|-c||Calculate the maximum level of any sidelobe - not just the rear on as the FB ratio tells us. If the sidelobe and FB ratio are equal, it means the biggest sidelobe is the rear one. If the Sidelobe is less than the FB ratio, then another lobe is more significant. Look in the .gai file (see below) to see where it is. This option slows the program quite a bit.|
|-e||Suppress calculation of the 3dB E-plane bandwidth. This is sometimes necessary if the programme is unable to find the 3 dB beamwidth, to prevent an error occuring.|
|-h||Suppress calculation of the 3dB H-plane bandwidth. This is sometimes necessary if the programme is unable to find the 3 dB beamwidth, to prevent an error occuring.|
|-p||Put data into a file filename.freq for reading into gnuplot, and a commmand file filename.gc for gnuplot to use. (run output -p filename then gnuplot filename.gc )|
|-s||Suppress all diagnostic output. By default, the program print the percentage of the job completed.|
|-EE_max||When the program computes the E-plane 3dB beamwidth, it assumes the antenna pattern is 3dB down somewhere in the range 90 to Emax, where E_max is by default 179 degrees. This can fail if it is never 3dB down in the range, or if it happened to go 3dB down in two or more points. You can change E_max, if you need to, but rarely if every should need to. Ive never seen a failure here, but are guarding against one. If you dont want the pattern, use the -e option instead, which skips it. See also -H below.|
When the program computes the H-plane 3dB beamwidth, it assumes the antenna pattern is 3dB down somewhere in the range 0 to Hmax, where H_max is by defualt 60 degrees. This can fail if it is never 3dB down in the range, or if it happended to go 3dB down in two or more points. Also, if it goes more than 3dB down, but that starts to come up again. You can change H_max, if you need to, as
failures do occasionally occur. If you dont want the pattern use -h option instead, which will skip it.
An obvious example of an antenna where you cant find the 3dB bandwidth for the H-plane is the 1ele dipole. The radiation is symmetrical about its axis, so the level is the same everywhere in the H plane. The program automatically avoids calculating it for a 1 ele beam.
Zo is the characteristic impedance used when calculating the VSWR. By default its 50 Ohms, but can be changed to any real, positive value.
|is the name of the file containing the antenna description. It is expected to be in a format created by input or first - two other programs in the Yagi-Uda project. The is also expected to exist a binary file filename.out created by typing yagi filename|
Im not aware of any limitations, apart from that filenames, including full path, cant exceed 90 characters.
filename ASCII file with antenna description. filename.out Binary data file, created by yagi. filename.dat ASCII file with gain, FB ratio etc. filename.gai ASCII file with angular dependence of gain.
Both DOS and Unix versions have been built. The DOS version as distributed requires a 386 PC with a 387 maths coprocessor.
Bugs should be reported to firstname.lastname@example.org. Bugs tend actually to be fixed if they can be isolated, so it is in your interest to report them in such a way that they can be easily reproduced. The program gives errors if element lengths are well away from a half-wave (by a factor of ~3) due to a breakdown in the equations. If the input file is edited manually and done incorrectly, there can be unpredictable results.
|Version 1.16||OUTPUT (1)||24th October 2000|