RF attenuating switch

What is claimed is: 1. A radio frequency (RF) attenuating switch, comprising: a first input lead configured to receive electrical power from a controller; a second input lead configured to couple to the controller; a first output lead configured to operatively supply the electrical power to a detonator; a second output lead configured to couple to the detonator; a switch configured to selectively couple the first input lead and the first output lead such that the switch operatively supplies the electrical power to the detonator via the first output lead when the switch is in a closed state; and a RF mitigation device electrically connected between the switch and the first output lead such that the electrical power is operatively supplied to the detonator through the RF mitigation device. 2. The RF attenuating switch of claim 1 , wherein the RF mitigation device is a spark gap. 3. The RF attenuating switch of claim 1 , wherein the RF mitigation device is a capacitor. 4. The RF attenuating switch of claim 1 , wherein the RF mitigation device is an RF choke. 5. The RF attenuating switch of claim 1 , wherein the RF mitigation device comprises one or more of a spark gap, a capacitor, an RF choke, or shielding. 6. The RF attenuating switch of claim 1 , further comprising a second RF mitigation device connected between the second input lead and the second output lead. 7. The RF attenuating switch of claim 6 , wherein the RF mitigation device and the second RF mitigation device each comprise one or more capacitors, one or more RF chokes, one or more spark gaps, or any combination thereof. 8. The RF attenuating switch of claim 6 , wherein the RF mitigation device and the second RF mitigation device comprise RF chokes. 9. The RF attenuating switch of claim 6 , wherein the RF mitigation device and the second RF mitigation device each comprise a spark gap and an RF choke. 10. An explosive assembly, comprising: a detonator; a radio frequency (RF) attenuating switch comprising: a first input lead configured to receive electrical power; a second input lead; a first output lead connected to the detonator; a second output lead connected to the detonator; a switch configured to selectively couple the first input lead and the first output lead such that the switch operatively supplies the electrical power to the detonator via the first output lead when the switch is in a closed state; and an RF mitigation device electrically connected between the switch and the first output lead such that the electrical power is operatively supplied to the detonator through the RF mitigation device; and a controller configured to control the switch and selectively the electrical power to the first input lead, wherein the controller is connected through the first input lead to the detonator such that, when the switch is in the closed state, the controller, the first input lead, the switch, the RF mitigation device, the first output lead, and the detonator are connected in series. 11. The explosive assembly of claim 10 , wherein the RF attenuating switch comprises a second RF mitigation device connected between the first input lead and the switch. 12. The explosive assembly of claim 11 , wherein the RF attenuating switch comprises a third RF mitigation device connected between the second input lead and the second output lead. 13. The explosive assembly of claim 10 , wherein the detonator is directly connected to the RF mitigation device and configured to, in response to receiving the electrical power via the RF mitigation device, detonate a first plurality of explosive charges operatively coupled to the detonator. 14. The explosive assembly of claim 10 , wherein the RF mitigation device comprises a spark gap or an RF choke. 15. The explosive assembly of claim 10 , further comprising a resistor connected in parallel with the RF mitigation device. 16. The explosive assembly of claim 15 , further comprising a printed circuit board (PCB), wherein the switch, the RF mitigation device, and the resistor are disposed on the PCB. 17. A method, comprising: deploying a perforating gun into a wellbore, the perforating gun comprising a firing head electrically connecting an electrical power source through a first radio frequency (RF) attenuating switch to a first detonator connected to a first plurality of explosive charges and electrically connecting a second RF attenuating switch to a second detonator connected to a second plurality of explosive charges, wherein the first RF attenuating switch comprises: a first input lead configured to receive electrical power from the electrical power source; a second input lead; a first output lead connected to the first detonator; a second output lead connected to the first detonator; a switch configured to selectively couple the first input lead and the first output lead such that the switch operatively supplies the electrical power to the first detonator via the first output lead when the switch is in a closed state; and an RF mitigation device electrically connected between the switch and the first output lead such that the electrical power is operatively supplied to the first detonator through the RF mitigation device; and detonating the first plurality of explosive charges in response to closing the switch thereby supplying the electrical power to the first detonator. 18. The method of claim 17 , wherein the RF mitigation device and the switch are disposed on a printed circuit board (PCB). 19. The method of claim 17 , wherein the RF mitigation device comprises one or more of a spark gap, a capacitor, an RF choke or shielding. 20. The method of claim 17 , wherein the first RF attenuating switch comprises a second RF mitigation device connected between the first input lead and the switch.