Methods and apparatus for enhanced radiation characteristics from antennas and related components

What is claimed is: 1. An aperture engine array having a plurality of aperture engine panels, wherein each panel comprises: an antenna layer having at least one antenna array, each array configured to receive and/or transmit radio frequency (RF) energy over a range of frequencies, wherein each array comprises fractal resonators configured to allow incident radiation to pass through to an adjacent layer; a backplane layer, at least a portion of which contains a metal surface that acts as a reflective backplane for the at least one antenna array while allowing incident RF radiation pass to an adjacent layer; and a solar cell layer including a panel of solar cells configured to absorb incident radiation and providing power thus provide a power source for the transmission and reception of the RF energy. 2. The aperture engine array of claim 1 , wherein the aperture engine array, wherein each of the plurality of aperture engine panels is configurable in multiple positions for optimum reception and/or transmission in a particular direction or directions. 3. The aperture engine array of claim 1 , wherein the plurality of aperture engine panels is configured as a surface, larger than an individual panel, for greater gathering of incident radiation and greater antenna gain. 4. The aperture engine array of claim 2 , wherein the array is part of a satellite or spacecraft. 5. The aperture engine array of claim 3 , wherein the aperture engine array is attached to a satellite or spacecraft. 6. The aperture engine array of claim 1 , wherein a transmitting apparatus is attached to the aperture engine array and is powered by power derived from the solar cells of the lowest layers of the aperture engine array panels. 7. The aperture engine array of claim 1 , wherein a receiving apparatus is attached to the aperture engine array and is powered by the collected power derived from the solar cells of the lowest layer. 8. The aperture engine array of claim 3 , wherein the plurality of aperture engine panels is placed in a remote environment and controlled by remote means. 9. The aperture engine array of claim 1 , wherein the aperture engine array is utilized for radar transmissions and reception. 10. The aperture engine array of claim 3 , wherein the aperture engine array is utilized for radar transmissions and reception. 11. The aperture engine array of claim 4 , wherein the aperture engine array is utilized for radar transmissions and reception. 12. The aperture engine array of claim 5 , wherein the aperture engine array is utilized for radar transmissions and reception. 13. The aperture engine array of claim 6 , wherein the aperture engine array is utilized for radar transmissions and reception. 14. The aperture engine array of claim 6 , wherein the aperture engine array is utilized for transmissions and reception. 15. The aperture engine array of claim 8 , wherein the aperture engine array is utilized for radar transmission and reception. 16. An aperture engine panel comprising: an antenna layer having at least one antenna array, each array configured to receive and/or transmit radio frequency (RF) energy over a range of frequencies, wherein each array comprises fractal resonators configured to allow incident radiation to pass through to an adjacent layer; a backplane layer, at least a portion of which contains a metal surface that acts as a reflective backplane for the at least one antenna array while allowing incident RF radiation pass to an adjacent layer; and a solar cell layer including a panel of solar cells configured to absorb incident radiation and providing power thus provide a power source for the transmission and reception of the RF energy.