Abstract: A phase detector generates a first output signal if a feedback clock signal leads a reference clock signal by more than a first time. The phase detector generates a second output signal if the feedback clock signal lags the reference clock signal by more than a second time. If the feedback clock signal either leads the reference clock signal by less than the first time or lags the reference clock signal by less than the second time, neither output signal is generated. The phase detector may be used in a delay-lock loop in which the first and second output signals increase or decrease a delay of the reference clock signal by respective first and second delay increments. In such case, the each of the first and second delay increments should be less than the sum of the first and second times.

Abstract: Power switching systems often benefit from controlling the instant at which the power devices change state so as to minimize dissipation in these devices. Such systems often require fairly tight tolerances on reactive components and a relatively narrow frequency operating range to be certain these switching times occur as intended. This invention defines a system that can adapt the required switching instant over very wide changes in the reactive components.

Abstract: A lock-detection circuit that can set an acceptable phase-error range adapted to define a locked state and/or an unlocked state at a constant rate without being affected by a frequency and that can detect the locked state and/or the unlocked state with precision without being affected by various fluctuations and variations, and a PLL circuit including the lock-detection circuit. The range corresponding to a phase difference between first and second output signals is determined to be a locked-state range, where the phase of each of the first and second output signals delays or advances with reference to that of an oscillation-output signal transmitted from a voltage-controlled-oscillation circuit.

Abstract: A digital phase detector has a plurality of first delay elements through which a first clock is delayed, a plurality of second delay elements through which a second clock is delayed, and a plurality of data holding circuits. The data holding circuits latch the first clock successively delayed through the first delay elements and hold a digital value representing a relative phase difference, in accordance with the second clock successively delayed through the second delay elements. Therefore, the phase detection resolution of the digital phase detector can be improved.

Abstract: A skew-tolerant digital phase detector is provided. Specifically, a detector is provided in the digital phase detector to detect certain failure conditions that may result from clock skew and duty cycle distortion. If the condition is detected, an adjusted signal is generated and the adjusted signal is synchronized with the reference signal. By using the generated signal to provide a lock if certain conditions arise, adjustment errors resulting from duty cycle distortion and clock skew can be minimized.

Abstract: A phase-locked loop circuit has a fractional-frequency-interval phase frequency detector, a charge pump, an oscillator, and a divider. The fractional-frequency-interval phase frequency detector has a phase frequency detector unit that is utilized as or comprises a plurality of phase frequency detector units. The divider is responsive to the oscillator and provides divider values for dividing an oscillator frequency by the divider values to provide a feedback frequency of a feedback loop signal of the phase-locked loop circuit. A reference input frequency is input as a first input into the phase frequency detector unit. The feedback frequency is input and selectively delayed as second inputs into the phase frequency detector unit so that the second inputs are aligned for input according to the reference input frequency and an oscillator frequency is, in effect, responsive to the phase frequency detector units and allowed to be divided by a fractional-integer divider value.

Abstract: A phase detector generates a first output signal if a feedback clock signal leads a reference clock signal by more than a first time. The phase detector generates a second output signal if the feedback clock signal lags the reference clock signal by more than a second time. If the feedback clock signal either leads the reference clock signal by less than the first time or lags the reference clock signal by less than the second time, neither output signal is generated. The phase detector may be used in a delay-lock loop in which the first and second output signals increase or decrease a delay of the reference clock signal by respective first and second delay increments. In such case, the each of the first and second delay increments should be less than the sum of the first and second times.

Abstract: A gated phase-frequency detector circuit includes a phase-frequency detector and a multiplexer circuit. The phase-frequency detector is arranged to provide UP and DOWN signals responsive to a reference clock signal and a feedback signal. Further, the phase-frequency detector includes a first flip-flop that provides the UP signal, a second flip-flop that provides the DOWN signal, and a clear logic circuit. One input of the multiplexer circuit is coupled to the output of the first flip-flop, another input of the multiplexer circuit is arranged to receive a logic high signal, and an output of the multiplexer circuit is coupled to the D input of the first flip-flop. The multiplexer circuit is arranged to multiplex the logic high signal and the UP signal responsive to a reference gate signal. If the reference gate signal corresponds to an active level, logic level of the UP signal does not change.

Abstract: A phase-locked loop circuit has a fractional-frequency-interval phase frequency detector, a charge pump, an oscillator, and a divider. The fractional-frequency-interval phase frequency detector has a phase frequency detector unit that is utilized as or comprises a plurality of phase frequency detector units. The divider is responsive to the oscillator and provides divider values for dividing an oscillator frequency by the divider values to provide a feedback frequency of a feedback loop signal of the phase-locked loop circuit. A reference input frequency is input as a first input into the phase frequency detector unit. The feedback frequency is input and selectively delayed as second inputs into the phase frequency detector unit so that the second inputs are aligned for input according to the reference input frequency and an oscillator frequency is, in effect, responsive to the phase frequency detector units and allowed to be divided by a fractional-integer divider value.

