actuated by a physical noise source, typically based on the uncertainty of the phase differences of a stable and an unstable autonomous oscillator. In this invention an autonomous random frequency modulated oscillator driven by a self contained pseudo-random number generator outputs three loosely correlated random binary streams. Included in the invention is a hardware method for proving wandering phase differences and also the existence of a colored random distribution of concatenated nibbles.

Abstract: An semiconductor device, containing logic blocks and high speed connections between the blocks, where the connections utilize current direction for logic representation rather than voltage level. Such high speed connections comprise differential transmitters which drive a pair of adjacent wires with differential current pulses that are received by a differential receiver which may be put in a low power state between transmissions.

Abstract: Provided are a data recovery apparatus and method for recovering (parallel) data from serial data received via a high-speed serial link with a reduced data recovery error rate. The data recovery apparatus includes a clock signal generating circuit and a data recovery circuit. The clock signal generating circuit generates at least two clock signal groups including first and second clock signal groups with different phases for alternate use in the data recovery circuit. The data recovery circuit recovers the data from the serial data by oversampling the serial data using one of the at least two clock signal groups selected based on the number of rising edges of sampling clock signals of the selected clock signal group being within an eye open region of the serial data.

Abstract: In a symbol timing detector, a correlator calculates a correlation value for a received radio packet signal. A peak detector compares the correlation value with a threshold value to be used, and sends, upon a correlation value detected larger than the threshold value, a detection signal to a symbol synchronous processor. A threshold value to be used for the peak detector is set different, after the first peak detected, between a predetermined estimation period and a period other than the former. A first peak is detected with a threshold value under a severer condition in the period other than the estimation period, and the next peak detection timing is estimated upon the first peak detected. A synchronization detecting position is determined, when no correlation peak is detected at the estimated timing, to output a sync detection signal.

Abstract: Methods, devices and systems are provided for bit synchronizing multiple serial bitstreams (106) with a common clock signal (116). Activity occurring in each bitstream is detected (304) for each of a plurality of phases corresponding to cycles of the common clock signal. One of the plurality of phases is selected (308) for each of the serial bitstreams based upon the activity detected within the selected phase. Data is then extracted (322) from the selected phase for each of the serial bitstreams using the common clock signal to thereby bit synchronize each of the plurality of serial bitstreams to each other.

Abstract: A gate drive circuit including dead time control circuits delaying on periods of switching elements S1, S2 based on a control signal; driving circuits; and monitor circuits. Each of the monitor circuits includes a current source and an N-type FET in which the source is connected to the gate of one of the switching elements; the drain is connected to the current source; and a predetermined voltage is applied to the gate. When an off state of one of the switching elements is detected, the N-type FET Qn outputs an off signal to the dead time control circuit on the other switching element side. Based on the off signal, the dead time control circuit on the other switching element side terminates an operation of delaying the on period of the other switching element.

Abstract: A wireless communications device may include a wireless receiver for receiving signals comprising alternating known and unknown symbol portions, and a demodulator connected thereto. The demodulator may include a channel estimation module for generating respective channel estimates for a prior unknown symbol portion(s), current unknown symbol portion and for future unknown symbol portion(s). An autocorrelation module may generate autocorrelation matrices for the prior, current and future unknown symbol portions. A channel match filter module may generate respective channel matching coefficients for the prior and current/future unknown symbol portions, and a factorization module may divide the autocorrelation matrices into respective upper and lower autocorrelation matrices. A transformation module may transform the channel matching coefficients into upper and lower channel matching coefficients.

Abstract: A wireless communications device may include a wireless receiver receiving signals having alternating known and unknown symbol portions over a channel, and a demodulator systolic array. The demodulator systolic array may include a channel estimation module generating respective channel estimates for each unknown symbol portion based upon the known symbol portions. An autocorrelation module may generate autocorrelation matrices based upon the channel estimates. A channel match filter module may generate respective channel matching coefficients for the unknown symbol portions, and a factorization module may divide the autocorrelation matrices into respective upper and lower autocorrelation matrices. A transformation module may transform the channel matching coefficients into upper and lower channel matching coefficients.

Abstract: A method for communicating data over a serial interface between a master device and at least one slave device is disclosed. A master device generates a preamble that is attached to a data block for transmission over the serial interface between a master device and at least one slave device. Upon receipt of the control word at the at least one slave device, the preamble is detected by the slave device. Upon detection of the preamble, the slave device is enabled to respond to information within the control word as appropriate.

Abstract: A system and method use an aligning device to align clock signals of two logic devices before data transfer between them. In this example, the aligning device aligns a clock signal of a sequencer with a clock signal of a storage device before the sequencer transfers data to the storage device. The aligning device includes a phase detector that receives a first reference clock signal, which is used to control the storage device, and a delayed signal, which is used to control the sequencer, and generates a comparison clock signal. The comparison clock signal is filtered before being used to control a phase of a second reference clock signal, which is related to the first reference clock signal. The phase controlled second clock signal is an aligning clock signal that is feed back to a delay device to produce one or more subsequent delay device clock signals that are aligned to the storage device clock or first reference clock signal.

Abstract: In order to prevent a signal of a signal wiring from receiving a bad influence due to a power supply capacitor, provided is a semiconductor including a high reference potential terminal and a low reference potential terminal composing power supply voltage terminals; a first MOS capacitor in which a gate of a p-channel MOS field effect transistor is connected to the low reference potential terminal, and a source and a drain are connected to the high reference potential terminal; and a first signal wiring connected to the gate via a parasitic capacitor and a signal in the low reference potential is supplied at the time of starting the power supply.

