Microwave-initiated antenna igniters with bandwidth selectivity

The invention claimed is: 1 . A tunable microwave-initiated antenna igniter comprising: a pair of tunable microstrip antennas configured to receive an electromagnetic radiation frequency that provides ignition energy; and a conductive material spanning a gap between said pair of tunable microstrip antennas. 2 . The device of claim 1 , wherein said pair of tunable microstrip antennas are disposed on a substrate. 3 . The device of claim 2 , wherein said substrate is a printed circuit board. 4 . The device of claim 2 , wherein said substrate is an FR4 printed circuit board. 5 . The device of claim 1 , wherein said pair of tunable microstrip antennas comprises half wavelength aluminum microstrip dipole antennas. 6 . The device of claim 1 , wherein said half wavelength aluminum microstrip dipole antennas are rounded microstrip dipole antennas. 7 . The device of claim 1 , wherein said half wavelength aluminum microstrip dipole antennas are rectangular microstrip dipole antennas. 8 . The device of claim 1 , wherein said pair of tunable microstrip antennas are tunable for frequency and bandwidth. 9 . The device of claim 1 , wherein dipole resonant frequency of said pair of tunable microstrip antennas is tuned by varying dipole length. 10 . The device of claim 1 , wherein dipole resonant frequency and bandwidth of said pair of tunable microstrip antennas is tuned by varying dipole width. 11 . The device of claim 1 , wherein said pair of tunable microstrip antennas are tunable to reject off-frequency high-power fields that may produce accidental ignitions. 12 . The device of claim 1 , wherein said gap is a dielectric gap. 13 . The device of claim 1 , wherein said conductive material spanning said gap is a bead of thermite epoxy. 14 . The device of claim 13 , wherein said thermite epoxy comprises dielectric epoxy and nanothermite. 15 . The device of claim 13 , wherein said thermite epoxy comprises 70 wt. % to 90 wt. % dielectric epoxy and 10 wt. % to 30 wt. % nanothermite. 16 . The device of claim 1 , wherein said conductive material spanning said gap is a bridgewire. 17 . The device of claim 16 , wherein said bridgewire is selected from the group consisting of 304 stainless steel, copper, molybdenum, nickel chromium 60, tantalum, and tungsten. 18 . The device of claim 16 , wherein said bridgewire spans said gap by soldering. 19 . The device of claim 16 , wherein said bridgewire is copper plated prior to soldering. 20 . The device of claim 16 , wherein said bridgewire spans said gap by joining using conductive epoxy. 21 . The device of claim 1 , wherein said bridgewire spanning said gap is graphite. 22 . A tunable microwave-initiated antenna igniter comprising: a pair of tunable microstrip antennas disposed on a substrate and configured to receive an electromagnetic radiation frequency that provides ignition energy; and a conductive material spanning a dielectric gap between said pair of tunable microstrip antennas; wherein tuning a dipole length and/or width of said tunable microstrip antennas tunes a dipole resonant frequency and/or bandwidth to reject off-frequency high-power fields to prevent accidental ignitions. 23 . The device of claim 22 , wherein said substrate is a printed circuit board. 24 . The device of claim 22 , wherein said substrate is an FR4 printed circuit board. 25 . The device of claim 22 , wherein said pair of tunable microstrip antennas comprises half wavelength aluminum microstrip dipole antennas. 26 . The device of claim 22 , wherein said half wavelength aluminum microstrip dipole antennas are rounded microstrip dipole antennas. 27 . The device of claim 22 , wherein said half wavelength aluminum microstrip dipole antennas are rectangular microstrip dipole antennas. 28 . The device of claim 22 , wherein said conductive material spanning said gap is a bead of thermite epoxy. 29 . The device of claim 28 , wherein said thermite epoxy comprises dielectric epoxy and nanothermite. 30 . The device of claim 28 , wherein said thermite epoxy comprises 70 wt. % to 90 wt. % dielectric epoxy and 10 wt. % to 30 wt. % nanothermite. 31 . The device of claim 22 , wherein said conductive material spanning said gap is a bridgewire. 32 . The device of claim 31 , wherein said bridgewire is selected from the group consisting of 304 stainless steel, copper, molybdenum, nickel chromium 60, tantalum, and tungsten. 33 . The device of claim 31 , wherein said bridgewire spans said gap by soldering. 34 . The device of claim 31 , wherein said bridgewire is copper plated prior to soldering. 35 . The device of claim 31 , wherein said bridgewire spans said gap by joining using conductive epoxy. 36 . The device of claim 22 , wherein said bridgewire spanning said gap is graphite.