Electronic ignition circuit

What is claimed is: 1. An electronic ignition circuit, comprising: a protection circuit comprising at least one of a fuse, a circuit breaker, and an automatic switch; an input circuit electrically coupled to the protection circuit, the input circuit comprising a bridge rectifier; a logic circuit electrically coupled to the input circuit, the logic circuit comprising: a microcontroller; and a switching circuit adapted to switch from a first detonator or igniter to a second detonator or igniter in response to a signal from the microcontroller, wherein the switching circuit includes a switch electrically coupled to the protection circuit at a first side of the switch and electrically coupled to the bridge rectifier at a second side of the switch; an ignition circuit electrically coupled to the logic circuit, the ignition circuit comprising a capacitor discharging circuit to discharge a firing capacitor through a fuse head; and an answer back circuit to transmit an indication of a result of a command or test in response to the microcontroller switching a resistor in the answer back circuit to increase a current flow. 2. The electronic ignition circuit of claim 1 , wherein the protection circuit comprises a fuse. 3. The electronic ignition circuit of claim 1 , wherein the protection circuit comprises a circuit breaker. 4. The electronic ignition circuit of claim 1 , wherein the protection circuit comprises at least one of a varistor at an input and a varistor at an output. 5. The electronic ignition circuit for controlling at least one detonator of claim 1 , wherein the protection circuit comprises at least one of a suppressor diode at an input and a suppressor diode at an output. 6. The electronic ignition circuit of claim 1 , further comprising: a firing transistor to discharge the firing switch through the fuse head, wherein the firing transistor remains active closed after the discharging the firing capacitor through the fuse head; and an arming switch, wherein the arming switch is active closed to charge the firing capacitor after receiving an arming code, and until it receives and reacts to a firing code. 7. The electronic ignition circuit of claim 6 , wherein the arming switch is active again after a time delay, wherein the time delay occurs after the discharge of the firing capacitor through the fuse head, to recharge the firing capacitor after ignition of the fuse head. 8. The electronic ignition circuit of claim 7 , further comprising a shot detection circuit configured to measure the voltage across the firing capacitor: before the discharging of the firing capacitor; after the discharging of the firing capacitor; and after the recharging of the firing capacitor. 9. The electronic ignition circuit of claim 1 , wherein at least three measured voltages are used to set a result variable representing one of a successful shot, and a failed shot. 10. The electronic ignition circuit of claim 1 , wherein the protection circuit comprises: at least one of one or more of a varistor and one or more of a suppressor diode, at an input; and a varistor and a suppressor diode, at an output. 11. The electronic ignition circuit of claim 1 , wherein the logic circuit comprises a supply voltage circuit configured to convert power to a voltage level acceptable to the logic circuit. 12. The electronic ignition circuit of claim 1 , wherein the ignition circuit comprises a voltage limiter for the firing capacitor. 13. An electronic ignition circuit for use with a fuse head, the electronic ignition circuit comprising: a microcontroller; a firing capacitor operably coupled to the fuse head; a voltage measuring circuit operably coupled to the microcontroller and configured to measure a voltage across the firing capacitor; and a switch operably coupled to the microcontroller, the switch being provided in series with the fuse head and a ground; wherein the microcontroller is configured to: control the voltage measuring circuit to measure a first voltage across the firing capacitor; actuate the switch to discharge the firing capacitor across the fuse head in response to a firing signal; control the voltage measuring circuit to measure a second voltage across the firing capacitor; and output a shot detection signal based on the first voltage and the second voltage. 14. The electronic ignition circuit of claim 13 , further comprising an answer back circuit operably coupled to the microcontroller, the answer back circuit comprising a resistor, wherein: the microcontroller is configured to transmit the shot detection signal to the answer back circuit; and the answer back circuit is configured such that a resistance of the resistor changes in response to the shot detection signal. 15. The electronic ignition circuit of claim 13 , wherein the microcontroller is further configured to: control the voltage measuring circuit to measure a third voltage across the firing capacitor in response to a predetermined time period passing after discharge of the firing capacitor; and output the shot detection signal based on the first voltage, the second voltage, and the third voltage. 16. The electronic ignition circuit of claim 13 , wherein the microcontroller is configured to determine that a shot occurred in response to the first voltage being within a first predetermined range and the second voltage being with a second predetermined range. 17. A method of activating a fuse head, the method comprising: providing an electronic ignition circuit comprising: a firing capacitor operably coupled to the fuse head; and a switch provided in series with the fuse head and a ground; measuring a first voltage across the firing capacitor; actuating the switch to discharge the firing capacitor across the fuse head; measuring a second voltage across the firing capacitor; and determining whether the fuse head was activated based on the first voltage and the second voltage. 18. The method of claim 17 , further comprising measuring a third voltage across the firing capacitor in response to a predetermined time period passing after discharge of the firing capacitor; wherein the determining whether the fuse head was activated comprises determining whether the fuse head was activated based on the first voltage, the second voltage, and the third voltage. 19. The method of claim 17 , wherein the determining whether the fuse head was activated comprises: determining whether the first voltage is within a first predetermined range; and determining whether the second voltage is within a second predetermined range.