Dual polarized electronically steerable parasitic antenna radiator (ESPAR)

What is claimed is: 1. A method comprising: setting a first terminating impedance of a first parasitic patch element of an antenna to set a first direction of a first beam without substantially affecting a second direction of a second beam, the first parasitic patch element separated from and parasitically coupled to a driven patch element of the antenna; setting a second terminating impedance of the first parasitic patch element to set the second direction of the second beam without substantially affecting the first direction of the first beam, the first beam and the second beam provided by the driven patch element electromagnetically interacting with the first parasitic patch element; and transmitting the first beam and the second beam from the antenna, the first beam having a first polarization and the second beam having a second polarization. 2. The method of claim 1 , further comprising: setting a third terminating impedance of a second parasitic patch element of the antenna, while setting the first terminating impedance of the first parasitic patch element, to further set the first direction of the first beam without substantially affecting the second direction of the second beam, the second parasitic patch element separated from and parasitically coupled to the driven patch element; and setting a fourth terminating impedance of the second parasitic patch element, while setting the second terminating impedance of the first parasitic patch element, to further set the second direction of the second beam without substantially affecting the first direction of the first beam. 3. The method of claim 2 , further comprising: setting a fifth terminating impedance of a third parasitic patch element of the antenna, while setting the first terminating impedance of the first parasitic patch element, to further set the first direction of the first beam without substantially affecting the second direction of the second beam, the third parasitic patch element separated from and parasitically coupled to the driven patch element; setting a sixth terminating impedance of the third parasitic patch element, while setting the second terminating impedance of the first parasitic patch element, to further set the second direction of the second beam without substantially affecting the first direction of the first beam; setting a seventh terminating impedance of a fourth parasitic patch element of the antenna, while setting the first terminating impedance of the first parasitic patch element, to further set the first direction of the first beam without substantially affecting the second direction of the second beam, the fourth parasitic patch element separated from and parasitically coupled to the driven patch element; and setting an eighth terminating impedance of the fourth parasitic patch element, while setting the second terminating impedance of the first parasitic patch element, to further set the second direction of the second beam without substantially affecting the first direction of the first beam. 4. The method of claim 1 , further comprising using a look up table of radiation patterns to set values for the first and second terminating impedances. 5. The method of claim 1 , wherein: setting the first terminating impedance comprises adjusting a first bias voltage of a first varactor; and setting the second terminating impedance comprises adjusting a second bias voltage of a second varactor. 6. The method of claim 1 , wherein the first polarization and the second polarization are orthogonal. 7. The method of claim 1 , further comprising controlling the first and second terminating impedances with first and second tuning elements, respectively, comprising any one of varactors, PIN diodes or micro-electromechanical systems (MEMS). 8. The method of claim 7 , further comprising: differentially coupling the first parasitic patch element to the first tuning element using first capacitive patches or a first aperture coupling, and differentially coupling the first parasitic patch element to the second tuning element using second capacitive patches or a second aperture coupling. 9. The method of claim 1 , further comprising: receiving a first signal at a first port for transmission by the first beam, the driven patch element being differentially coupled to the first port; and receiving a second signal at a second port for transmission by the second beam, the driven patch element being differentially coupled to the second port. 10. The method of claim 9 , further comprising: differentially coupling the driven patch element to the first port using a first passive circuit having first arms of differing lengths or using a first active electronic circuit generating opposite phase signals, and differentially coupling the driven patch element to the second port using a second passive circuit having second arms of differing lengths or using a second active electronic circuit generating opposite phase signals. 11. The method of claim 9 , further comprising: differentially coupling the driven patch element to the first port using a first pair of capacitive patches or a first aperture; and differentially coupling the driven patch element to the second port using a second pair of capacitive patches or a second aperture. 12. A method comprising: setting a first terminating impedance of a first parasitic patch element of an antenna to set a first direction of a first beam without substantially affecting a second direction of a second beam, the first parasitic patch element separated from and parasitically coupled to a driven patch element of the antenna; setting a second terminating impedance of the first parasitic patch element to set the second direction of the second beam without substantially affecting the first direction of the first beam, the first beam and the second beam provided by the driven patch element electromagnetically interacting with the first parasitic patch element; and receiving the first beam and the second beam by the antenna, the first beam having a first polarization and the second beam having a second polarization. 13. The method of claim 12 , further comprising: setting a third terminating impedance of a second parasitic patch element of the antenna, while setting the first terminating impedance of the first parasitic patch element, to further set the first direction of the first beam without substantially affecting the second direction of the second beam, the second parasitic patch element separated from and parasitically coupled to the driven patch element; and setting a fourth terminating impedance of the second parasitic patch element, while setting the second terminating impedance of the first parasitic patch element, to further set the second direction of the second beam without substantially affecting the first direction of the first beam. 14. The method of claim 13 , further comprising: setting a fifth terminating impedance of a third parasitic patch element of the antenna, while setting the first terminating impedance of the first parasitic patch element, to further set the first direction of the first beam without substantially affecting the second direction of the second beam, the third parasitic patch element separated from and parasitically coupled to the driven patch element; setting a sixth terminating impedance of the third parasitic patch element, while setting the second terminating impedance of the first parasitic patch element, to further set the second direction of the second beam without substantially affecting the first direction of the first beam; setting a seventh terminating impedance of a