Abstract: A device checks the skew between two clock signals among a plurality of clock signals having the same frequency. The two clock signals of each possible pair of clock signals respectively enable two successive flip-flops that are initially set at distinct states. The whole set of the flip-flops is connected in a looped shift register configuration. An alarm signal is provided by an Exclusive-OR gate receiving the outputs of two successive flip-flops of the shift register.

Abstract: A phase-locked loop having a phase error processor (PEP) circuit in which a phase error is provided to the PEP circuit in the form of a first pulse stream comprising pulses of a width dictated by the phase error between the incoming data and a local clock and a second pulse stream comprising pulses of a reference width. The circuit includes two integrators having outputs coupled to first and second inputs of a comparator, respectively. Switches couple the first pulse stream to the input of one integrator and the second pulse stream to the input of the other integrator during a first time window and reverse the connections during a second time window. The switches are controlled by a SWAP signal which alternates state at regular intervals. The output of the comparator is exclusive-ORed with the SWAP signal in order to invert the comparator output signal every other window so as to average any input offset error of the comparator or offset due to mismatch of the integrators evenly between the two pulse streams.

Abstract: A signal transmitter-receiver system comprising first and second transmitter-receiver units interconnected by a signal transmission line, a first transmitter-receiver unit including a first transmission circuit for delivering a selected one of a plurality of a.c. signals each having a distinct phase difference with respect to a reference a.c. signal to the signal transmission line at each of successive predetermined communication time interval, the second transmitter-receiver unit including a second receiving circuit for identifying the phase difference of the a.c. signal or the signal transmission line with respect to the reference a.c. signal at each communication time interval, the second transmitter-receiver unit including a second transmission circuit for changing the combination of positive and negative amplitudes of the a.c.

Abstract: A phase detector circuit (10) for generating an analog signal (VR) dependent upon the phase difference between two digital signals (VE, VA) includes two NOR circuits (20, 27) to the inputs (18, 26; 28, 24) of which the two digital signals are supplied on the one hand delayed and negated and on the other directly. The output signals of the NOR circuits (20, 27) control two current sources (S1, S2), one of which in the activated state furnishes a constant charge current (I1) for a storage capacitor (C) whilst the other of which leads a constant discharge current (I2) of equal magnitude away from said storage capacitor (C). The charge voltage at said storage capacitor (C) is an analog signal (VR) which represents a measure of the phase deviation between the digital signals (VE, VA).

Abstract: A signal processing circuit measures the phase difference between digitally formated reference tone and telephone line signals over a prescribed number of signal periods so as to provide to an attendant processor an average value of phase differential. The reference tone and line signals are conditioned as square wave signals, and applied to a first exclusive-OR circuit and to respective divide-by-two flip-flop circuits, which produce square wave signals having a frequency which is half the frequency of the conditioned square wave signals. The output of the first exclusive-OR circuit represents the half-cycle phase difference between the two sine waves. The full-cycle square wave signals are applied to a second exclusive-OR circuit, which produces a series of pulses, each representing a respective full-cycle phase difference between the reference and line sine waves.

Abstract: A phase difference measuring device includes a phase detector, a low-pass filter/voltage controlled oscillator, a reference signal selector for selecting either an internal reference signal or an external reference signal as a reference signal, a phase comparator for comparing an undertest signal with the selected reference signal and obtaining a phase difference between the two compared signal. The internal reference signal is selected when the undertest signal is a jittering signal, and the external reference signal is selected when the undertest signal is a wandering signal. The undertest signal, the selected reference signal, and a relatively high frequency clock signal from external are sent to the phase comparator and a phase difference between the undertest signal and the selected reference signal is counted by the relatively high frequency clock signal.

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.