Abstract: The invention relates to a phase shifted binary transmission encoder with data input and data output, where the phase shifted binary transmission encoder includes an exclusive or gate having two inputs and one output, the output of the exclusive or gate being the output of the Phase shifted binary transmission encoder, where one input of the exclusive or gate is connected with the output via a first delaying element and the other input of the exclusive or gate is connected with the data input via a second delay element, both delaying elements being connected with a clock input, wherein the delay elements are transparent D flip-flops. Furthermore the invention relates to a phase modulator and an optical network element for phase shaped binary transmission.

Abstract: A comparator compares a first binary input signal and a second binary input signal each binalized. A generator generates a reset signal at each rising edge or each falling edge of the first input signal. A counter counts the second input signal at each timing determined by the reset signal. The counted value represents a ratio of each frequency of the first input signal and the second input signal. A subtractor calculates a difference between the counted value and a set value representing a predetermined ratio of each frequency of the first input signal and the second input signal. An integrator integrates the difference. The integrated value represents a phase difference of the frequencies of the first input signal and the second input signal.

Abstract: An apparatus is disclosed that is an analog phase detector where a summation technique is used to determine the phase difference of the two input waveforms of the phase detector. Instead of multiplying the two signals—a technique used in the prior art—a difference amplifier subtracts one waveform from the other. The difference amplifier produces a waveform whose maximum peak-to-peak amplitude is directly proportional to the phase difference. Feeding this waveform into an envelope detector followed by a low pass filter, we are able to get a DC voltage level that is directly proportional to the phase difference of the two input waveforms.

Abstract: A phase comparator has a flip-flop circuit and a logic circuit. The flip-flop circuit compares an input clock signal with a leading edge and a trailing edge of an input data signal to produce a leading phase comparison result signal indicative of a leading phase comparison result related to the leading edge of the input data signal and a trailing phase comparison result signal indicative of a trailing phase comparison result related to the trailing edge of the input data signal. The logic circuit produces an output up signal when both of the leading and the trailing phase comparison result signals indicate a lag phase of the input clock signal. The logic circuit produces an output down signal when both of the leading and the trailing phase comparison result signals indicate a lead phase of the input clock signal.

Abstract: A phase-locked loop circuit includes a first PFD (phase detector) and a second PFD. The first PFD accepts an input clock signal CLK and a feedback clock signal FBCLK, and supplies its positive output to a charge pump. The second PFD accepts an inverted signal NCLK of the input clock signal CLK and the feedback clock signal FBCLK, and supplies its negative output to the charge pump. The phase-locked loop circuit outputs the clock signal whose phase differs from the phase of the input clock signal by 90 degrees.

Abstract: A circuit comprising a phase detector/correction circuit, at least one column of memory cells, a control circuit and a sense amplifier. The control circuit may be configured to read a sequence from the memory cells in a predetermined order and present a first output signal. The sense amplifier may be configured to present a periodic signal in response to the first output signal.

Abstract: An improved DDLL containing a majority filter counter circuit is disclosed. The majority filter counter circuit is located between the phase detector and the shift register of the DDLL. The majority filter counter circuit receives shifting commands from the phase detector and filters the shift commands from reaching the shift register until a predetermined number (e.g., 16) have been received from the phase detector before transmitting a shift command (either shift right or shift left) to the shift register. Once the shift register receives the shift command, the shift register directs the delay line to shift by one tap in either a shift right or a shift left direction depending upon the phase relationship between CLKIn and CLKOut. By waiting for e.g., 16 shift commands, the majority filter counter circuit ensures that a premature shift command is not delivered to the shift register in the case of a noise event.

Abstract: Systems and methods are provided for operating a delay locked loop during a reset. The systems and methods provide for activating a reset mode signal to prevent a phase lock signal from forcing the DLL out of a reset, and deactivating the reset mode signal only after at least one shifting operation is performed to allow the phase lock signal to correctly allow the DLL to be out of the reset.

Abstract: A phase frequency detector (PFD) circuit (516) compares two clock signals and generates a number of outputs to indicate a phase difference between these two clock signals (513, 519). The phase frequency detector has more than three states. The PFD circuit may be used in phase locked loop (PLL) or delay locked loop (DLL) circuit in order to maintain or lock a phase relationship between the two clock signals. The PFD circuitry will allow for a fast lock acquisition time, even when there is a relatively wide frequency range between the two clock signals.