Abstract: A system and method for generating a clock signal having spread spectrum modulation. The method involves generating a clock signal by generating edge positions for edges of the clock signal from a digital representation of a timing for each edge to impart spread spectrum modulation to the clock signal. A programmable modulator is provided that generates digital values representing edge positions for edges of a clock signal based on at least one of a time-varying period value and a time-varying duty-cycle value. The programmable modulator may comprise a first circuit, called a period modulation circuit, that generates a time-varying digital period value, and a second circuit, called a duty-cycle modulation circuit, that generates a time-varying digital duty-cycle value. The time-varying period values and time-varying duty cycle values are processed to produce a digital edge position value that specifies an edge position for a clock signal.

Abstract: An apparatus and method is disclosed to compensate for skew and asymmetry of a locally processed system clock used to synchronize an output signal, e.g., a data signal or a timing signal, from a logic circuit, for example a memory device. A first phase detector, array of delay lock loop (DLL) delay elements and accompanying circuitry are disclosed to phase-lock the rising edge of the output signal with the rising edge of the system clock XCLK signal. Additionally, a comparator circuit, a register delay, an array of DLL delay elements and accompanying circuitry are disclosed to add or subtract delay from the falling edge of the DQ signal in order to produce a symmetrical output of the DQ signal.

Abstract: A multimedia processing system and method thereof are provided. The system and method provide for synchronizing a first clock of a multimedia decoder of a first multimedia processing device to a second clock of a multimedia encoder of a second multimedia processing device, synchronizing a first timing reference of the multimedia decoder to a second timing reference of the multimedia encoder, receiving, at a network interface of the first multimedia processing device, an encoded multimedia data stream from a network interface of the second multimedia processing device, wherein the encoded multimedia data stream is encoded by the multimedia encoder based on the second clock and the second timing reference, and decoding the encoded multimedia data stream at the multimedia decoder based on the first clock and the first timing reference.

Abstract: A system and method are disclosed to generate and terminate clock shift modes during initialization of a synchronous circuit (e.g., a delay-locked loop or DLL). Upon initialization, the DLL is entered into a ForceSL (Force Shift Left) mode and an On1x mode (i.e., left shifting on each clock cycle). The feedback clock that tracks the phase of the reference clock (which, in turn, is derived from the system clock) is initially delayed in a coarse phase detector prior to applying it to the coarse phase detection window. Two delayed versions of the feedback clock are sampled by the reference clock to generate a pair of phase information signals, which are then used to establish an advanced phase equal (APHEQ) signal. The APHEQ signal advances onset of the PHEQ (phase equalization) phase and is used to terminate the ForceSL and On1x modes, thereby preventing wrong ForceSL exit due to clock jitter or feedback path overshooting during On1x exit.

Abstract: A multiplicity of electronic devices is provided to generate triangular wave signals variable between an upper and lower limit voltages by charging or discharging capacitors. One of the triangular wave signals serves as a master triangular wave signal for controlling the phases of the remaining (or slave) triangular wave signals. A detection signal is generated every time the master triangular wave signal reaches predetermined threshold levels. In response to the detection signal, a capacitor associated with one slave triangular signal is promptly discharged to bring the slave triangular signal to the lower limit voltage, whereby the respective slave triangular wave signals are synchronized to be offset in phase relative to the master triangular wave signal by respective predetermined phase angles.

Abstract: An operation signal generator circuits are provided to continue to operate an object circuit which is not operated unless an operation signal arrives for the purpose of power consumption reduction, and thereby the object circuit is put into dummy operation. This enables an influence of environmental factors, which may affect operation of the circuit element included in the object circuit, to be maintained in a stable or balanced state, and also enables stable and accurate operation of the object circuit at the time of actual operation, with reduced power consumption.

Abstract: The disclosed embodiments relate to circuits that produce synchronized output signals. More specifically, there is provided a synchronization circuit adapted to receive an input signal, the synchronization circuit comprising a delay monitor adapted to produce a delayed input signal, a counter adapted to determine a difference between the input signal and the delayed input signal and produce a coarse timing signal in response thereto, a circuit adapted to produce a fine timing signal based on the input signal, and a circuit adapted to combine the coarse timing signal and the fine timing signal to produce an output signal.

Abstract: A radio frequency generating system comprises a synchronization board that receives an external clock signal from a clock source and generates multiple copies of the external clock signal. Each of a plurality of signal generation board receives a copy of the external clock signal from the synchronization board. Each signal generation board comprises a plurality of direct digital synthesizers that are synchronized using the external clock signal.

Abstract: A module includes a semiconductor device, a phase adjustment circuit generating a second clock so that a phase adjustment signal output from the semiconductor device and a first clock have a predetermined phase relationship, and an output circuit that is provided in the semiconductor device and generates the phase adjustment signal from the second clock.

Abstract: This invention discloses a system and method for dynamically managing voltage and frequency in an integrated circuit (IC), comprising a plurality of ring oscillators for generating a plurality of continuous pulses with frequencies reflecting the process parameter, operating voltage and temperature effects in the IC, a period generator for generating at least one gating period with a predetermined duration, a plurality of counters coupling to the plurality of ring oscillators as well as the period generator for counting the number of the continuous pulses in the gating period, at least one selector for selecting a predetermined number counted by the plurality of counters, and at least one voltage-and-frequency adjustment circuitry for adjusting one or more operating voltages or one or more clock frequencies in the IC based on the predetermined number selected by the selector, wherein the IC operating voltage or clock frequency correlates with the ring oscillator frequencies.