Abstract: A phase-locked-loop (PLL) with stable phase discrimination includes a charge pump with a current source and current sink to control a VCO, and a phase discriminator to compare the VCO's signal to a stable reference signal for controlling the charge pump. The phase discriminator includes a resettable D-flipflop to provide the current source control signal and a resettable D-flipflop to provide the current sink control signal. The reset signal keeps both sink and source temporarily alive to avoid a dead zone region. The reset signal is produced under the combined control of the sink and source control signals and, in addition, of the reference signal to enhance stability.

Abstract: The device comprises a switched-mode power supply (1) equipped with an electronic switching member (T.sub.1), the closing of which controls the power supply to an inductor (L.sub.1) which discharges, when the member reopens, into a capacitor (C.sub.1) at the terminals of which the output voltage of the device appears, characterized in that it comprises (a) storage means for recording a sequence of image numbers of successive segments of the predetermined waveform, (b) a clocked digital counter (2) and (c) means (3) for successively loading this counter (2) with each of the numbers of this sequence considered as a bound of the count performed by the counter (2), the latter cyclically controlling the closing of the switching member (T.sub.1) for a predetermined time interval, each time the count performed reaches the limit thus fixed.

Abstract: A fully-symmetric high-speed CMOS frequency synthesizer which exhibits minimum dead-zone effects is disclosed. A fully-symmetric phase-frequency detector and a fully differential charge-pump filter combined with a voltage-controlled oscillator are key elements of the invention described.

Abstract: A receiver (10) for extracting complex values by reference to a local frequency reference determines the frequency offset between a local oscillator (16) and the carrier by employing a circuit (40) for determining a "phase rotation." When a record of the input signal is determined to have resulted from a predetermined reference sequence of complex values, the phase-rotation circuit (40) compares the phases of complex values extracted from this record with corresponding symbols of the reference sequence. By comparing this difference for one part of the sequence with that for another, circuitry (38, 50, 52, 53, 54) in the receiver infers the frequency offset between the transmitter reference and the receiver reference, and a complex multiplier (34) compensates for this offset by multiplying the successive complex-valued samples by a complex exponential whose frequency is the negative of the frequency offset.

Abstract: A ring oscillator for circulating pulse edges of two types therein includes an even number of inverting circuits connected in a ring. Each of the inverting circuits is operative to invert an input signal and output an inversion of the input signal. One of the inverting circuits is a first start inverting circuit which starts an operation of inverting an input signal in response to a first control signal applied from an external input. One of the inverting circuits except the first start inverting circuit and an inverting circuit immediately following the first start inverting circuit is a second start inverting circuit which starts an operation of inverting an input signal in response to a second control signal.

Abstract: A semiconductor integrated circuit is operative in a plurality of different modes. A plurality of select signals whose number corresponds to modes selected from a plurality of different modes are outputted. In response to the select signals, it is detected whether at least two operation modes are selected simultaneously. If so, a detection signal is outputted. In response to this detection signal, the operation of the semiconductor integrated circuit is stopped. Further, in response to the select signal, the semiconductor integrated circuit is activated in a mode by means of a predetermined select signal of these select signals. Further, in response to these select signals, the selected mode can be detected.

Abstract: A skew fault detection system for detecting clock skew between two clock phases utilizes a plurality of skew fault detection circuits each of which employs two D-type flip-flops. The clock terminals of both of these flip-flops are connected to one of the clock phases, and one of the clock phases is coupled to a delay circuit on the D input terminal of one of the flip-flops. The delay circuit is adjustable to correspond to the clock pulse delay that is inherent in the circuit that is being monitored to control the maximum amount of clock skew that is allowable before this flip-flop will set. If the clock skew exceeds this allowable time, a skew fault occurs and the flip-flop will set. The circuit compares the initiation of one clock phase against the initiation of the other clock phase and to determine when the initiation of one clock phase occurs earlier than the initiation of the other clock pulse by a time duration that exceeds a predetermined allowable skew amount of time.

