A method and apparatus for performing on-system phase-locked loop (PLL) management in a memory device are provided. The method may include: utilizing a processing circuit within the memory controller to set multiple control parameters among multiple parameters stored in a register circuit of a transmission interface circuit within the memory controller, for controlling parameter adjustment of a PLL of the transmission interface circuit; utilizing a trimming control circuit to perform the parameter adjustment of the PLL according to the multiple control parameters, to adjust a set of voltage parameters among the multiple parameters, for optimizing a control voltage of a voltage controlled oscillator (VCO); and during the parameter adjustment of the PLL, utilizing the trimming control circuit to generate and store multiple processing results in the register circuit, for being sent back to the processing circuit, to complete the parameter adjustment of the PLL, thereby achieving the on-system PLL management.

A method and apparatus for performing on-system phase-locked loop (PLL) management in a memory device are provided. The method may include: utilizing a processing circuit within the memory controller to set multiple control parameters among multiple parameters stored in a register circuit of a transmission interface circuit within the memory controller, for controlling parameter adjustment of a PLL of the transmission interface circuit; utilizing a trimming control circuit to perform the parameter adjustment of the PLL according to the multiple control parameters, to adjust a set of voltage parameters among the multiple parameters, for optimizing a control voltage of a voltage controlled oscillator (VCO); and during the parameter adjustment of the PLL, utilizing the trimming control circuit to generate and store multiple processing results in the register circuit, for being sent back to the processing circuit, to complete the parameter adjustment of the PLL, thereby achieving the on-system PLL management.

An oscillator and a clock circuit are disclosed. In an oscillator (100), a tail inductor connected to a cross-coupled transistor includes at least two inductors connected in parallel. Therefore, an inductance of the tail inductor is less than an inductance of any one of the inductors. This can address a design difficulty that a tail inductor with a smaller inductance needs to be used as an operating frequency of a VCO increases. The oscillator (100) includes a first cross-coupled transistor (121) and a first tail inductor (111). The first tail inductor (111) includes at least two inductors connected in parallel. The first tail inductor (111) is coupled to a source of the first cross-coupled transistor (121). The source of the first cross-coupled transistor (121) is coupled to a power supply or a ground through the first tail inductor (111).

An oscillator and a clock circuit are disclosed. In an oscillator (100), a tail inductor connected to a cross-coupled transistor includes at least two inductors connected in parallel. Therefore, an inductance of the tail inductor is less than an inductance of any one of the inductors. This can address a design difficulty that a tail inductor with a smaller inductance needs to be used as an operating frequency of a VCO increases. The oscillator (100) includes a first cross-coupled transistor (121) and a first tail inductor (111). The first tail inductor (111) includes at least two inductors connected in parallel. The first tail inductor (111) is coupled to a source of the first cross-coupled transistor (121). The source of the first cross-coupled transistor (121) is coupled to a power supply or a ground through the first tail inductor (111).

The present disclosure is directed to a digital phase-locked loop frequency synthesizer including: a digitally controlled voltage-controlled oscillator (DCO); a reference oscillator; a digital phase detector; a DCO control module comprising a plurality of registers each arranged to control the frequency of the signal with a predetermined resolution; a first feedback loop arranged to provide a first feedback path between the output of the DCO and the digital phase detector; and a second feedback loop arranged to provide a second feedback path between the first register output and the second register input, the second feedback loop comprising an adder module arranged to change a value of the second register based on the first register output to maximize a DCO frequency output range provided by the first register.

The present disclosure is directed to a digital phase-locked loop frequency synthesizer including: a digitally controlled voltage-controlled oscillator (DCO); a reference oscillator; a digital phase detector; a DCO control module comprising a plurality of registers each arranged to control the frequency of the signal with a predetermined resolution; a first feedback loop arranged to provide a first feedback path between the output of the DCO and the digital phase detector; and a second feedback loop arranged to provide a second feedback path between the first register output and the second register input, the second feedback loop comprising an adder module arranged to change a value of the second register based on the first register output to maximize a DCO frequency output range provided by the first register.

A method and apparatus for performing on-system phase-locked loop (PLL) management in a memory device are provided. The method may include: utilizing a processing circuit within the memory controller to set multiple control parameters among multiple parameters stored in a register circuit of a transmission interface circuit within the memory controller, for controlling parameter adjustment of a PLL of the transmission interface circuit; utilizing a trimming control circuit to perform the parameter adjustment of the PLL according to the multiple control parameters, to adjust a set of voltage parameters among the multiple parameters, for optimizing a control voltage of a voltage controlled oscillator (VCO); and during the parameter adjustment of the PLL, utilizing the trimming control circuit to generate and store multiple processing results in the register circuit, for being sent back to the processing circuit, to complete the parameter adjustment of the PLL, thereby achieving the on-system PLL management.

A method and apparatus for performing on-system phase-locked loop (PLL) management in a memory device are provided. The method may include: utilizing a processing circuit within the memory controller to set multiple control parameters among multiple parameters stored in a register circuit of a transmission interface circuit within the memory controller, for controlling parameter adjustment of a PLL of the transmission interface circuit; utilizing a trimming control circuit to perform the parameter adjustment of the PLL according to the multiple control parameters, to adjust a set of voltage parameters among the multiple parameters, for optimizing a control voltage of a voltage controlled oscillator (VCO); and during the parameter adjustment of the PLL, utilizing the trimming control circuit to generate and store multiple processing results in the register circuit, for being sent back to the processing circuit, to complete the parameter adjustment of the PLL, thereby achieving the on-system PLL management.

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 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.