System and methods for operating a solenoid valve

What is claimed: 1. A drive circuit for controlling a solenoid valve having a solenoid coil and a poppet configured to translate therein, said drive circuit comprising: a supply bus configured to couple the solenoid coil to a power supply and supply a coil current; a return bus configured to provide a ground path for the coil current; a flyback circuit coupled in parallel to only the solenoid coil, said flyback circuit comprising only a bipolar diode; a switch coupled in series with the solenoid coil and configured to couple and decouple the solenoid coil to said return bus; and a charge pump circuit having at least one capacitor, said charge pump circuit configured to charge said at least one capacitor using the coil current through the solenoid valve, wherein said charge pump circuit is further configured to momentarily change a reference of said at least one capacitor coupled in series with the solenoid coil to boost a voltage applied across the solenoid coil when said switch is opened in order to accelerate a decrease in the coil current through the solenoid coil. 2. The drive circuit of claim 1 , wherein said switch comprises a semiconductor device having drain-source voltage rating of at least a bus voltage for said supply bus plus a reverse breakdown voltage of said bipolar diode. 3. The drive circuit of claim 1 wherein said charge pump circuit is further configured to momentarily change the reference of said at least one capacitor coupled in series with the solenoid coil to boost the voltage applied across the solenoid coil and accelerate an increase in the coil current through the solenoid coil when said switch is closed. 4. The drive circuit of claim 3 , wherein said charge pump circuit further comprises: a field effect transistor (FET) coupled to said at least one capacitor and configured to selectively reference said at least one capacitor to the ground path or open circuit; and a control circuit configured to: open said FET to reference said at least one capacitor to open circuit to discharge the solenoid coil through said bipolar diode. 5. The drive circuit of claim 4 , wherein said control circuit is further configured to couple said at least one capacitor to said flyback circuit to charge said at least one capacitor. 6. The drive circuit of claim 3 , wherein said charge pump circuit is further configured to couple said at least one capacitor in series with another solenoid coil to boost a voltage applied across said another solenoid coil. 7. The drive circuit of claim 1 , wherein said bipolar diode comprises a bipolar transient voltage suppression diode. 8. A drive circuit for controlling a plurality of solenoid valves having respective solenoid coils and respective poppets configured to translate therein, said drive circuit comprising: a supply bus configured to couple the respective solenoid coils to a power supply and supply respective coil currents; respective return buses configured to provide a ground path for the respective coil currents; respective bipolar diodes coupled in parallel to the respective solenoid coils; respective switches coupled in series with the respective solenoid coils and configured to couple and decouple the respective solenoid coils to said respective return buses; and a charge pump circuit having a bank of capacitors, said charge pump circuit configured to charge said bank of capacitors using one or more of the respective coil currents through one or more of the respective solenoid valves, wherein said charge pump circuit is further configured to momentarily change a reference of said bank of capacitors coupled in series with the respective solenoid coils to boost a voltage applied across the respective solenoid coils when said respective switches are opened in order to accelerate a decrease in the respective coil currents through the respective solenoid valves. 9. The drive circuit of claim 8 wherein said charge pump circuit is further configured to momentarily change the reference of said bank of capacitors coupled in series with the respective solenoid coils to boost the voltage applied across the respective solenoid coils and accelerate an increase in the respective coil currents through the respective solenoid valves when said respective switches are closed. 10. The drive circuit of claim 9 , wherein said charge pump circuit further comprises: a field effect transistor (FET) coupled to said bank of capacitors and configured to selectively reference said bank of capacitors to the ground path or open circuit; and a control circuit configured to: open said FET to reference said bank of capacitors to open circuit to discharge the respective solenoid coils through said respective bipolar diodes. 11. The drive circuit of claim 9 , wherein the plurality of solenoid valves comprises a first group of valves controlled out of phase with respect to a second group of valves, wherein said respective switches for said first group of valves are synchronized to open and close together, and wherein said respective switches for said second group of valves are synchronized to open and close together. 12. The drive circuit of claim 11 further comprising a plurality of switches configured to couple said bank of capacitors for said charge pump circuit to the respective solenoid coils for said first group of valves and for said second group of valves to charge said bank of capacitors through the respective solenoid coils. 13. The drive circuit of claim 11 , wherein said first group of valves comprises only one solenoid valve, and wherein said second group of valves comprises only one other solenoid valve. 14. The drive circuit of claim 8 , wherein said respective switches each comprise a semiconductor device having drain-source voltage rating of at least a bus voltage for said supply bus plus a reverse breakdown voltage of said respective bipolar diodes. 15. A method of controlling a solenoid valve having a solenoid coil and a poppet configured to translate therein, said method comprising: supplying a voltage to the solenoid coil over a supply bus; coupling the solenoid coil to a ground path over a return bus to translate the poppet to an opened position; decoupling the solenoid coil from the ground path to translate the poppet to a closed position; directing a flyback current sourced from the solenoid coil through a flyback circuit coupled in parallel to only the solenoid coil, the flyback circuit comprising only a bipolar diode; charging a capacitor of a charge pump circuit using a coil current conducted through the solenoid coil; and momentarily changing a reference of the capacitor coupled in series with the solenoid coil to boost a voltage applied across the solenoid coil when the solenoid coil is decoupled from the ground path in order to accelerate a translation of the poppet to the closed position. 16. The method of claim 15 , wherein coupling and decoupling the solenoid coil comprises closing and opening a semiconductor device coupled between the solenoid coil and the ground path. 17. The method of claim 16 , wherein the semiconductor device has a drain-source voltage rating of at least a bus voltage for the supply bus plus a reverse breakdown voltage of the bipolar diode. 18. The method of claim 15 further comprising: momentarily changing the reference of the capacitor coupled in series with the solenoid coil to boost the voltage applied across the solenoid coil and accelerate a translation of the poppet to the opened position when the solenoid coil is coupled to the ground path.