Abstract: The present invention provides a phase comparator provided in a phase locked loop circuit, the phase comparator converting a phase difference between first and second input signals into a current signal, wherein the phase comparator has: a lock detector for detecting locked and unlocked states of the phase locked loop circuit to generate a detected signal which indicates one of the locked and unlocked states; and a current source connected to the lock detector for receiving the detected signal from the lock detector and varying a supply current based on the detected signal, so that if the detected signal indicates the unlocked states, then the current source increases the supplying current.

Abstract: A phase comparison of timing signals is made by combinational circuitry which receives the timing signals and a window signal, the window signal identifying edges of the timing signals to be compared. The comparison may result in a charge pumped output which can be fed back to control the phase of one of the timing signals. The phase comparator and charge pump circuit can be included in a multiplier circuitry in which the phase of an input signal is directly compared to the phase of an edge of the multiplied signal.

Abstract: Network elements of a synchronous digital communications system have a clock generator for generating a clock signal locked to an input signal. Such a clock generator comprises a tunable oscillator (OSC) and a phase comparator (PK) for comparing the phase of the input signal (IN) with the phase of the clock signal (CLK) and for generating a correction signal which serves to tune the oscillator (OSC). To avoid phase transients due to interruptions and disturbances in the input signal (IN), means (WD) are provided for determining an expectancy window, for deciding whether the correction signal lies within the expectancy window, and for tuning the oscillator with the correction signal if the correction signal lies within the expectancy window.

Abstract: The present invention relates to a phase detector with no dead zone comprising two detecting means and two control logic circuits. The phase-frequency detector employs the control logic circuits to proceed with reset operation of the detecting means such that the existence of a phase difference between the reference clock signal and the feedback clock signal prevents the misdetection of the up, down signals (output signal), and the up, down signals will not be simultaneously at "1".

Abstract: A digital phase locked loop includes a digital phase detector which provides a magnitude control signal to adjust the step size of up and down adjustments in the phase/frequency of a digitally controlled oscillator, resulting in shorter lock-in or acquisition time and smaller jitter as compared to conventional digital phase locked loop devices. In the disclosed embodiments, the digital phase detector includes multiple bit shift registers in both the up and down directions to count or measure a number of up or down minimum width pulses and provide a pulse magnitude control based on the value of the shift registers to the digitally controlled oscillator. The digitally controlled oscillator includes a charge pump and voltage controlled oscillator. In one embodiment, the charge pump provides programmable control over its output current pulses to a capacitor which controls the output frequency of the voltage controlled oscillator.

Abstract: A wireless communication system (10) uses a phase detector (28) having a first pair of flip-flops (50, 56) for detecting the phase difference between an input frequency and a reference frequency. The first pair of flip-flops control current sources (66, 70) in the charge pump of the phase detector to modulate the error signal. A second pair of flip-flops (52, 58) detect when the input frequency is more than 2.pi. ahead of or behind the reference frequency. The second pair of flip-flops increment and decrement a counter (54) which in turn controls additional current sources (78-88) in the charge pump. The additional current sources extend the linear operating range of the error signal when the phase error exceeds .+-.2.pi..

Abstract: A clock signal phase comparator includes a first delay unit for delaying a clock signal for a predetermined time, a first phase detector for comparing an output signal of the first delay unit and a reference clock signal and outputting a first high or low level output signal, a second delay unit for delaying for a predetermined time and outputting the reference clock signal, and a second phase detector for comparing an output signal of the second delay unit and the clock signal and outputting a second high or low level output signal. The phase comparator separately displays the phase comparison results in grades of fast, slow and locking, and when a locked phase is detected, the phase control system is partially or entirely disabled, for thereby reducing current consumption of the system.

Abstract: A phase/frequency detector, such as may be used in a phase-lock loop (PLL), having reduced jitter at high frequencies by reducing or eliminating the dead zone. The detector generates two output signals (UP and DOWN) wherein one of the output signals (depending upon which input signal arrives first) has a pulse width which is equal to a time delay between the input signals. There is a dead zone associated with very small phase differences between the input signals, and the dead zone is reduced by increasing the durations of two output pulses, using several delay elements which operate on signals that are derived from the reference and feedback inputs. The circuit may be tuned to reduce the dead zone to less than one picosecond, making it particularly useful for very high speed (greater than one gigahertz) clock circuits. The phase/frequency detector uses self-resetting, complementary metal-oxide semiconducting (SRCMOS) gates.

