Abstract: An apparatus includes a phase-locked loop (PLL) circuit including a phase-frequency detector configured to output phase error signals. A phase error monitor circuit is configured to determine instantaneous peak phase error by logically combining the phase error signals and comparing pulse widths of the logically combined phase error signals to a programmable delay time at each reference clock cycle to determine instantaneous phase error change. A storage element is configured to store the instantaneous phase error change.

Abstract: Phase interpolation techniques for voltage-controlled delay line (VCDL) implementation are provided. The techniques of the invention may employ a second-order phase interpolation topology to improve tuning range performance of the VCDL over process and temperature variation. In one aspect of the invention, the technique may use a complementary input signal to set an absolute 180-degree phase reference. As a result, the maximum tuning range of 180 degrees can be achieved regardless of internal delay variation.

Abstract: An instantaneous phase error detector (IPED) and method includes a first gate configured to logically OR output phase error signals as data to a first latch, and a second gate configured to logically combine the output phase error signals to clock the first latch. A delay element delays to the data to the first latch where the output of the first latch provides instantaneous phase error change information. A second latch is coupled to the output phase error signals to output a lead/lag signal to indicate which of the output phase error signals is leading. A phase-locked loop employing the output of the IPED is also disclosed along with static phase measurement and jitter optimization features.

Abstract: An instantaneous phase error detector (IPED) and method includes a first gate configured to logically OR output phase error signals as data to a first latch, and a second gate configured to logically combine the output phase error signals to clock the first latch. A delay element delays to the data to the first latch where the output of the first latch provides instantaneous phase error change information. A second latch is coupled to the output phase error signals to output a lead/lag signal to indicate which of the output phase error signals is leading. A phase-locked loop employing the output of the IPED is also disclosed along with static phase measurement and jitter optimization features.

Abstract: An apparatus includes a phase-locked loop (PLL) circuit including a phase-frequency detector configured to output phase error signals. A phase error monitor circuit is configured to determine instantaneous peak phase error by logically combining the phase error signals and comparing pulse widths of the logically combined phase error signals to a programmable delay time at each reference clock cycle to determine instantaneous phase error change. A storage element is configured to store the instantaneous phase error change.

Abstract: There are provided relaxation oscillators and methods for controlling the same. A relaxation oscillator includes a load device, a switching device, a fine-tuning varactor, and a current source. The load device is configured to provide a variable oscillator output based on a variable input reference voltage. The switching device is connected in signal communication with the load device and is configured to become active and inactive based on the variable oscillator output. The fine-tuning varactor is connected in signal communication with the switching device and is configured to provide fine-tuning of the variable oscillator output when the switching device is active. The current source is connected in signal communication with the switching device and is configured to provide coarse-tuning of the variable oscillator output when the switching device is active.

Abstract: A hybrid circuit includes a current-starved voltage-controlled circuit configured to adjust a first type of signal difference, and a phase-interpolated voltage controlled circuit configured to adjust a second type of signal difference. The current-starved circuit and the phase-interpolated circuit cooperate to provide improved operational performance of the hybrid circuit.

Abstract: A method of differentially controlling an LC voltage controlled oscillator (VCO) includes providing an LC-VCO comprising at least one inductor, measuring an inductor common voltage (CMV) output at a point along the at least one inductor, utilizing the measured inductor CMV as an input to a charge pump, and outputting from the charge pump a plurality of differential control voltages to control an output of the LC-VCO.

Abstract: A hybrid circuit includes a current-starved voltage-controlled circuit configured to adjust a first type of signal difference, and a phase-interpolated voltage controlled circuit configured to adjust a second type of signal difference. The current-starved circuit and the phase-interpolated circuit cooperate to provide improved operational performance of the hybrid circuit.

Abstract: Improved voltage controlled oscillator circuits and phase-locked loop circuits are disclosed. For example, a voltage controlled oscillator circuit comprises a first linear amplifier, the first linear amplifier generating a coarse-tuning voltage from an input voltage, a second linear amplifier, the second linear amplifier generating a fine-tuning voltage from the input voltage, and a voltage controlled oscillator comprising a coarse-tuning input coupled to the first linear amplifier, a fine-tuning input coupled to the second linear amplifier, and a clock signal output, wherein a frequency of a signal on the clock signal output is changeable as a function of the input voltage. Such a voltage controlled oscillator circuit may be employed in a phase-locked loop circuit.

