Disclosed are a control signal pulse width extraction-based phase-locked acceleration circuit and a phase-locked loop system, the phase-lock acceleration circuit includes a pulse width extraction control circuit and a current injection switch module; the control output terminal of the pulse width extraction control circuit is connected to the current injection control terminal of the current injection switch module, and the stepping current control terminal of the current injection switch module and the driving input terminal of the pulse width extraction control circuit are both connected to the preset control signal output end of a phase frequency detector for use in controlling, according to pulse width changes of signals outputted by the preset control signal output end, the current injection switch module to inject charges until the phases of a reference clock signal and feedback clock signal inputted by the phase frequency detector are synchronized.

A PLL circuit includes a phase comparator, an integrator path, a proportional path, a current controlled oscillator, a divider, and a double integrator path. The double integrator path includes an intermittent operation gm amplifier, a filter circuit, and a voltage-current conversion circuit. The intermittent operation gm amplifier receives an output voltage of a filter circuit. When a pulse CLK for an intermittent operation is ON, the intermittent operation gm amplifier outputs its voltage to the filter circuit. When the pulse CLK for the intermittent operation is OFF, the intermittent operation gm amplifier does not output the output voltage of the filter circuit to the filter circuit. Even when the pulse CLK for the intermittent operation is OFF, an input potential of the voltage-current conversion circuit is held by the filter circuit, and a current to the current controlled oscillator flows. This makes it possible to oscillate at a high frequency without increasing an area of the filter circuit.

A hybrid Phase Locked Loop, PLL (10, 34A, 34B, 38) employs an analog control loop during a first period of operation, such as steady-state operation, to achieve a simple design, stable operation at very high frequency, and low phase noise. During a second period of operation, such as frequency changes, a digital control loop takes over. Under digital control, charge pump (14) inputs are forced to be at or near 100% duty cycle for maximum loop filter (16) charging and fast, linear frequency change. The digital control loop monitors when the target frequency is reached, and exits the second period of operation with the proper feedback signal phase. The digital control loop can operate in two control modes. In a first mode, the phase of the divided VCO output signal is synchronized with the phase of a periodic reference signal throughout the frequency change. In a second mode, the frequency and phase are controlled in separate steps, by controlling the integer and fractional parts of delta-sigma generated division number. Three embodiments are disclosed. In a first embodiment, a switch substitutes constant charge pump (14) inputs for the outputs of a phase frequency detector, PFD (12) to maximize the loop filter (16) current. In a second embodiment, one pulse of one of the periodic signals is suppressed, forcing the PFD (12) to output charge pump input signals at near 100% duty cycle. In a third embodiment, all the cycles of one of the periodic signals are suppressed, forcing PFD (12) output signals to 100% duty cycle.

Some examples described herein provide an integrated circuit comprising an auxiliary clock and data recovery (CDR) circuitry. The CDR circuitry is configured to oversample an incoming data signal and generate a locked clock signal. The auxiliary CDR circuitry may comprise a phase-locked loop (PLL) configured to receive the incoming data signal and generate the locked clock signal. The PLL may comprise a phase detector (PD) configured to receive the incoming data signal and capture a number of samples of the incoming data signal in response to a number of adjacent clock signals and minimum data transition thresholds implemented by an intersymbol interference (ISI) filter, the minimum data transition thresholds identifying minimum data transitions in the incoming data signal.

A digital phase-locked loop (PLL) includes a time-to-digital converter (TDC) and a digitally controlled oscillator (DCO). The DCO generates a PLL clock signal and various sampling clock signals that are mesochronous. The TDC samples a phase difference between a reference clock signal and a frequency-divided version of the PLL clock signal based on the sampling clock signals and various enable signals. The enable signals are generated based on a calibration of the digital PLL. Each enable signal is associated with a sampling clock signal and indicates whether the associated sampling clock signal is to be utilized for sampling the phase difference. Further, the TDC generates control data indicative of the sampled phase difference. The DCO generates the PLL clock signal and the sampling clock signals based on the control data until the digital PLL is in a phase-locked state.

In a PLL circuit, first an ILFD is connected to an output voltage Vtune from an LPF, thereby causing the ILFD to operate as an oscillator. The ILFD, a DIV, PFD, CP, and LPF form a PLL and thereby locking operations are initiated. When a predetermined time elapses, an output frequency from the ILFD converges into a certain value and the PLL is subjected to a locked state. After the locked state is reached, a sample hold circuit SH holds the output voltage Vtune from the loop filter as of that time and frequency adjustment of the ILFD is completed. Similar frequency adjustment is sequentially performed on other ILFDs.

A method for generating a clock signal using a digital phase-locked loop includes updating a gain of a variable gain digital filter of the digital phase-locked loop using an estimate error of a current estimate of a phase and a frequency of an input clock signal and a measurement error of a measurement of the phase and the frequency of the input clock signal. The gain may include a proportional gain component and an integral gain component. The method may include calculating the current estimate of the phase and the frequency of the input clock signal based on a previous estimate of the phase and the frequency of the input clock signal, the measurement of the phase and the frequency of the input clock signal, and the gain of the variable gain digital filter. The gain may be updated every cycle of the input clock signal.

An apparatus includes circuitry and an oscillator circuit that may be configured to generate a clock signal dependent upon a control signal. The circuitry may be configured to perform a frequency measurement of the clock signal. In response to a determination that the frequency of the clock signal is greater than a first threshold, the circuitry may also be configured to perform a phase comparison between a divided clock signal and a reference clock signal, and to adjust a value of the control signal such that the adjusted value depends upon a result of the comparison. In response to a determination that the frequency of the clock signal is less than the first threshold, the circuitry may be configured to adjust the value of the control signal such that the adjusted value depends upon a result of the measurement.

Performance indicator circuitry is provided for characterizing performance of a phase locked loop (PLL) in a phase path of a polar modulator or polar transmitter that is used to generate a phase modulated RF signal. The PLL includes an oscillator, a high pass path, and a low pass path. The low pass path includes a loop filter. The performance indicator circuitry includes first input circuitry and parameter calculation circuitry. The first input circuitry is configured to input a loop filter signal from the loop filter. The parameter calculation circuitry is configured to compute a value for a performance indicator based on the loop filter signal and control or characterize an aspect of operation of the PLL based on the value.

A circuit device includes a phase comparator that performs phase comparison between an input signal based on an oscillation signal and a reference signal, a processor that performs a digital signal process on phase comparison result data which is a result of the phase comparison so as to generate frequency control data, and an oscillation signal generation circuit that generates the oscillation signal having an oscillation frequency which is set on the basis of the frequency control data. The processor performs the digital signal process by using data used when a hold-over state is ended in a case where the hold-over state occurs due to the absence or the abnormality of the reference signal, and then the hold-over state is ended.