Abstract: The present invention, generally speaking, provides improved methods of generating clean, precisely-modulated waveforms, at least partly using digital techniques. In accordance with one aspect of the invention, a "difference engine" is provided that produces a digital signal representing the frequency error between a numeric frequency and an analog frequency. The frequency error may be digitally integrated to produce a digital signal representing the phase error. The difference engine may be incorporated into a PLL, where the analog frequency is that of an output signal of a VCO of the PLL. Direct modulation of the PLL output signal may be performed numerically. By further providing an auxiliary modulation path and performing calibration between the direct modulation path and the auxiliary modulation path, modulation characteristics may be separated from loop bandwidth constraints.

Abstract: A frequency detecting circuit is provided that includes a level shift detecting unit for generating pulse signals of a certain pulse width at each level shifting of input clock signals and a level detecting unit. The level detecting unit includes a charging unit and a discharging unit. The discharging unit is activated by the pulse signals of the level shift detecting unit to discharge the charges of the charging unit. An inverter having a logic threshold voltage receives electrical signals in accordance with the charged level of the charging unit to output a signal indicative of the frequency of the input clock signals.

Abstract: A sampling circuit system enhances sampling resolution without increasing frequencies of clock signals for sampling. An input waveform is input to a first group of sampling circuits and a sampling circuit serving as a standard circuit. Clock signals out of phase from each other by 2 .pi./n (n=an integer not less than 3) radian, respectively, against a clock signal input to the standard circuit are input to the first group of sampling circuits for sampling. Then sampling signals output from the first group of the sampling circuits are input to a second group of sampling circuits so as to be sampled again by inputting a sampling signal output from the standard circuit as a common clock signal for the second group of sampling circuits.

Abstract: An integrated XNOR flip-flop is provided which is faster than conventional XNOR flip-flop combinations. The integrated XNOR flip-flop is faster and uses less area than conventional XNOR flip-flop combinations. The integrated circuit has few gates along the critical path and takes advantage of the set up times inherent in the flip-flop. Accordingly, the integrated XNOR flip-flop is able to perform the same function in an expedient manner. In one illustrative embodiment, a plurality of the integrated XNOR flip-flops are used to compare a tag of a cache memory with an address to determine whether the desired address is available in the cache.

Abstract: A phase detector enables sampling of an input waveform such that a resolution, equivalent to the resolution conventionally obtained by doubling a clock frequency, is obtained without doubling the frequency. In order to accomplish this, the phase detector has the following construction and function. A first sampling circuit samples an input waveform using an in-phase clock signal from a clock to generate a sampled waveform. A second sampling circuit samples the input waveform by using a falling edge of the clock to generate an output a signal. A third sampling circuit samples the output signal from the second sampling circuit by a rising edge of the sampled waveform supplied from the first sampling circuit to generate a phase detection flag. This phase detection flag thus detects the presence of the input waveform at a rate double the frequency of the clock.

Abstract: A frequency departure detecting circuit permits flexibly modify a detecting condition of frequency departure. A working reference clock is counted for a given period. On the basis of uniformity between bits of given number of upper bits of the counted value, large magnitude of frequency departure of repeated frequency of the reference clock from a frequency that should be is judged. Also, through comparison of given number of lower bits of the counted value and externally set detecting value, departure of the repeated frequency of the reference clock from the frequency that should be, is judged. When the counted value reaches a predetermined value, free running condition of the counter is judged to stop counting operation. When judgement is made that the repeated frequency of the reference clock is departed from the frequency that should be, the working reference clock is replaced with a back-up reference clock in response to an alarm.

Abstract: Internal node timing on an integrated circuit which is supplied with a clock signal from a system clock, the cycle time of which can be varied is measured by connecting a sequential element such as a latch to the node to measured and clocking it with a delayed measurement clock while increasing the clock cycle time. The output of the sequential element is an output pin of said integrated circuit. The measurement clock has the same cycle time as the system clock but has a latching edge delayed, the delay being at least 1.5 times the nominal system clock cycle time when it is desired to make measurement over both the high phase and low phase. The output pin is observed and the clock cycle time at which the sequential element fails to latch the current value determined. In a further embodiment, two sequential elements are used to make two measurements of this type and the difference between the two measurements is used to compute the time delay between the two nodes being measured. One node may be a clock node.

Abstract: A power control circuit of a monitor capable of being applied to all kinds of monitors is constructed to supply a control signal in accordance with the state of the monitor among On, Stand-by, Suspend and Off states by considering the input of vertical and horizontal sync signals after checking the current input state of the horizontal and vertical sync signals of the monitor, thereby facilitating the embodiment of the circuit that provides the control signal according to the current power supply state of the monitor by an ASIC.

