Abstract: In an example, a system is adapted to be coupled to a load device having a load clock. The system includes a clock generation device with a pin. The system also includes a capture circuit coupled to the pin and operable to sample a value at the pin. The system includes a D flip-flop having a data input coupled to the capture circuit, a clock input coupled to a clock, and having an output, where the D flip-flop is operable to provide, at the output, a system reference event (SYSREF) signal to align the load clock to the clock, based at least in part on the value at the pin.

Abstract: In an example, a system includes an N divider coupled to an output of a low dropout regulator. The system also includes a load balancing circuit coupled to the N divider and configured to sink a load balancing current at the output of the low dropout regulator during one or more phases of the N divider. The system includes a switch coupled to the load balancing circuit and configured to connect the load balancing circuit to the output of the low dropout regulator during the one or more phases of the N divider.

Abstract: In an example, a system is adapted to be coupled to a load device having a load clock. The system includes a clock generation device with a pin. The system also includes a capture circuit coupled to the pin and operable to sample a value at the pin. The system includes a D flip-flop having a data input coupled to the capture circuit, a clock input coupled to a clock, and having an output, where the D flip-flop is operable to provide, at the output, a system reference event (SYSREF) signal to align the load clock to the clock, based at least in part on the value at the pin.

Abstract: A dual-PFD circuit with delay feedback generated by a dual-modulus prescaler based on mode control from a feedback delay generation circuit. The PFD circuit can be used with a PLL feedback divider to divide a VCO clock signal VCO_clk and generate FB and FB_DLY signals. The PLL feedback divider includes a dual modulus prescaler to selectively divide the VCO_clk by either M or M+1 (such as 4/5) based on a divide mode control input to generate a prescaled divide signal, and a programmed counter/divider (N counter/1/N divider) to selectively divide the prescaled divide signal to generate the FB signal, and a delay generation circuit to selectively delay the FB signal by a pre-defined delay to generate the FB_DLY signal. The prescaler is responsive to the pre-defined delay from the delay generation circuit to change divide modes. The dual PFD circuit response to the FB and FB_DLY signals in relation to a reference signal to generate a phase comparison signal.

Abstract: Frequency synthesis is based on phase synchronizing PLL output across REFERENCE and VCO clock domains (including outputs for multiple PLLs), based on an input (REF-Domain) SYNC signal (phase timing reference). A frequency synthesizer includes a VCO to generate VCO_clk and a PLL output circuit, such as a channel divider, to generate PLL_OUT based on VCO_clk (in the VCO-Domain). The VCO loop includes a PD to phase compare an input PD_clock based on REF_CLK, and a VCO feedback signal based on divided VCO_clk (NDIV_out). SYNC alignment circuitry generates a SYNC alignment signal based on SYNC, PD_clk, and NDIV_out (REF-Domain), which is used to synchronize the PLL output circuit and PLL_OUT to SYNC. If a reference divider generates PD_clk, the SYNC alignment circuitry generates a reset to SYNC-align the reference divider. If the VCO loop uses fractional divide, the SYNC alignment circuitry resets the fractional modulator to a known sequence.

Abstract: A dual-PFD circuit with delay feedback generated by a dual-modulus prescaler based on mode control from a feedback delay generation circuit. The PFD circuit can be used with a PLL feedback divider to divide a VCO clock signal VCO_clk and generate FB and FB_DLY signals. The PLL feedback divider includes a dual modulus prescaler to selectively divide the VCO_clk by either M or M+1 (such as 4/5) based on a divide mode control input to generate a prescaled divide signal, and a programmed counter/divider (N counter/1/N divider) to selectively divide the prescaled divide signal to generate the FB signal, and a delay generation circuit to selectively delay the FB signal by a pre-defined delay to generate the FB_DLY signal. The prescaler is responsive to the pre-defined delay from the delay generation circuit to change divide modes. The dual PFD circuit response to the FB and FB_DLY signals in relation to a reference signal to generate a phase comparison signal.