Abstract: A circuit for generating temperature-stable clocks including first and second crystal oscillators, an input for a reference clock source, a clock output, a first phase acquisition circuit coupled to the first and second crystal oscillators, a second phase acquisition circuit coupled to the input for the reference clock source and to the second crystal oscillator, a first DPLL coupled to the first phase acquisition circuit, a crystal oscillator variation estimator coupled to the first DPLL, a second DPLL coupled to the second phase acquisition circuit and including a phase-frequency detector having a input coupled to the second phase acquisition circuit, a loop filter, a frequency subtractor having an input coupled to the loop filter and an input coupled to the crystal oscillator variation estimator, and a DCO coupled to the frequency subtractor and driving an input of the phase-frequency detector.

Abstract: A master phase locked loop device is operable in association with one or more slave devices including slave digitally controlled oscillators (sDCOs), one or more digital PLL (DPLL) channels include a master digitally controlled oscillator (mDCO). A master synchronization timer generating master timing pulses to read phase and frequency information from the mDCO(s). A peripheral interface sends the read frequency and phase information to the one or more slave devices. A synchronization interface sends the master timing pulses to synchronize a replica synchronization timer in the sDCO(s) that generates slave timing pulses for use in updating the phase and frequency information received at the slave device(s).

Abstract: A time-to-digital converter (TDC) measures a time interval ?TTot between a leading signal and a triggering signal. A phase regulator incorporates a looped delay line to create pre-defined sub-intervals TNOR determined by the length of the delay line. The phase regulator has an input receiving the leading signal such that the leading signal loops around the delay line. A counter for counting the number of times m the leading signal loops around the delay line before said triggering signal arrives to obtain a coarse measurement of the time interval defined in terms of the sub-intervals TNOR. A Vernier core for measures a residual time interval TR where TR=?TTot?mTNOR to obtain a value for the time interval ?TTot. The TDC uses simpler encoding logic with reduced power consumption and phase noise performance better than 5 dB.

Abstract: A time-to-digital converter (TDC) measures a time interval ?TTot between a leading signal and a triggering signal. A phase regulator incorporates a looped delay line to create pre-defined sub-intervals TNOR determined by the length of the delay line. The phase regulator has an input receiving the leading signal such that the leading signal loops around the delay line. A counter for counting the number of times m the leading signal loops around the delay line before said triggering signal arrives to obtain a coarse measurement of the time interval defined in terms of the sub-intervals TNOR. A Vernier core for measures a residual time interval TR where TR=?TTot?mTNOR to obtain a value for the time interval ?TTot. The TDC uses simpler encoding logic with reduced power consumption and phase noise performance better than 5 dB.

Abstract: In a digital phase locked loop comprising a PLL loop including a first software-implemented controlled oscillator (SDCO) responsive to a control value to generate output phase and frequency values locked to a reference input signal, and a hardware-implemented controlled oscillator responsive to output phase and frequency values from said first SDCO to synthesize said clock signals, hardware delays are compensated for by sampling said synthesized clock signals, or derivatives thereof, to generate synthesized clock phase values. The synthesized clock signal phase values are compared with feedback phase values derived from the PLL loop to generate a compensation value to modify the synthesized clock signals or derivatives thereof.

Abstract: A clock signal generator responsive to synchronization pulses to perform actions has a phase locked loop (PLL) part including a digitally controlled oscillator (DCO) and an output driver coupled to the DCO, and a synthesizer part including a frequency synthesizer responsive to frequency and phase information from the DCO to generate a synthesized clock and programmable output dividers for generating output clocks from the synthesized clock. An interface establishes communication between the PLL part and the synthesizer part. The output driver is programmed to compute a phase offset required to align a selected output divider with the phase of the DCO and transmit the computed offset to the selected output divider over said interface for application to said selected output divider upon the occurrence of a synchronization pulse.

