Technique for fully discharging a storage capacitor in a firing circuit for an electro-explosive device

That which is claimed is: 1. A firing circuit configured for complete discharge of a storage capacitor, said firing circuit comprising: the storage capacitor; an inductor receiving output of said storage capacitor; a diode; a transistor switch having a gate to which said inductor and said diode are connected in series said diode being disposed between said inductor and said transistor switch; said inductor and said capacitor being configured for inductor capacitor ringing, said inductive capacitive ringing creating upon initiation of said circuit a gate voltage at said gate above an initial capacitor voltage of said storage capacitor; and said diode blocking the discharge of said gate voltage ensuring that the capacitor is fully discharged; wherein a gate voltage of said first field effect transistor, upon triggering of said firing circuit swings to a negative value equal to a voltage of said storage capacitor less a forward voltage of said diode. 2. The firing circuit of claim 1 wherein said transistor switch disposed between said capacitor and a bridgewire. 3. The firing circuit of claim 1 wherein said transistor switch is a field effect transistor. 4. The firing circuit of claim 3 wherein said field effect transistor is an P-type field effect transistor. 5. The firing circuit of claim 1 where said capacitor is a gate to source capacitance of a field effect transistor. 6. The firing circuit of claim 1 wherein a gate to source voltage of said field effect transistor is the difference between twice a storage capacitor voltage and a diode forward voltage. 7. The firing circuit of claim 1 wherein during discharge, a gate to source voltage of said first field effect transistor remains constant. 8. A method for the complete discharge of a storage capacitor in a firing circuit, said method comprising: instantiating an inductive capacitive ringing in said firing circuit thereby creating a negative gate voltage of a field effect transistor equal to 2 times a voltage of said capacitor less a forward voltage of a diode; preventing the flow of current in an opposite direction and stops further ringing thereby maintain the peak field effect transistor (FET) gate to source voltage remains constant, and the FET remains in its low resistance state providing for complete storage capacitor discharge.