Wide band antenna

What is claimed is: 1. A method of manufacturing a travelling wave antenna element, comprising the steps of: selecting a desired operating frequency range and selecting a predetermined required performance characteristic of said antenna element, wherein said predetermined required performance characteristic comprises at least one of impedance bandwidth, directive gain, and efficiency; and forming an antenna component having an upper and lower conductive loop by: providing a first conductive loop element defined by an upper conductor and a first conductive blade member that tapers outwardly to form a flare portion adjacent a distal end of said upper conductor; providing a second conductive loop element defined by a base conductor and a second conductive blade member that tapers outwardly to form a flare portion adjacent a distal end of said base conductor; placing said first and second conductive loop elements adjacent to each other such that outer edges of the first and second conductive blade members face each other to define a notch therebetween which opens outwardly from a feed region; providing an elongate vane between a first location on said upper conductor and a second location on said first conductive blade to define a pair of loops within said first conductive loop element; wherein selecting the second location is a function of the length of the upper conductor, and wherein the second location on the first blade member is at least ⅙ of the length of the upper conductor; and matching an impedance of said antenna component, at said desired operating frequency range, to a transmission line to be connected at said feed region thereof; wherein said step of providing said elongate conductive vane comprises: selecting a minimum distance of said second location from said feed region at which said impedance match is maintained and said performance characteristic is attained, and placing said conductive vane within said first conductive loop element such that it extends from said selected second location on said first conductive blade to a first location on said upper conductor; and/or selecting an angle of inclination of said conductive vane within said first conductive loop at which said performance characteristic is attained, and placing said conductive vane at said selected angle of inclination between said first location on said upper conductor and said second location on said first conductive blade. 2. The method according to claim 1 , wherein the distance of the second location from the feed region is between ⅙ and ⅘ of the length of the upper conductor. 3. The method according to claim 1 , wherein the conductive vane is inclined outwardly, away from the feed region, such that the distance of the first location from the proximal end of the upper conductor is greater than that of the second location from the feed region. 4. The method according to claim 1 , wherein the conductive vane is curved along at least a portion of its length. 5. The method according to claim 1 , comprising the step of selecting the distance of the first location from the proximal end of the upper conductor as a function of the length of the upper conductor and in accordance with the selected second location. 6. The method according to claim 5 , wherein, when the distance of the second location from the feed region is ⅙ of the length of the upper conductor, the distance of the first location from the proximal end of the upper conductor is ⅕ or ¼ of the length of the upper conductor. 7. The method according to claim 5 , wherein the first location is between ⅕ and ⅚ along the length of the upper conductor from its proximal end. 8. The method according to claim 1 , comprising the step of selecting the length of the upper conductor and/or the base conductor according to a selected desired cut-off frequency of the antenna element. 9. The method according to claim 8 , comprising the steps of selecting a cut-off frequency of the antenna element, and selecting the peripheral dimensions of the upper loop such that, combined, they are substantially equal to a wavelength corresponding to the selected cut-off frequency. 10. An antenna element manufactured substantially in accordance with the method of claim 1 , and comprising an upper loop and a lower loop, said upper loop comprising a first conductive loop element defined by an upper conductor and a first conductive blade member that tapers outwardly to form a flare portion adjacent a distal end of said upper conductor, said lower loop comprising a second conductive loop element defined by a base conductor and a second conductive blade member that tapers outwardly to form a flare portion adjacent a distal end of said base conductor, said first and second conductive blade members defining, between their facing edges, a notch which opens outwardly from a feed region, said upper loop further comprising an elongate conductive vane extending at an angle from a first location on said upper conductor to a second location on said first conductive blade to define a pair of loops within said upper loop, wherein an impedance of said antenna element substantially matches, at said desired operating frequency range, an impedance of a transmission line to be connected at said feed region thereof; and: said conductive vane is located within said upper loop such that it extends from a selected second location on said first conductive blade to a first location on said upper conductor, said selected second location corresponding to a minimum distance from said feed region at which said impedance match is maintained; and/or said conductive vane is located at a selected angle of inclination between said first location on said upper conductor and said second location on said first conductive blade to attain a selected desired characteristic of said antenna element. 11. The wide band antenna comprising an array of antenna elements according to claim 10 .