Abstract: A phase locked loop including an in-phase detector (IPD), a quadrature phase detector (QPD), a frequency detector (FD), a squelch, a filter, and a voltage controlled oscillator (VCO). The in-phase detector has an IPD sample input, an IPD input, and an IPD output, where the IPD sample input is coupled to a data input. The quadrature phase detector has a QPD sample input, a QPD input, and a QPD output, where the QPD sample input is coupled to the data input. The frequency detector has a first FD input coupled to the IPD output, a second FD input coupled to the QPD output, and a FD output. The squelch has a squelch input, an enable input, and a squelch output where the squelch input is coupled to the IPD output and the squelch enable is coupled to the FD output. The filter has a filter input coupled to the squelch output and a filter output. The voltage controlled oscillator has a VCO input coupled to the filter output, a VCO in-phase output, and a VCO quadrature output.

Abstract: A direct conversion Binary FSK radio receiver has an AFC loop comprising an Exclusive-Or phase detector 104 responsive to the I.sub.3 and Q.sub.3 signals. I and Q filters 100, 101 are not identical but have different frequency-phase characteristics such that their phase shifts are identical when the local oscillator 102 is correctly tuned and differ when the local oscillator is off-tune. Detector 104 detects the change of phase and applies a control signal to local oscillator 102 such as to return the local oscillator frequency to the correct value. Alternatively, identical filters may be used in the I and Q channels, circuits having different phase shifts being coupled between the I.sub.3 and Q.sub.3 signals and the inputs of the phase detector 104.

Abstract: A transition detection device, generating a variable-duration pulse, such as an enable signal for the input circuits of a CMOS static memory circuit, receiving an input signal that includes a delay circuit of determined delay value, making it possible to generate a delayed enable signal, with a safety margin of duration equal to the delay value. A calibration circuit is provided, which includes an exclusive-OR circuit receiving the input signal on a first input. A controlled delay circuit is provided to deliver an input signal delayed by a second delay value to a second input of the exclusive-OR circuit, which, upon access by the CEB signal, delivers a calibrated output pulse of duration equal to the second delay value, and truncated pulses for any transition occurring on the other inputs of the circuit, in the presence of address transitions or of other, not strictly simultaneous, inputs.

Abstract: A frequency multiplier circuit generates an supplemental high-frequency timing signal from a single, low-frequency current-controlled oscillator (CCO). The current-controlled oscillator (CCO) generates a controlled discharge current and a controlled bias current which are controlled in parallel to substantially eliminate inaccuracies in a characteristic frequency-current curve of the current-controlled oscillator. The frequency multiplier circuit generates a high-frequency timing signal using the digitally-controlled CCO and avoids the usage of a phase-locked loop (PLL) technique. Specifically, a frequency multiplier includes a current-controlled oscillator having a plurality of input lines connected to receive a digital current select signal and having an output terminal connected to carry a timing signal at a current-controlled oscillator frequency f.sub.CCO set in accordance with the current select signal.

Abstract: The present invention relates to a low frequency discriminator circuit comprised if apparatus for providing a rectangular wave input signal, apparatus for integrating the input signal, apparatus for detecting whether the integrated input signal falls between upper and lower thresholds respectively, and apparatus for providing an output signal indicating when the integrated input signal falls between the thresholds, whereby the frequency of the input signal may be determined to be between higher and lower limits.

Abstract: A frequency lock indicator (10) comprises a first delay (14), second delay (20), first sampler (24), second sampler (28), third sampler (32), fourth sampler (34), and lock indicator (36). The first delay (14) delays a rising edge of a frequency reference (12) which clocks the first sampler (24) on a rising edge and the third sampler (32) on a falling edge. The second delay (20) delays a rising edge of a feedback signal (18) to produce a delayed feedback signal (22) which clocks the second sampler (28) on a rising edge and the fourth sampler (34) on a falling edge. The first and third samplers sample an up-pump signal (26) and the second and fourth samplers sample a down-pump signal (30). The lock indicator (36) produces a lock indication signal (38) when the sampled up-pump signal substantially equal to the sampled down-pump signal.

Abstract: An object of the present invention is to provide an A/D conversion device capable of compensating for quantizing errors occurring as a result of variations in operating conditions and a physical quantity detection device using this A/D conversion device.

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: An integrated circuit (20) configures the active level of an input, output, or input/output pin by sensing a logic state on the pin's bonding pad (21) at the inactivation of a reset signal, such as a power-on reset signal. The integrated circuit (20) selects a true or complement signal to provide to or from an internal circuit (25). The voltage level on the pin is latched on the active-to-inactive transition of the power-on reset signal. Thus, the use of proper board-level termination resistors (70, 71) programs the pins to the desired active logic level without the need for additional logic circuitry or a dedicated device pin.

Abstract: .[.A bit clock reproducing circuit produces an output bit clock signal in response to an input clock signal but without reproducing jitter present in the input signal. A counter is supplied with a reference clock signal as a counting input, and the counter is periodically loaded, at a fixed time during each cycle of the input clock signal, with data which is a predetermined function of the state of the counter at such times..]. .Iadd.A bit clock reproducing circuit incorporates a counter for counting pulses of a clock pulse source after the arrival of an edge of a data pulse, at which time the counter is loaded with one of a number of preset values stored in a read-only memory, the contents of which are addressed by the counter output. Input data pulses are gated to an output terminal when the counter arrives at a predetermined state.