Antenna array with wide-band reactance cancellation

What is claimed is: 1. An antenna array comprising two or more radiating elements, with nearest neighbor radiating elements connected together with a non-Foster circuit between terminals of the radiating elements such that a mutual reactance between the nearest neighbor radiating elements is reduced over a wider bandwidth than which would be obtained if the non-Foster circuits were omitted, wherein the non-Foster circuit at terminals of the radiating elements is implemented as a series circuit of a negative capacitor and a negative resistor. 2. The antenna of claim 1 wherein the radiating elements are monopole type antennas. 3. The antenna of claim 1 wherein the radiating elements are dipole type antennas. 4. The antenna of claim 1 further comprising additional non-Foster circuits connected in series with each radiating element such that the self-reactance of each radiating element is cancelled over said wider bandwidth. 5. The antenna of claim 1 further including a decoupling network. 6. The antenna of claim 1 further including a beam-forming network. 7. The antenna of claim 1 wherein the non-Foster circuit at terminals of the radiating elements implement a negative capacitor. 8. The antenna of claim 1 wherein the non-Foster circuit at terminals of the radiating elements implemented a series circuit of a negative capacitor and a negative resistor. 9. The antenna of claim 1 wherein said two or more radiating elements comprise four or more radiating elements, wherein all nearest neighbor elements are all equally spaced relative to each other. 10. The antenna of claim 1 wherein said two or more radiating elements are arranged in an Adcock antenna array. 11. The antenna of claim 1 wherein said non-Foster circuit is connected between feed points of said radiating elements. 12. The antenna of claim 1 wherein said radiating elements are arranged in an Adcock array of radiating antenna elements. 13. The antenna of claim 1 wherein said non-Foster circuit realizes a negative capacitor wired in series with a negative resistor. 14. An antenna network for coupling a antenna array having two driven antenna elements with a sum-difference network having two outputs, the sum-difference network comprising three negative capacitors, first and second ones of the three negative capacitors each being coupled in series between one of the outputs of the sum-difference network and one of the two driven antenna elements, with the third one of the three negative capacitors being coupled between the two driven antenna elements. 15. The antenna network of claim 14 An antenna network for coupling an antenna array having two driven antenna elements to a sum-difference network having two outputs, the antenna network comprising three negative capacitors, first and second ones of the three negative capacitors each being coupled in series between one of the outputs of the sum-difference network and one of the two driven antenna elements, with the third one of the three negative capacitors being coupled between the two driven antenna elements, and further including a first negative resistor coupled in series with the third one of the three negative capacitors between the two driven antenna elements. 16. The antenna network of claim 15 further including second and third negative resistors each one of which is coupled in series with one of the first and second ones of the three negative capacitors coupled between one of the outputs of the sum-difference network and one of the two driven antenna elements. 17. A method of improving stability of the odd mode of an antenna system having one or more negative capacitors coupling neighboring driven elements to one another, the method comprising inserting a negative resistor in series with each of the negative capacitors coupling neighboring driven elements to one another. 18. The method of claim 17 where the negative resistor has a value which is sufficiently large in absolute value to assure that in a signal analysis that all zeros are in a left half of an s plane analysis thereof. 19. An antenna array comprising two or more antenna elements, with nearest neighbor antenna elements connected together at feed points of said antenna elements by a non-Foster circuit. 20. The antenna of claim 19 An antenna array comprising two or more antenna elements, with nearest neighbor antenna elements connected together at feed points of said antenna elements by a non-Foster circuit, wherein said non-Foster circuit realizes a negative capacitor wired in series with a negative resistor. 21. A method of reducing the self reactance of a plurality of antenna elements disposed in an array of parallel antenna elements, the parallel antenna elements each having an axis which is laterally spaced the axes of other antennas in said array, the method comprising: a. providing a plurality of first non-Foster circuits each connected in series between a transmitter and/or a receiver and a connection point of each antenna element disposed in said array, and b. providing a plurality of second non-Foster circuits connected between the connection points of neighboring antenna elements disposed in said array. 22. The method of claim 21 A method of reducing the self reactance of a plurality of antenna elements disposed in an array of parallel antenna elements, the parallel antenna elements each having an axis which is laterally spaced the axes of other antennas in said array, the method comprising: a. providing a plurality of first non-Foster circuits each connected in series between a transmitter and/or a receiver and a connection point of each antenna element disposed in said array, and b. providing a plurality of second non-Foster circuits connected between the connection points of neighboring antenna elements disposed in said array, wherein (i) said plurality of antenna elements comprise N antenna elements, (ii) the plurality of first non-Foster circuits comprise N first non-Foster circuits and (iii) the plurality of second non-Foster circuits comprise N second non-Foster circuits, and wherein the value of N is the same for the numbers of antenna elements, first non-Foster circuits and second non-Foster circuits. 23. The method of claim 22 wherein the first and second non-Foster circuit each realize a negative capacitor connected in series with a negative resistor. 24. In combination, an antenna array having two driven antenna elements, a sum-difference network having two outputs, and a network comprising three negative capacitors, first and second ones of the three negative capacitors each being coupled in series between one of the outputs of the sum-difference network and one of the two driven antenna elements, with the third one of the three negative capacitors being coupled between the two driven antenna elements and further including a first negative resistor coupled in series with the third one of the three negative capacitors between the two driven antenna elements. 25. The combination of claim 24 further including second and third negative resistors each one of which is coupled in series with one of the first and second ones of the three negative capacitors coupled between one of the outputs of the sum-difference network and one of the two driven antenna elements. 26. The antenna array of claim 20 wherein the antenna elements each comprise an antenna with a corresponding feed point and wherein the non-Foster circuits con