Abstract: A PLL (phase lock loop) circuit improves pull-in and noise performances by changing a loop gain based on the loop states. The PLL circuit includes a voltage controlled oscillator (VCO) for generating an oscillation signal whose oscillation frequency is controlled by a control voltage provided thereto, a phase comparator for detecting a phase difference between the oscillation signal from the VCO and a reference signal wherein a detection gain of the phase difference is regulated by a bias voltage provided thereto, a low pass filter for receiving an output signal of the phase comparator for removing high frequency components therefrom to produce the control voltage supplied to the VCO, a phase lock loop formed by the VCO, phase comparator and low pass filter, and a phase lock detection circuit for detecting whether the phase lock loop has reached a phase lock state and changing the bias voltage to decrease the detection gain of the phase comparator when the phase lock loop has reached the lock state.

Abstract: A parallel sampling phase detector with linear output response is disclosed. The parallel sampling phase detector is disclosed for use in data recovery. The device includes a voltage controlled oscillator (VCO) that generates ten separate phase signals using a five stage ring oscillator. Five linear phase detectors are employed in the device, each operating during one of five "window" intervals. The "window" intervals are non-overlapping, and are generated using preselected ones of the VCO output phases. The linear phase detectors each generate, respectively, a variable pulsewidth pump up signal wherein the pulsewidth of the pump up signal is proportional to a phase difference between the input data signal applied to the phase detector, and the output phase signals of the VCO. Each phase detector also generates a pump down signal that has a fixed pulsewidth.

Abstract: A phase detector is disclosed that eliminates frequency ripple in a phase-locked loop circuit. The detector includes first and second circuits for providing UP and DOWN signals respectively. It also includes a delay element for setting the duration of the DOWN signal so as to eliminate phase jitter and static phase offset.

Abstract: A circuit for detecting the phase angle of a three-phase alternating current includes a plurality of low-pass filters installed at each input port for removing noise and high-frequency signals mixed in an alternating current input signal, a plurality of multipliers each for multiplying the signal output from each of the low-pass filter by a feedback signal, a subtracter for receiving the signals output from the plurality of multipliers and calculating an error between two signals, a loop filter for receiving the signal output from the subtracter and filtering the same, an integrator for receiving the signal output from the loop filter, time-integrating the same, and outputting an estimated digital phase angle signal, and a phase delay compensator installed between the subtracter and the loop filter, for compensating for phase delay of the input signal caused by the low-pass filters.

Abstract: A process tolerant delay circuit includes a plurality of inverters that receive an input signal and provide an output signal related to the input signal but including a propagation delay of the plurality of inverters. At least one inverter comprises FETs of minimum channel lengths dependent upon a fabrication process by which the circuit was made. Accordingly, the plurality of inverters have a propagation delay dependent upon the fabrication process. A delay compensation device receives the output signal of the inverters and provides a compensated output signal related to the received signal but including a variable delay established in accordance with a control signal. A process sense stack provides the control signal only during a transition of the input signal, and with a value dependent upon a channel length of a FET device thereof.

Abstract: A controlled delay path inserts a selected delay into a clock distribution circuit to create a total clock delay that is equal to an integer number of clock cycles relative to a reference dock signal or which produces a selected phase relationship to the reference dock signal. The delay path correction of the invention is particularly useful in circuits having a wide range of possible system clock frequencies or having programmable routing of clock signals, and therefore a wide range of operating delays. A reference clock signal is directed to a range of selectable voltage controlled delay elements by a phase detector that receives the reference clock signal and a feedback signal, and that produces an error voltage which adjusts the voltage controlled delay elements to produce an output clock signal. Additional selectable delays may be included that create offset options and allow selection of a leading, lagging, or in-phase reference dock/output clock relationship.

Abstract: A phase lock loop includes a charge pump, a voltage controlled oscillator (VCO), and a phase frequency detector. The phase frequency detector has a dynamic logic structure. The phase frequency detector generates up and down signals for directing the charge pump to provide a voltage signal to the VCO to vary the frequency of the VCO clock. The difference between the up and down signals is indicative of the phase difference between the reference clock signal and the VCO clock. The phase frequency detector includes up and down signal generators for generating the up and down signals, respectively. The up signal generator includes a first p field effect transistor (FET) having a gate for receiving a set signal, a second p FET having a source coupled to the drain of the first p FET and having a gate for receiving a reference clock signal. A first n FET has a source coupled to the drain of the second p FET and has a gate for receiving the set signal.

