Adjusting the magnitude of a capacitance of a digitally controlled circuit

What is claimed is: 1. An apparatus comprising: a digitally controlled circuit having a variable capacitance; and a controller configured to adjust a magnitude of the variable capacitance of the digitally controlled circuit; wherein the digitally controlled circuit comprises a plurality of gain elements, the plurality of gain elements comprising one or more positive voltage-to-frequency gain elements and one or more negative voltage-to-frequency gain elements; wherein the controller is configured to adjust the magnitude of the capacitance by adjusting the gain provided by respective ones of the gain elements in an alternating sequence of the positive voltage-to-frequency gain elements and the negative voltage-to-frequency gain elements; wherein the one or more positive voltage-to-frequency gain elements are configured such that increasing a magnitude of a control voltage applied to one or more of the positive voltage-to-frequency gain elements increases a frequency of the digitally controlled circuit; and wherein the one or more negative voltage-to-frequency gain elements are configured such that decreasing the magnitude of the control voltage applied to one or more of the negative voltage-to-frequency gain elements increases the frequency of the digitally controlled circuit. 2. The apparatus of claim 1 , further comprising: a digital-to-analog converter providing a digital-to-analog control voltage responsive to control codes supplied by the controller; and a plurality of switches configured to select one of the digital-to-analog control voltage, a fixed high voltage and a fixed low voltage to connect to corresponding ones of the plurality of gain elements responsive to corresponding control signals from the controller; wherein the controller is configured to adjust the control signals such that one of the plurality of gain elements is supplied with the digital-to-analog control voltage while remaining ones of the plurality of gain elements are supplied with the fixed high voltage or the fixed low voltage. 3. The apparatus of claim 2 , wherein the digital-to-analog converter comprises a transfer function such that at least a top two control codes produce a same maximum voltage and at least a bottom two control codes produce a same minimum voltage. 4. The apparatus of claim 1 , wherein the plurality of gain elements comprises two or more banks of gain elements, the control signals for gain elements in the two or more banks being offset from one another. 5. The apparatus of claim 4 , wherein the magnitude of the offset of the control signals is based at least in part on the number of banks of gain elements. 6. The apparatus of claim 4 , further comprising: first and second digital-to-analog converters providing respective first and second digital-to-analog control voltages responsive to control codes supplied by the controller; a first plurality of switches configured to select one of the first digital-to-analog control voltage, a fixed high voltage and a fixed low voltage to connect to corresponding ones of a first one of the two or more banks of gain elements responsive to corresponding control signals from the controller; a second plurality of switches configured to select one of the second digital-to-analog control voltage, the fixed high voltage and the fixed low voltage to connect to corresponding ones of a second one of the two or more banks of gain elements responsive to corresponding control signals from the controller; wherein the controller is configured to adjust the control signals such that one of the gain elements in the first bank is supplied with the first digital-to-analog control voltage, one of the gain elements in the second bank is supplied with the second digital-to-analog control voltage, and remaining ones of the gain elements in the first bank and the second bank are supplied with the fixed high voltage or the fixed low voltage. 7. The apparatus of claim 1 , wherein the digitally controlled circuit comprises one of an oscillator and a filter. 8. The apparatus of claim 1 , wherein the plurality of gain elements comprise varactors. 9. The apparatus of claim 1 , wherein the digitally controlled circuit comprises two or more digitally switched high-Q capacitors for coarse band tuning of the magnitude of the variable capacitance, the plurality of gain elements comprising a plurality of digitally controlled varactors providing for continuous tuning of the magnitude of the variable capacitance within a given coarse band. 10. The apparatus of claim 1 , wherein the plurality of gain elements comprise high-Q switched capacitors. 11. The apparatus of claim 10 , wherein each of the high-Q switched capacitors comprises a first switched capacitor controlled by a first transistor and a second switched capacitor controlled by a second transistor, the controller being configured to provide a same control voltage to each of the first transistor and the second transistor, the first transistor and the second transistor having different threshold voltages. 12. An integrated circuit comprising: a digitally controlled circuit having a variable capacitance; and a controller configured to adjust a magnitude of the variable capacitance of the digitally controlled circuit; wherein the digitally controlled circuit comprises a plurality of gain elements, the plurality of gain elements comprising one or more positive voltage-to-frequency gain elements and one or more negative voltage-to-frequency gain elements; wherein the controller is configured to adjust the magnitude of the capacitance by adjusting the gain provided by respective ones of the gain elements in an alternating sequence of the positive voltage-to-frequency gain elements and the negative voltage-to-frequency gain elements; wherein the one or more positive voltage-to-frequency gain elements are configured such that increasing a magnitude of a control voltage applied to one or more of the positive voltage-to-frequency gain elements increases a frequency of the digitally controlled circuit; and wherein the one or more negative voltage-to-frequency gain elements are configured such that decreasing the magnitude of the control voltage applied to one or more of the negative voltage-to-frequency gain elements increases the frequency of the digitally controlled circuit. 13. A phase-locked loop comprising: a phase detector; a filter having at least one input coupled to at least one output of the phase detector; a controller having at least one input coupled to at least one output of the filter; an oscillator having a variable capacitance, the oscillator having at least one input coupled to at least one output of the controller; and a divider having at least one input coupled to at least one output of the oscillator and at least one output coupled to at least one input of the phase detector; wherein the oscillator comprises a plurality of gain elements, the plurality of gain elements comprising one or more positive voltage-to-frequency gain elements and one or more negative voltage-to-frequency gain elements; wherein the controller is configured to adjust the magnitude of the capacitance by adjusting the gain provided by respective ones of the gain elements in an alternating sequence of the positive voltage-to-frequency gain elements and the negative voltage-to-frequency gain elements; wherein the one or more positive voltage-to-frequency gain elements are configured such that increasing a magnitude of a control voltage applied to one or more of the positive voltage-to-frequency gain elements increases a frequency of the digitally controlled circuit; and wherein the one or more neg