Differential charge pump

What is claimed is: 1. A differential charge pump, including: (a) a clock signal having a first phase and a second phase, the second phase being different from the first phase, for controlling switches regulating charge pumping cycles of the differential charge pump; (b) at least two charge pump sections electrically coupled in parallel to an input voltage source separate from the clock signal, wherein each charge pump section generates an output voltage comprising a charge-pumped multiple of an input voltage from the input voltage source, each charge pump section including at least two charge multiplying stages having an input and an output, the input of each charge multiplying stage being switchably coupled to an associated input voltage source separate from the clock signal and the output of each charge multiplying stage being switchably coupled to one of (i) an associated intermediate storage capacitance coupled to and shared with at least one other of the at least two charge pump sections or (ii) a common terminal storage capacitance, each charge multiplying stage including: (1) a fly capacitor having an input and an output; (2) a first switch coupled between the input of the fly capacitor and an intermediate node, and coupled to and controlled by a selected one of the first phase or the second phase of the clock signal; (3) a second switch coupled between the intermediate node and the output of the fly capacitor, and coupled to and controlled by a selected one of the second phase or the first phase of the clock signal, the selected phase controlling the second switch being different from the selected phase controlling the first switch; and wherein the charge pumping cycle in at least a first one of the charge pump sections is initiated on the first phase of the clock signal, and the charge pumping cycle in at least a second one of the charge pump sections is initiated on the second phase of the clock signal. 2. The differential charge pump of claim 1 , wherein the output voltage of the charge pump is the opposite polarity with respect to the input voltage source. 3. The differential charge pump of claim 1 , wherein the output voltage of the charge pump is the same polarity with respect to the input voltage source. 4. The differential charge pump of claim 1 , wherein each charge pump section includes two charge multiplying stages. 5. The differential charge pump of claim 1 , wherein each charge pump section includes at least three charge multiplying stages. 6. The differential charge pump of claim 1 , wherein the first switch and the second switch of each charge multiplying stage are field effect transistors. 7. The invention of claim 1 , wherein the output of at least one charge multiplying stage is switchably coupled to the associated intermediate storage capacitance coupled to and shared with at least one other of the at least two charge pump sections, and the output of at least one other charge multiplying stage is switchably coupled to the common terminal storage capacitance. 8. A differential charge pump, including: (a) a clock signal having a first phase and a second phase, the second phase being different from the first phase, for controlling switches regulating charge pumping cycles of the differential charge pump; (b) a first means for pumping charge coupled to an input voltage source separate from means for providing the clock signal for generating an output voltage comprising a charge-pumped multiple of an input voltage from the input voltage source, the first means for pumping charge including at least two charge multiplying stages having an input and an output, the input of each charge multiplying stage being switchably coupled to an associated input voltage source separate from the clock signal and the output of each charge multiplying stage being switchably coupled to one of (i) an associated intermediate storage capacitance or (ii) a common terminal storage capacitance, each charge multiplying stage including: (1) a fly capacitor having an input and an output; (2) a first switch coupled between the input of the fly capacitor and an intermediate node, and coupled to and controlled by a selected one of the first phase or the second phase of the clock signal; (3) a second switch coupled between the intermediate node and the output of the fly capacitor, and coupled to and controlled by a selected one of the second phase or the first phase of the clock signal, the selected phase controlling the second switch being different from the selected phase controlling the first switch; (c) a second means for pumping charge electrically coupled to the input voltage source for generating an output voltage comprising a charge-pumped multiple of an input voltage from the input voltage source, and electrically coupled in parallel to the first means for pumping charge, the second means for pumping charge including at least two charge multiplying stages having an input and an output, the input of each charge multiplying stage being switchably coupled to an associated input voltage source separate from the clock signal and the output of each charge multiplying stage being switchably coupled to one of (i) an associated intermediate storage capacitance coupled to and shared with a corresponding one of the charge multiplying stages of the first means for pumping charge or (ii) a common terminal storage capacitance, each charge multiplying stage including: (1) a fly capacitor having an input and an output; (2) a first switch coupled between the input of the fly capacitor and an intermediate node, and coupled to and controlled by a selected one of the first phase or the second phase of the clock signal; (3) a second switch coupled between the intermediate node and the output of the fly capacitor, and coupled to and controlled by a selected one of the second phase or the first phase of the clock signal, the selected phase controlling the second switch being different from the selected phase controlling the first switch; (d) means for initiating a charge pumping cycle in the first means for pumping charge on the first phase of the clock signal; and (e) means for initiating a charge pumping cycle in the second means for pumping charge on the second phase of the clock signal. 9. The differential charge pump of claim 8 , wherein the output voltage of the charge pump is the opposite polarity with respect to the input voltage source. 10. The differential charge pump of claim 8 , wherein the output voltage of the charge pump is the same polarity with respect to the input voltage source. 11. The differential charge pump of claim 8 , wherein the first means for pumping charge and the second means for pumping charge each include two charge multiplying stages. 12. The differential charge pump of claim 8 , wherein the first means for pumping charge and the second means for pumping charge each include at least three charge multiplying stages. 13. The differential charge pump of claim 8 , wherein the first switch and the second switch of each charge multiplying stage are field effect transistors. 14. The invention of claim 8 , wherein, for each of the first means and second means for pumping charge, the output of at least one charge multiplying stage is switchably coupled to the associated intermediate storage capacitance coupled to and shared with at least one other of the at least two charge pump sections, and the output of at least one other charge multiplying stage is switchably coupled to the common terminal storage capacitance. 15. A method for operating a charge pump, including the steps of: (a) providing a clock signal h