Abstract: In one embodiment, a method of providing phase detection from a circuit having first and second inputs and at least one output is disclosed. The method includes a cyclical operation of four steps. The first step awaits the receipt at the first input of an input signal which at least meets the requirements of one of two given binary values. The second step awaits the receipt at the first input of an input signal which at least meets the requirements of the other of the two given binary values before providing an output signal of a first value at the output. The third step awaits the receipt at the second input of an input signal which at least meets the requirements of one of two given binary values. The fourth step awaits the receipt at the second input of an input signal which at least meets the requirements of the other of the two given binary values before changing the output signal at the output to a second value. The process then returns to the first step.

Abstract: A circuit combining the functions of phase-sensitive rectifier and integrator uses an operational amplifier and capacitors. A control signal switches a capacitor in and out of a feedback loop containing a second feedback capacitor, resulting in a residual charge in the second feedback capacitor if there is a phase-difference between an input signal and the control signal. The invention may also incorporate an automatic offset compensation circuit by using additional switches and a second control signal. The capacitor that is switched in and out of the feedback loop is coupled to a compensation capacitor during periods when the capacitor is not being used for the phase-sensitive rectifier and integrator portions of the circuit. The circuit arrangement allows the use of long time constants in the integrator portion of the circuit.

Abstract: The present invention provides a method and an apparatus for controlling and measuring the phase window of a data separator that is suitable for implementation in an automatic test equipment (ATE) system. The test circuit comprising cross-coupled flip-flops uses the pump up (PU) and pump down (PD) signals produced by a phase detector of a phase-locked loop (PLL) to digitally monitor the phase window. The PLL captures a fixed frequency data pattern provided to the data separator and tracks its frequency. The clock inputs of the cross-coupled flip-flops are driven by the pump up and pump down signals output by the phase detector. Once the PLL has captured the fixed frequency data pattern and settled, a single data bit is shifted from its initial position in the center of the phase window. The single data bit is shifted so that its phase leads or lags its initial position. When the single data bit is shifted in the data pattern, the phase detector correspondingly sets PU high, PD high, or both PU and PD high.

Abstract: A damping circuit is described which includes a phase-and-frequency detector, a charge pump, a voltage-current oscillator and a capacitor. The phase-and-frequency detector generates UP and DOWN signals representative of a difference in phase between a pair of digital input signals. The charge pump varies an amount of charge carried within the capacitor in accordance with the UP and DOWN signals. The voltage controlled oscillator generates an output signal having a frequency controlled by both a voltage provided by the capacitor and by the UP and DOWN signals directly received from the phase-and-frequency detector. No analog damping resistor is required. Rather, the digital damping circuit is a digital circuit which generates adequate phase and frequency damping without a damping resistor. In this manner damping is achieved which is substantially unaffected by process parameters and operating and ambient parameters. Method embodiments of the invention are also described.

Abstract: A frequency discriminator of the horizontal synchronizing signal for a multi-mode monitor has a plurality of filter capacitors connected to horizontal synchronizing signal lines for rejecting noises of a direct current component of the horizontal synchronizing signal. The frequency discriminator also includes a plurality of phase comparator means respectively connected to the filter capacitors for comparing local oscillating frequencies set differently according to each mode with the inputted horizontal synchronizing signal to output one signal representative of the mode of the monitor.

Abstract: A phase modulated signal is split into quadrature components Savg+SaSin(.phi.(t)+kx(t)) and Cavg+CaCos((.phi.(t)+kx(t)). The average value for each signal is compared with the signal to produce a data bit whose meaning is that the average value was exceeded at a sampling instant. The bits at successive times (t.sub.0 and t.sub.1) are separated by an interval set by the Nyquist rate on the peak rate of change of the phase for the signal. Four bits at two sample times t.sub.0 and t.sub.1 are processed to determine the phase quadrants modulo 360 degrees to determine the direction of the phase change. The determination is used to produce a counter enable signal, counter direction control signal (up/down) and optionally an error signal if the phase change during one clock period is more than plus or minus one quadrant. A tracking counter counts the number of quadrants of change from those signals.