A device and method of clock synchronization for external memory interface. The device, and method, generating a clock output from a phase lock loop block via a sub-module clocking component; multiplexing the clock output through a global clock into different clock domains; clocking the data and an address or a command path by each clock domain; clocking the phase compensation FIFO by clock domain and clock phase alignment clock; generating the pointer for the phase compensation FIFO from central pointer generator block; and synchronizing the pointer of the adjacent intellectual property module with a parent intellectual property module.

In a reference signal generator including a synchronization circuit configured to convert a digital signal into an analog signal, supply this signal to a voltage controlled oscillator, and control the voltage controlled oscillator to obtain a signal synchronized with the reference signal, without an accumulation of quantization error in a holdover control in which an acquisition of a reference signal is not available. The reference signal generator includes a phase synchronization circuit and a controller. The phase synchronization circuit controls the reference signal outputted from the oscillator, according to a control signal obtained based on the reference signal. The controller generates a free-running control signal and controls the oscillator when the reference signal becomes unavailable. The oscillator receives discrete values and oscillates accordingly. A digital delta-sigma modulator configured to modulate the free-running control signal of the controller disposed in a subsequent stage of the controller.

A phase discontinuity mitigation implementation within a phased lock loop (PLL) improves throughput of a radio access technology. The throughput is improved by maintaining a phase of the PLL while powering off some devices of the PLL, such as a local oscillator (LO) frequency divider. In one instance, when the PLL is powered down, one or more portions of a delta sigma modulator for the PLL are clocked with a reference clock for the PLL. This implementation maintains phase continuity when the first phase lock loop turns back on.

A phase and frequency detector receives a reference clock signal with a period error and receives a feedback clock signal from a feedback divider. The feedback divider circuit divides a clock signal from a voltage controlled oscillator. The feedback divider divides by different divide values during odd and even cycles of the reference clock signal to cause the feedback clock signal to have a period error that substantially matches the period error of the reference clock signal. The divider values supplied to the feedback divider are determined, at least in part, by the period error of the reference clock signal.

A device and method of clock synchronization for external memory interface. The device, and method, generating a clock output from a phase lock loop block via a sub-module clocking component; multiplexing the clock output through a global clock into different clock domains; clocking the data and an address or a command path by each clock domain; clocking the phase compensation FIFO by clock domain and clock phase alignment clock; generating the pointer for the phase compensation FIFO from central pointer generator block; and synchronizing the pointer of the adjacent intellectual property module with a parent intellectual property module.

Disclosed herein are systems and methods for improved performance of phase-locked loop based clock generators, particularly in the context of wireless audio. A PLL clock generator includes a PLL core configured to receive a module reference clock provided by a communications module and generate a subsystem data clock corresponding to a module data clock of the communications module; and a data clock tracker module configured to receive the module data and subsystem data clocks and determine a corresponding data clock correction factor. The bandwidth of the PLL core may be dynamically changed thereby enabling both fast and very precise settling. The PLL core may use a low jitter frequency reference for the phase detector while an a synchronous and jitter-prone audio sample clock is used to ensure a mean frequency of the PLL core tracks the audio sample clock.

A phase and frequency detector receives a reference clock signal with a period error and receives a feedback clock signal from a feedback divider. The feedback divider circuit divides a clock signal from a voltage controlled oscillator. The feedback divider divides by different divide values during odd and even cycles of the reference clock signal to cause the feedback clock signal to have a period error that substantially matches the period error of the reference clock signal. The divider values supplied to the feedback divider are determined, at least in part, by the period error of the reference clock signal.

A reference frequency signal generator comprises a plurality of ovenized reference crystal oscillators (OCXOs) having different turn-over-temperatures, a selector logic circuit coupled to outputs of the OCXOs, a temperature sensor, and a controller coupled to an output of the temperature sensor. The selector logic circuit outputs one of the outputs of the OCXOs based on a control signal from the controller. The controller also generates control signals for the OCXOs. In some implementations, the reference frequency signal generator includes a phase-locked loop or a fractional output divider coupled to the output of the selector logic circuit and configured to receive a calibration signal from the controller.

A phase-locked loop (PLL) performs hitless switching from a first reference clock (ref1) to a second reference clock (ref2) by entering holdover mode (418), and aligning the feedback clock (fbclk) to the second reference clock while in holdover mode. The alignment is performed by adjusting a divisor input (D) for the multi-mode divider (128) that divides the output clock frequency (PLLout) to generate the feedback clock. Other features are also provided.

An apparatus includes a plurality of monitoring circuits and a reset circuit. The monitoring circuits may each be configured to determine a status of one of a plurality of input signals, transmit one of the input signals to a PLL circuit and generate a loss signal in response to the status. The reset circuit may be configured to receive the loss signal and generate a reset signal in response to the loss signal. One of the input signals may be a primary input used by the PLL circuit. One of the input signals may be a secondary input that has been selected to replace the primary input. The reset signal may be configured to reset a feedback clock divider of the PLL circuit.