Phase multipliers in power converters

1 . A system, comprising: a pulse-width-modulated (PWM) controller configured to generate an incoming PWM signal PWM in in response to an output voltage signal and/or an output current signal for supply to a load; a phase multiplier configured to generate, in response to the incoming PWM signal PWM in , N-1 PWM signals for N-1 power stages, each of the N-1 PWM signals has the same frequency as the incoming PWM signal PWM in , wherein the phase multiplier is further configured to adjust a duty cycle of each of the N-1 PWM signals in response to a corresponding fine-tuning signal, wherein the phase multiplier comprises: a delay module configured to receive the incoming PWM signal PWM in and copy a pulse width W of the incoming PWM signal PWM in ; N-1 slices of PWM logic circuits configured to receive the pulse width W and a clock signal to generate N-1 PWM signals, wherein each i th slice of the N-1 slices of the PWM logic circuits comprises: a phase shifter configured to generate an i th phase-shifted clock signal; a delay controller configured to receive the pulse width and the i th phase-shifted clock signal to generate an output signal; and, a latch configured to generate an i th PWM signal in response to the phase-shifted clock signal and the output signal such that the phase difference between the i th PWM signal and incoming PWM signal PWM in equals (i-1)*360/N, 2≤i≤N, wherein the delay controller is further configured to update the output signal to adjust the duty cycle of the i th PWM signal in response to a corresponding fine-tuning signal indicating a current difference between an i th current monitor output signal generated by an i th power stage and a reference current output signal generated by a reference power stage. 2 . The system of claim 1 , wherein the delay module comprises a delay-locked-loop (DLL). 3 . The system of claim 1 , wherein the PWM controller is further configured to generate a sync clock signal associated with the PWM in signal to be received by the phase multiplier. 4 . The system of claim 1 , wherein the latch further comprises a set-reset (SR) latch, with a set input coupled to receive the phase-shifted clock signal, and a reset input coupled to receive the output signal of the delay controller, wherein a rising edge of the output signal happens at a time period of W after a rising edge of the phase-shifted clock signal. 5 . The system of claim 1 , further comprising N power stages, each of the N power stages having an output coupled to supply a common output node, and N-1 of the power stages coupled to a corresponding one of the N-1 slices of PWM logic circuits, wherein each of the N-1 power stages is configured to operate according to a duty cycle and phase of a corresponding one of the N-1 PWM signals. 6 . The system of claim 5 , wherein one of the N power stages is coupled to receive the incoming PWM signal PWM in . 7 . The system of claim 1 , wherein the phase multiplier further comprises: a frequency synthesizer configured to generate the clock signal in response to receiving a sync clock signal, wherein the clock signal has a frequency that is 32 times a frequency of the incoming PWM signal PWM in . 8 . The system of claim 7 , wherein the N-1 slices of the PWM logic circuits are further configured to receive the phase-shifted clock signal to generate the N-1 PWM signals. 9 . The system of claim 1 , further comprising: N power stages configure to receive N PWM signals and correspondingly generate N current monitor output signals, wherein the PWM controller is further configured to receive a first current monitor output signal of a first power stage as the reference current output signal, and each of the N-1 slices of the PWM logic circuits further comprises: a phase current control circuit (ISHARE) coupled to receive the N current monitor output signals from the N power stages, wherein the ISHARE is configured to generate the corresponding fine-tuning signal. 10 . The system of claim 9 , wherein the ISHARE comprises: a N-input selection circuit configured to receive the N current monitor output signals from the N power stages, wherein a selection signal is configured to select one of the N current monitor output signals at a frequency that is N times a frequency of the incoming PWM signal PWM in ; an analog-to-digital converter configured to sample and convert each of the N current monitor output signals selected; a calculation circuit configured to generate N average current values corresponding to the N current monitor output signals being sampled and converted; and, a comparator system configured to receive the N average current values and generate N-1 current differences between one of the N average current values and each one of the other N-1 average current values, wherein each of the N-1 current differences is received by a corresponding delay controller as the corresponding fine-tuning signal to adjust the pulse width of the corresponding one of the N-1 PWM signals. 11 . A phase multiplier configured to generate, in response to an incoming PWM signal PWM in , N-1 PWM signals for N-1 power stages, each of the N-1 PWM signals has the same frequency as the incoming PWM signal PWM, wherein the phase multiplier is further configured to adjust a duty cycle of each of the N-1 PWM signals in response to a corresponding fine-tuning signal, the phase multiplier comprises: N-1 slices of PWM logic circuits configured to receive the pulse width W and a system clock signal to generate N-1 PWM signals, wherein each i th slice of the N-1 slices of the PWM logic circuits comprises: a phase shifter configured to generate an i th phase-shifted clock signal in response to the system clock signal; a delay controller configured to receive a pulse width W of the PWM in and the i th phase-shifted clock signal to generate an output signal; and a latch configured to generate an i th PWM signal in response to the i th phase-shifted clock signal and the output signal such that the phase difference between the i th PWM signal and the incoming PWM signal PWM in equals (i-1)*360/N, 2≤i≤N, wherein the delay controller is further configured to update the output signal to adjust the duty cycle of the i th PWM signal in response to a fine-tuning signal indicating a current difference between an i th current monitor output signal generated by an i th power stage and a reference current output signal generated by a reference power stage. 12 . (canceled) 13 . The integrated circuit of claim 11 , further comprising: a frequency synthesizer configured to receive a sync clock signal and generate the system clock signal, wherein the system clock signal has a frequency that is 32 times a frequency of the incoming PWM signal PWM in . 14 . The integrated circuit of claim 11 , wherein the latch further comprises a set-reset (SR) latch, with a set input coupled to receive the i th phase-shifted clock signal, and a reset input coupled to receive the output signal of the delay controller, wherein a falling edge of the output signal happens at a time period of W after a rising edge of the i th phase-shifted clock signal. 15 . The integrated circuit of claim 11 , wherein the delay module comprises a delay-locked-loop (DLL). 16 . A method to generate N-1 pulse-width-modulated (PWM) signals, the method comprising: receiving, by a delay module, an incoming PWM signal PWM in and copying a pulse width W of the incoming PWM signal PWM in ; receiving, by N-1 slices of PWM logic circuits, the pulse width W and a first clock signal to generate