A PLL circuit includes a fractional-N divider generating a feedback signal, a first phase-frequency detector that compares the feedback signal to a reference signal to generate first up/down control signals that control a charge pump to generate a charge pump output current. A noise cancelation circuit includes a synchronization circuit that generates first and second synchronized feedback signals from the PLL circuit output and the feedback signal, where the first and second synchronized feedback signals are offset by an integer number of cycles of the PLL circuit output. A second phase-frequency detector circuit compares the first and second synchronized feedback clock signals to generate second up/down control signals whose pulse widths differ by the integer number of PLL cycles. A current digital to analog converter circuit is controlled in response to the second up/down control signals to apply noise canceling sourcing and sinking currents to the charge pump output current.

In described examples, a phase locked loop (PLL) has a first phase detector cell (PD) that has a gain polarity. The first PD cell has a phase error output and inputs coupled to a reference frequency signal and a feedback signal. A second PD cell has an opposite gain polarity. The second PD cell has a phase error output and inputs coupled to the reference frequency signal and the feedback signal. A loop filter has a feedforward path and a (lossy) integrating path coupled to an output of the filter. The feedforward path has a third PD cell that has phase error output AC-coupled to the filter output. The integrating path includes an opamp that has an inverting input coupled to the first PD cell phase error output and a non-inverting input coupled to the second PD cell phase error output.

In described examples, a feedback loop has phase detection (PD) circuitry that has a reference input to receive a reference frequency signal, a feedback input to receive a feedback signal, and phase difference outputs. A phase to digital converter (P2DC) includes a first phase to charge converter (PCC) that has a gain polarity and a first phase error output; a second PCC that has an opposite gain polarity and a second phase error output. A differential loop filter has an amplifier with an inverting input coupled to the first phase error output and a non-inverting input coupled to the second phase error output. An analog to digital converter (ADC) has an input coupled to an output of the differential loop filter. A feedback path is coupled to the output of the P2DC, with an output of the feedback path providing the feedback signal to the PD feedback input.

A PLL circuit includes: a charge pump; a voltage-controlled oscillator including an oscillation portion; and a voltage-converting circuit configured to convert a voltage from the charge pump and apply the converted voltage to the voltage-controlled oscillator. The power supply range supplied to the voltage-converting circuit is larger than the power supply range supplied to the oscillation portion of the voltage-controlled oscillator.

A method of a phase-locked loop circuit includes: using a phase detector to generate a charging current signal according to an input frequency signal and a feedback signal; limiting a voltage level corresponding to the charging current signal in a voltage range according to a prediction signal to generate a digital output; performing a low-pass filter operation according to the digital output; generating a digital controlled oscillator (DCO) frequency signal according to an output of the loop filter; generating the feedback signal according to the DCO frequency signal; generating a phase signal, which indicates accumulated phase shift information, according to information of the feedback circuit and fractional frequency information; and, generating the prediction signal according to the phase signal.

A charge pump for use in a Phase Locked Loop/Delay Locked Loop minimizes static phase error through the use of an operational amplifier. The operational amplifier also mitigates the effects of low power supply voltage.

A phase locked loop having a charge pump is described. The charge pump has circuitry to select a mode for each semiconductor chip from a plurality of modes to enhance yield. Nine unique modes are defined from which a selection is made for each chip. The selected mode mitigates effects of device mistracking anomalies for each chip. A method is provided to show how the modes are determined and prioritized.

A charge pump device includes first to third current source circuits, a first switch, and a second switch. The first current source circuit is implemented with a first type transistor, and provides a first current to an output node. The first switch is selectively turned on according to a first control signal. When the first switch is turned on, the second current source circuit drains a second current from the output node. The second switch is selectively turned on according to a second control signal. Each of the first switch and the second switch is implemented with a second type transistor, and a withstand voltage of the first type transistor is higher than a withstand voltage of the second type transistor. When the second switch is turned on, the third current source circuit drains a third current from the output node.

A charge pump (321), a phase-locked loop circuit (301), and a clock control apparatus are provided, related to the field of wireless communications technologies, to implement a high-speed and low-noise charge pump in the clock control apparatus. The charge pump includes a degeneration circuit (3210), a charging current source transistor (Mio 1), a switch circuit (3211) and a discharging current source transistor (Mc 2). The charging current source transistor is configured to provide a charging current. The degeneration circuit is coupled between a first terminal of the charging current source transistor and a power supply terminal. The degeneration circuit is configured to degrade a first voltage corresponding to the power supply terminal to a second voltage. The switch circuit is coupled between a second terminal of the charging current source transistor and a load. The switch circuit is configured to control a charging current output to the load.

Apparatus and methods for timing offset compensation of frequency synthesizers are provided herein. In certain embodiments, an electronic system includes a frequency synthesizer, such as a fractional-N phase-locked loop (PLL), which generates an output clock signal based on timing of a reference clock signal. Additionally, the electronic system includes an integer PLL configured to compensate for a timing offset, such as a phase offset and/or frequency offset, of the frequency synthesizer based on timing of the output clock signal.