Telecommunications JBCardenas © 1982 Com3 1Q1516 Antenna Design JBC © 198 v A2,2 Key design requirements 1.Provide the theoretical computations of shapes and geometries with matching and clear illustrations 2.Provide the wire geometries input to NEC for all configurations 3.You may have to configure curves with short sections of linear wire, compute the metric diameter of the 10AWG wire 4.A linear wire section should have at least 3 segments 5.Package report concisely, e.g. side by side comparisons of 3D and 2D plots, with 3 D antenna geometry, indicate gain and beamwidth for each pattern 6.In addition to the profiles, make sure to include the wire diagrams and orient all diagrams so that it is clearly perceived by the reader, if necessary use more than one illustration for a particular configuration 7.Simulation is easy, the difficult part is the math of steps 1 and 2. Remember garbage in garbage out. 8.Hard copy final report, short discussion of theoretical computations, optimization results, final result and comparative analysis 9.Soft copy to include all input data for the simulator, a user guide (notepad) if it will fit CD, an installation package. 10.X-axis propagation axis, Y-axis horizontal parallel to dipole elements, center signal source.
Telecommunications JBCardenas © 1982 Com3 1Q1516 Antenna Design JBC © 198 v A2,2 Design objective: Design an antenna for 476 MHz with one driven dipole element, a parasitic reflector and a dipole director 0.01 wavelength from driven element. Optimize design (gain) by varying the 0.01 distance. Use AWG8 solid bare copper wire as wire element. Provide 2D 3D radiation pattern, gain, beamwidth Sensitivity analysis: when optimum is found Use a reflector comprised of wire elements Use a reflector comprised of sheet metal Check performance at +/- 10%, 20% of 476 MHz Comparative analysis: vs a beam antenna comprised of one dipole reflector parasitic and one dipole director parasitic both 0.01 wavelengths away from driven element
Telecommunications JBCardenas © Q1516 model 1 JBC © 198 v A2,2 Driven dipole for 476 MHz at the focus of a parabolic reflector Parabolic reflector is a section of a cylindrical parabola, at least 5 parabolic elements; at least 5 linear elements to comprise the mesh. The diameter of the mouth of the parabola and the length of the cylinder > than length of driven dipole The driven dipole should be in the plane of the mouth of the reflector (or inside) Try to make the focal length as near as 0.01 wavelength as possible Provide a parasitic director 0.01 wavelengths away from driven element Optimization: vary the 0.01 director distance to get best gain
Telecommunications JBCardenas © Q1516 model 2 JBC © 198 v A2,2 Driven dipole for 476 MHz at the focus of a parabolic reflector Parabolic reflector is a section of a full parabola, comprised of at least 3 parabolic wire elements, and 3 circular (or hexagonal) wire elements. The diameter of the mouth of the parabola > length of driven dipole The driven dipole should be in the plane of the mouth of the reflector (or inside) Try to make the focal length as near as 0.01 wavelengths as possible Provide a parasitic director 0.01 wavelengths away from driven element Optimization: vary the 0.01 director distance (small increments) to get best gain
Telecommunications JBCardenas © Q1516 model 3 JBC © 198 v A2,2 Driven dipole for 476 MHz 0.01 wavelength from center of corner reflector Corner reflector comprised of at least 15 linear wire elements to comprise the mesh (or 5 V elements) The width and height of the mouth of the reflector > length of driven dipole The driven dipole should be in the plane of the mouth of the reflector (or inside) Provide a parasitic director 0.01 wavelengths away from driven element Optimization 1: vary the angle of the reflector to get best gain start at 90 degrees, then +/- a few degrees. Optimization 2: Once optimization 1 is attained, vary the 0.01 director distance to get best gain