Abstract: A phase locked loop with holdover mode has a loop filter for creating an offset frequency value for a controlled oscillator. The loop filter includes a register for storing the current offset frequency value the said controlled oscillator. A first multiplexer responsive to a holdover signal selects, depending on the quality of a reference signal, the output of the loop filter or a holdover queue to control the controlled oscillator. A second multiplexer responsive to the holdover signal selects for input to the register, depending on the quality of the reference signal, the sum of an output of the register and a value derived from the current phase difference between the output of the controlled oscillator and the reference signal or a current output value of the holdover queue.

Abstract: A multi-channel phase locked loop (PLL) device has a plurality of PLL channels. Each channel includes a digitally controlled oscillator (DCO) supplying an output clock, via an output divider, to a respective output pin. A first multiplexer selects any of the PLL channels for alignment. A feedback calibration PLL is responsive to a feedback signal derived from an output clock of a selected channel at the respective output pin. A delay control module is responsive to an output of the feedback calibration PLL to adjust the phase of the output clock.

Abstract: A clock signal generator responsive to synchronization pulses to perform actions has a phase locked loop (PLL) part including a digitally controlled oscillator (DCO) and an output driver coupled to the DCO, and a synthesizer part including a frequency synthesizer responsive to frequency and phase information from the DCO to generate a synthesized clock and programmable output dividers for generating output clocks from the synthesized clock. An interface establishes communication between the PLL part and the synthesizer part. The output driver is programmed to compute a phase offset required to align a selected output divider with the phase of the DCO and transmit the computed offset to the selected output divider over said interface for application to said selected output divider upon the occurrence of a synchronization pulse.

Abstract: A master phase locked loop device is operable in association with one or more slave devices including slave digitally controlled oscillators (sDCOs), one or more digital PLL (DPLL) channels include a master digitally controlled oscillator (mDCO). A master synchronization timer generating master timing pulses to read phase and frequency information from the mDCO(s). A peripheral interface sends the read frequency and phase information to the one or more slave devices. A synchronization interface sends the master timing pulses to synchronize a replica synchronization timer in the sDCO(s) that generates slave timing pulses for use in updating the phase and frequency information received at the slave device(s).

Abstract: A multi-channel phase locked loop (PLL) device has a plurality of PLL channels. Each channel includes a digitally controlled oscillator (DCO) supplying an output clock, via an output divider, to a respective output pin. A first multiplexer selects any of the PLL channels for alignment. A feedback calibration PLL is responsive to a feedback signal derived from an output clock of a selected channel at the respective output pin. A delay control module is responsive to an output of the feedback calibration PLL to adjust the phase of the output clock.

Abstract: A phase locked loop with holdover mode has a loop filter for creating an offset frequency value for a controlled oscillator. The loop filter includes a register for storing the current offset frequency value the said controlled oscillator. A first multiplexer responsive to a holdover signal selects, depending on the quality of a reference signal, the output of the loop filter or a holdover queue to control the controlled oscillator. A second multiplexer responsive to the holdover signal selects for input to the register, depending on the quality of the reference signal, the sum of an output of the register and a value derived from the current phase difference between the output of the controlled oscillator and the reference signal or a current output value of the holdover queue.

Abstract: In a digital phase locked loop comprising a PLL loop including a first software-implemented controlled oscillator (SDCO) responsive to a control value to generate output phase and frequency values locked to a reference input signal, and a hardware-implemented controlled oscillator responsive to output phase and frequency values from said first SDCO to synthesize said clock signals, hardware delays are compensated for by sampling said synthesized clock signals, or derivatives thereof, to generate synthesized clock phase values. The synthesized clock signal phase values are compared with feedback phase values derived from the PLL loop to generate a compensation value to modify the synthesized clock signals or derivatives thereof.