Abstract: A data discriminating circuit is provided on the receiver side of a digital signal transmission system, and performs data discrimination with a proper phase relation settled between data and a clock signal. In the discrimination circuit, a data discriminating section discriminates input data in synchronism with a clock signal and outputs resultant data as discriminated data, a phase-relation judging section judges a phase relation between the input data and the discriminated data, a clock phase controller produces a phase control signal to control and initially-determined phase of the clock signal, based on an output of the phase-relation judging section, and a clock phase judging section determines a phase of the clock signal and alters the initially-determined phase of the clock signal in accordance with the phase control signal from the clock phase controller.

Abstract: A control system comprises a controller for controlling an actuator, for instance of an electrically power assisted vehicle steering system. An unstable circuit, such as first and second cascade connected integrators has an input connected to the controller and an output connected to a detector, which signals an error when the output signal of the unstable circuit is outside an acceptable range. During normal operation, the controller supplies a signal to the unstable circuit such that its output signal remains within the acceptable range. The error signal may be used to disable the actuator, for instance so as to remove power assistance from steering system.

Abstract: A controlled delay path inserts a selected delay into a clock distribution circuit to create a total clock delay that is equal to an integer number of clock cycles relative to a reference input clock signal or which produces a selected phase relationship to the reference clock signal. The delay path correction of the invention is particularly useful in circuits having a wide range of possible system clock frequencies or having programmable routing of clock signals, and therefore a wide range of operating delays. A reference input clock signal is directed to a range of selectable voltage controlled delay elements by a phase detector that receives the reference input clock signal and a feedback signal, and that produces an error voltage which adjusts the voltage controlled delay elements to produce an output clock signal. Additional selectable delays may be included that create offset options and allow selection of a leading, lagging, or in-phase reference input clock/output clock relationship.

Abstract: A method and system are provided for detecting and measuring a phase difference, linearly over a range of 360.degree., between the output signals from a primary stratum clock module (100) and a standby stratum clock module (120) in a telecommunications system, calculating the amount of time needed to delay the standby clock signal (.o slashed.2) enough to cancel the phase difference, and controlling a digital delay line (132) to shift the phase of the standby clock signal (.o slashed.2) accordingly and thereby cancel the phase difference. Both the frequency and phase alignments of the two clocks are thus maintained. Therefore, when the system or user switches operations from the primary stratum clock module (100) to the standby stratum clock module (120), phase-related transients are not generated, which results in a significant increase in the overall performance and reliability of the system.

Abstract: A phase comparator circuit in which an output synchronized with the input signal may be accurately produced without producing a malfunction even in the absence of the synchronization signal, in which a detection unit 11 detects the phase information of an input signal, an error detection unit 12 detects the phase error with respect to the phase of the input signal, a switch 13 switches between the phase error from the error detecting unit and plural fixed values of the phase error +.DELTA..alpha. and -.DELTA..alpha.

Abstract: A bit synchronizing circuit is provided with both analog and digital devices in an enhanced bit synchronizing circuit system. There is provided a digital phase detector and a digital lock detector which are compatible with analog circuity. The output of the digital phase detector is coupled to an analog summing circuit having an output which is coupled to a low pass filter (LPF). The analog output of the LPF is coupled to the input of a voltage controlled oscillator (VCO) which produces a data rate clock. The output of the digital lock detector is coupled to an analog summing circuit having an output coupled to a low pass filter (LPF). The output of the LPF is coupled to a comparator for generating a lock indication signal output. The output of the comparator is also coupled to a sweep circuit which is coupled to an input of the voltage controlled oscillator for resolving frequency uncertainties in the bit synchronizing circuit.

Abstract: A reference current source (38) and a matched reference transistor (40) are provided as part of a current limiting circuit, wherein the matched reference transistor (40) is scaled, electrically matched, and physically located in close proximity to an on-chip switching transistor (16) of a DC--DC converter. By serially coupling the reference current source (38) to the reference transistor (40), a reference signal (48), which is equal to the voltage across the reference transistor (40), is generated. The reference signal (48) is compared to the voltage across the switching transistor (16) while the switching transistor (16) is conducting. When the voltage across the switching transistor (16) exceeds that across reference transistor (40), the gate drive to the switching transistor (16) is disabled for the remainder of the current conductive phase.

Abstract: A phase/frequency comparator includes: two inputs which respectively receive first and second logic signals; a first logic gate which is at an active state during a duration equal to the phase advance of the first signal with respect to the second signal; and a second logic gate which is at an active state during a duration equal to the phase advance of said second signal with respect to the first signal. The phase/frequency comparator also includes: a first switching element operated by the active state of the second gate to prevent transmission to the first gate a state liable to switch the first gate to its active state; and a second switching element operated by the active state of the first gate to prevent transmission to the second gate a state liable to switch the second gate to its active state.