Wide band embedded armor antenna using double parasitic elements

What is claimed is: 1. A wideband embedded armor antenna, comprising: an armor layer mounted to a vehicle having a conductive skin; a driven dipole in a first plane between said armor layer and said vehicle; a first parasitically driven dipole in a second plane on the outside of said armor layer; a second parasitically driven dipole in a third plane between said driven dipole and said vehicle, said second parasitically driven dipole spaced from said driven dipole capacitively coupling said driven dipole to said second parasitically driven dipole, said second parasitically driven dipole having two segments; a resistor between said two dipole segments, wherein said resistor and said capacitive coupling form an RC circuit that lowers the frequency of said antenna, whereby said RC circuit tunes out inductance that causes destructive interference and diminishes gain, such that said antenna can operate in close proximity to said skin without shorting out said antenna; a feed for said driven dipole which does not pierce said armor layer, whereby the antenna structure is embedded in the armor layer without altering the characteristics of said armor layer; and wherein a gain across a frequency band associated with said dipoles is at least −1 dBi. 2. The antenna of claim 1 , wherein the frequency band associated with said dipoles includes the UHF band. 3. The antenna of claim 2 , wherein said UHF band extends from 225 MHz to 450 MHz. 4. The antenna of claim 1 , wherein said second parasitically driven dipole is air gap spaced from said vehicle. 5. The antenna of claim 1 , and further including resistors between the elements of the dipoles. 6. The antenna of claim 1 , wherein said dipoles include bowtie shaped elements. 7. The antenna of claim 6 , wherein said bowtie shaped elements are in the form of triangularly-shaped elements. 8. The antenna of claim 1 , and further including a number of armor plates attached to the side of said vehicle, each of said armor plates including an embedded driven dipole antenna and an exterior parasitically-driven dipole antenna, along with an interior parasitically-driven dipole antenna and further including a phasing module for driving the antennas in said panels. 9. The antenna of claim 8 , wherein said phasing module drives the embedded antennas in said panels in-phase. 10. The antenna of claim 8 , wherein said phasing module phases the feeds for said embedded antennas so as to provide a steerable beam therefrom. 11. For use with an armored vehicle, a wideband embedded armor antenna, comprising: an armor layer mounted to au armored vehicle having a conductive skin; a driven dipole in one plane between said armor layer and said vehicle, said dipole operating in the UHF band; a first parasitically driven dipole in a second plane on the outside of said armor layer; a second parasitically driven dipole in a third plane between said driven dipole and said vehicle, said second parasitically driven dipole spaced from said driven dipole capacitively coupling said driven dipole to said second parasitically driven dipole, said second parasitically-driven dipole having two segments; a resistor between said two dipole segments, wherein said resistor and said capacitive coupling form an RC circuit that lowers the frequency of said antenna, whereby said RC circuit tunes out inductance that causes destructive interference and diminishes gain, such that said antenna can operate in close proximity to said skin without shorting out said antenna; and, a feed for said driven dipole which does not pierce said armor layer, whereby the antenna structure is embedded in the armor layer without altering the characteristics of said armor layer. 12. The antenna of claim 11 , wherein said UHF band extends from 225 MHz to 450 MHz. 13. A wideband embedded armor antenna, comprising: an armor layer mounted to an electrically conductive surface; a driven dipole in one plane between said armor layer and said electrically conductive surface; a parasitically driven dipole in a second plane between said driven dipole and the electrically conductive surface and spaced from the electrically conductive surface with an air gap, said second parasitically driven dipole spaced by said air gap from said driven dipole capacitively coupling said driven dipole to said second parasitically driven dipole, said second parasitically driven dipole having two segments; a resistor between said two dipole segments, wherein said resistor and said capacitive coupling form an RC circuit that lowers the frequency of said antenna, whereby said RC circuit tunes out inductance that causes destructive interference and diminishes gain, such that said antenna can operate in close proximity to said electrically conductive surface without shorting out said antenna; a feed for said driven dipole which does not pierce said armor layer; and wherein a gain across a frequency band associated with said dipoles is at least −1 dBi. 14. The antenna of claim 13 , and further including a resistor between the elements of said driven dipole. 15. A wideband embedded armor antenna, comprising: an armor layer mounted to an electrically conductive surface of an armored vehicle; a driven dipole in one plane between said armor layer and said vehicle; a first parasitically driven dipole in a second plane on the outside of said armor layer said dipole operating in the UHF band; a second parasitically driven dipole in a third plane between said driven dipole and the surface of said vehicle, said second parasitically driven dipole spaced from said driven dipole capacitively coupling said driven dipole to said second parasitically driven dipole, said second parasitically driven dipole having two segments and a resistor between said two dipole segments, wherein said resistor and said capacitive coupling form an RC circuit that lowers the frequency of said antenna, whereby said RC circuit tunes out inductance that causes destructive interference and diminishes gain, such that said antenna can operate in close proximity to said electrically conductive surface without shorting; and, a feed for said driven dipole which does not pierce said armor layer, said dipoles including bowtie shaped elements; and wherein a gain across a frequency band associated with said dipoles is at least −1 dBi. 16. The antenna of claim 15 , wherein said bowtie shaped elements are in the form of triangularly-shaped elements. 17. The antenna of claim 15 , and further including a resistor between the dipole segments of each of said dipoles. 18. The antenna of claim 17 , wherein the values of said resistors are 610 ohms for the driven dipole, 640 ohms for said first parasitically driven dipole, and 485 ohms for said second parasitically driven dipole. 19. The antenna of claim 15 , wherein the length of said driven dipole is 12.9 inches, the length of said first parasitically driven dipole is 8.2 inches and the length of said second parasitically driven dipole is IOM inches. 20. The antenna of claim 15 , wherein said second parasitically driven element is air gap spaced from the surface of said vehicle. 21. The antenna of claim 20 , wherein said air gap is between 2 and 2-¼ inches.