Phase modulator having fractional sample interval timing skew for frequency control input

The invention claimed is: 1. A method, comprising: determining an output frequency control word (FCW) having a plurality of bits, the output FCW being configured to control an oscillator of a phase-locked loop circuit, the oscillator comprising a plurality of capacitor banks, the plurality of capacitor banks respectively corresponding to the plurality of bits of the output FCW; storing the output FCW in a clocked delay cell, wherein the clocked delay cell comprises a series of D flip-flops; providing an input clock to the clocked delay cell, wherein the input clock is provided to delay the output FCW by an amount of delay based on a clock period of the input clock minus an estimated loop delay in a portion of the phase-locked loop circuit; and in accordance with the input clock, releasing the delayed output FCW from the clocked delay cell, and respectively applying the plurality of bits of the delayed output FCW to the plurality of capacitor banks of the oscillator. 2. The method of claim 1 , wherein providing the input clock comprises: providing a modified system clock as the input clock. 3. The method of claim 2 , wherein the modified system clock comprises: a system clock designed for the phase-locked loop circuit. 4. The method of claim 2 , wherein the modified system clock comprises: a delayed system clock provided from a second delay cell, the second delay cell configured to apply a second delay to a system clock designed for the phase-locked loop. 5. The method of claim 2 , wherein the modified system clock comprises: a selected system clock provided from a tunable multi-phase circuit. 6. The method of claim 5 , wherein the tunable multi-phase circuit is local to the phase-locked loop circuit and the selected system clock is provided from the tunable multi-phase circuit from a system clock. 7. The method of claim 5 , wherein the tunable multi-phase circuit is located remotely from the phase-locked loop circuit and the selected system clock is provided from the tunable multi-phase circuit locally to a system clock and the selected system clock is distributed across a chip to the phase-locked loop circuit. 8. The method of claim 1 , wherein providing the input clock comprises: providing a selected modified system clock as the input clock from a plurality of modified system clock options. 9. The method of claim 8 , wherein the plurality of modified system clock options comprises two or more of: a system clock designed for the phase-locked loop circuit, a delayed system clock provided from a second delay cell, the second delay cell configured to apply a second delay to the system clock designed for the phase-locked loop circuit, a first selected system clock provided from a first tunable multi-phase circuit, wherein the first tunable multi-phase circuit is local to the phase-locked loop circuit, and a second selected system clock provided from a second tunable multi-phase circuit, wherein the second tunable multi-phase circuit is located remotely from the phase-locked loop circuit and the selected system clock is distributed across a chip to the phase-locked loop circuit. 10. The method of claim 1 , wherein determining the output FCW comprises: receiving an input FCW and responsively providing the output FCW. 11. The method of claim 10 , wherein receiving the input FCW further comprises: determining the input FCW by interpolating between successive values of an initial input FCW. 12. The method of claim 10 , wherein receiving the input FCW and responsively providing the output FCW further comprises: receiving the input FCW and responsively providing the output FCW based on (i) an interpolation between two reference output FCWs of a set of reference output FCWs and (ii) a sensitivity characteristic of a plurality of sensitivity characteristics respectively corresponding to the plurality of capacitor banks of the oscillator. 13. The method of claim 12 , wherein determining the output FCW further comprises: determining the plurality of sensitivity characteristics by determining, for each capacitor bank of the plurality of capacitor banks of the oscillator, a respective sensitivity characteristic of the capacitor bank; and determining the set of reference output FCWs for an associated set of frequencies of the oscillator. 14. The method of claim 13 , wherein the respective sensitivity characteristic of the capacitor bank indicates a change in a frequency of the oscillator that occurs as a result of an incremental addition of each capacitor in the capacitor bank. 15. The method of claim 13 , wherein determining, for each capacitor bank of the plurality of capacitor banks of the oscillator, the respective sensitivity characteristic of the capacitor bank comprises: measuring first and second frequencies of the oscillator by turning on (i) a first number of capacitors in the capacitor bank to measure the first frequency and (ii) a second number of capacitors in the capacitor bank to measure the second frequency; and determining the respective sensitivity characteristic of the capacitor bank based on a difference between the first and second frequencies and a difference between the first and second number of capacitors. 16. The method of claim 13 , wherein determining the set of reference FCWs for the associated set of frequencies of the oscillator comprises: selecting a number of desired frequencies of the oscillator; and for each desired frequency of the oscillator: providing an initial FCW to the oscillator and thereafter adjusting the initial FCW by selectively setting capacitance values of the at least two capacitor banks of the oscillator so as to cause the oscillator to generate approximately the desired frequency; and setting the adjusted initial FCW as a reference output FCW associated with the desired frequency. 17. A circuit comprising: an oscillator circuit, wherein the oscillator circuit includes a tank circuit having a plurality of capacitor banks; and a frequency control word (FCW) processing circuit configured to determine an output FCW having a plurality of bits, the output FCW being configured to control the oscillator of a phase-locked loop circuit, wherein the plurality of capacitor banks of the oscillator respectively correspond to the plurality of bits of the output FCW; a clocked delay cell configured to store the output FCW, wherein the clocked delay cell comprises a series of D flip-flops; and an input clock selection circuit configured to provide an input clock to the clocked delay cell, wherein the input clock is provided to delay the output FCW by an amount of delay based on a clock period of the input clock minus an estimated loop delay in a portion of the phase-locked loop circuit; wherein the clocked delay cell is further configured to, in accordance with the input clock, release the delayed output FCW from the clocked delay cell and respectively apply the plurality of bits of the delayed output FCW to the plurality of capacitor banks of the oscillator. 18. The circuit of claim 17 , wherein the input clock selection circuit comprises: a multiplexer circuit configured to provide, from one or more modified system clock options, a selected modified system clock as the input clock to the clocked delay cell, the multiplexer circuit configured to receive a selection of the modified system clock at a select input of the multiplexer circuit. 19. The circuit of claim 17 , wherein the FCW processing circuit comprises: a linearization circuit coupled to the clocked delay cell