Abstract: A digital phase locked loop has a phase acquisition module that outputs a first phase value representative of the phase of a reference signal expressed with respect to an internal phase reference. A phase offset write module convert a phases offset commanded from an external source into a phase offset correction value expressed with respect to the internal phase reference. A phase offset controller sums the phase offset correction values to produce a second phase value, which is added to the first phase value to produce a third phase value expressed with respect to the internal phase reference. A digital controlled oscillator (DCO) outputs a fourth phase value expressed with respect to the internal phase reference. A phase detector outputs a fifth phase value representing the difference between the third and fourth phase values. A loop filter derives a frequency offset for the DCO based on the fifth phase value. An output module generates one or more output clocks from the fourth phase value.

Abstract: A digital phase locked loop has a phase acquisition module that outputs a first phase value representative of the phase of a reference signal expressed with respect to an internal phase reference. A phase offset write module convert a phases offset commanded from an external source into a phase offset correction value expressed with respect to the internal phase reference. A phase offset controller sums the phase offset correction values to produce a second phase value, which is added to the first phase value to produce a third phase value expressed with respect to the internal phase reference. A digital controlled oscillator (DCO) outputs a fourth phase value expressed with respect to the internal phase reference. A phase detector outputs a fifth phase value representing the difference between the third and fourth phase values. A loop filter derives a frequency offset for the DCO based on the fifth phase value. An output module generates one or more output clocks from the fourth phase value.

Abstract: Phase slope is controlled in a phase locked loop wherein a phase error signal controlling a controlled oscillator has a proportional component and an integral component, by determining whether the proportional component falls within a range bounded by upper and lower limit values. The proportional component is combined with the integral component if the proportional component falls within the range to provide the phase error signal. Otherwise, the proportional component is modified to meet a phase slope requirement while leaving the integral component unmodified. The modified proportional component is combined with the unmodified integral component to provide the phase error signal.

Abstract: A phase-locked loop to is simultaneously synchronized to high and low frequency clocks by (i) locking an output of the phase-locked loop to a high-frequency reference clock, (ii) measuring at a high rate a first phase difference between the high-frequency reference clock and the output of the phase-locked loop, (iii) measuring at a high rate a second phase difference between a low-frequency reference clock and the output of the phase-locked loop; (iv) computing at a low rate from said first and second phase differences a third phase difference between the high-frequency and low frequency clocks; (v) combining at a low rate said third phase difference with said second phase-difference to obtain a total phase difference; and (vi) adjusting the output of the phase-locked loop at a low rate to reduce the obtained total phase difference.

Abstract: A phase-locked loop to is simultaneously synchronized to high and low frequency clocks by (i) locking an output of the phase-locked loop to a high-frequency reference clock, (ii) measuring at a high rate a first phase difference between the high-frequency reference clock and the output of the phase-locked loop, (iii) measuring at a high rate a second phase difference between a low-frequency reference clock and the output of the phase-locked loop; (iv) computing at a low rate from said first and second phase differences a third phase difference between the high-frequency and low frequency clocks; (v) combining at a low rate said third phase difference with said second phase-difference to obtain a total phase difference; and (vi) adjusting the output of the phase-locked loop at a low rate to reduce the obtained total phase difference.

Abstract: Phase slope is controlled in a phase locked loop wherein a phase error signal controlling a controlled oscillator has a proportional component and an integral component, by determining whether the proportional component falls within a range bounded by upper and lower limit values. The proportional component is combined with the integral component if the proportional component falls within the range to provide the phase error signal. Otherwise, the proportional component is modified to meet a phase slope requirement while leaving the integral component unmodified. The modified proportional component is combined with the unmodified integral component to provide the phase error signal.

Abstract: A digital FM transmitter has a digital controlled oscillator for generating a modulated RF carrier. A digital signal processor receives digital input samples and generates a modulating signal for input to the digital controlled oscillator. A bandpass filter for filters frequency components of the modulated carrier outside a predetermined frequency band and supplies the filtered modulated RF carrier to an antenna.