Abstract: Improved voltage controlled oscillator circuits and phase-locked loop circuits are disclosed. For example, a voltage controlled oscillator circuit comprises a first linear amplifier, the first linear amplifier generating a coarse-tuning voltage from an input voltage, a second linear amplifier, the second linear amplifier generating a fine-tuning voltage from the input voltage, and a voltage controlled oscillator comprising a coarse-tuning input coupled to the first linear amplifier, a fine-tuning input coupled to the second linear amplifier, and a clock signal output, wherein a frequency of a signal on the clock signal output is changeable as a function of the input voltage. Such a voltage controlled oscillator circuit may be employed in a phase-locked loop circuit.

Abstract: There are provided relaxation oscillators and methods for controlling the same. A relaxation oscillator includes a load device, a switching device, a fine-tuning varactor, and a current source. The load device is configured to provide a variable oscillator output based on a variable input reference voltage. The switching device is connected in signal communication with the load device and is configured to become active and inactive based on the variable oscillator output. The fine-tuning varactor is connected in signal communication with the switching device and is configured to provide fine-tuning of the variable oscillator output when the switching device is active. The current source is connected in signal communication with the switching device and is configured to provide coarse-tuning of the variable oscillator output when the switching device is active.

Abstract: A clock and data recovery circuit includes a delay-locked-loop adapted to recover data from a data stream: and a phase-locked-loop in communication with the delay-locked-loop and adapted to recover a clock signal from the data stream.

Abstract: A method of differentially controlling an LC voltage controlled oscillator (VCO) includes providing an LC-VCO comprising at least one inductor, measuring an inductor common voltage (CMV) output at a point along the at least one inductor, utilizing the measured inductor CMV as an input to a charge pump, and outputting from the charge pump a plurality of differential control voltages to control an output of the LC-VCO.

Abstract: Improved voltage controlled oscillator circuits and phase-locked loop circuits are disclosed. For example, a voltage controlled oscillator circuit comprises a first linear amplifier, the first linear amplifier generating a coarse-tuning voltage from an input voltage, a second linear amplifier, the second linear amplifier generating a fine-tuning voltage from the input voltage, and a voltage controlled oscillator comprising a coarse-tuning input coupled to the first linear amplifier, a fine-tuning input coupled to the second linear amplifier, and a clock signal output, wherein a frequency of a signal on the clock signal output is changeable as a function of the input voltage. Such a voltage controlled oscillator circuit may be employed in a phase-locked loop circuit.

Abstract: A low-power full-rate semidigital DLL architecture using an analog-based FSM (AFSM). The AFSM is a mixed-mode FSM in which analog integration is substituted for digital filtering, thus enabling a lower power implementation of the clock and data recovery function. An integrated voltage is converted to a digital code by an analog-to-digital converter (ADC), and the digital code is used either directly or after (low frequency) digital signal processing to control a controllable delay element, such as, a phase rotator, for data edge tracking.

Abstract: A low-power full-rate semidigital DLL architecture using an analog-based FSM (AFSM). The AFSM is a mixed-mode FSM in which analog integration is substituted for digital filtering, thus enabling a lower power implementation of the clock and data recovery function. An integrated voltage is converted to a digital code by an analog-to-digital converter (ADC), and the digital code is used either directly or after (low frequency) digital signal processing to control a a controllable delay element, such as, a phase rotator, for data edge tracking.

Abstract: Phase interpolation techniques for voltage-controlled delay line (VCDL) implementation are provided. The techniques of the invention may employ a second-order phase interpolation topology to improve tuning range performance of the VCDL over process and temperature variation. In one aspect of the invention, the technique may use a complementary input signal to set an absolute 180-degree phase reference. As a result, the maximum tuning range of 180 degrees can be achieved regardless of internal delay variation.

Abstract: A clock and data recovery circuit includes a delay-locked-loop adapted to recover data from a data stream: and a phase-locked-loop in communication with the delay-locked-loop and adapted to recover a clock signal from the data stream.

Abstract: An oscillator has a slope-fixing circuit that generates a control signal and fixes the slope of the control signal, a swing-fixing circuit that fixes the swing of the control signal, and a switching block that generates an output signal having a frequency derived from the swing and the slope of the control signal. The slope-fixing circuit comprises a fixed timing capacitor C1 in parallel with a plurality of switchable timing capacitors C2 . . . CN to provide an effective capacitance C. The slope of the control signal is determined by the ratio of a control current I to the effective capacitance C. The swing-fixing circuit comprises a replica cell that accepts a programmable reference voltage VREF and provides a fixed voltage swing VSW=VDD−VREF across a pair of load transistors. The switching block comprises a pair of switching transistors that alternate between “on” and “off” states depending on the value of the control signal to produce an oscillating output signal.