Random Wire Aerial Info

I use a random wire a fair amount now with the ft817 and HFpacker amp.  Why?  simply put the random wire only requires one high point when putting up, the feed point is down at the ground and the LDG Z100 Pro with a 4:1 Balun or 1:1 Balun gives me all bands.

On our next outing, (which has been a long time, especially since we stopped in Cairns and then relocated to Brisbane) is to Fraser Island on 23 of July for a week.  I will be beaconing on HF APRS Mobile as Vk4KWI-15 and you can look me up on http://aprs.fi.  In the now much smaller 4WD I have installed a TS480SAT coupled to either a diamond mono bander for 20m, 30m or a Maldol HMC6-s.  As we travel generally the 20m and 30m aerials are installed and I switch between them using the TS480SAT's internal switch.

As for the random wire, I figure more wire in the air is better at camp and I get a choice of radios, so the hard decision is sit in the car or sit at the campfire.  Anyway here is the random wire info I use as copied from the writers web site and reproduced here.

"Random" Length -
Wire Antennas
WØIPL

---

Many people use what is referred to as a "random length" wire antenna for HF, quite effectively. The problem occurs when the wire ends up being a half wave multiple on one of the bands you would like to operate on. Odd number quarter wave lengths work very nicely. Even number quarter wave lengths (half wave multiple) do not.
With eight bands to contend with, how do you find a good "random length"? Well, what I did was to make a table of lengths that you should not use and then extrapolated out from there. Guess what? No longer random, is it?
Look at the table and you can easily see why a true random length will work beautifully on one band and not worth beans on another.
The formula that I used was 300/Freq[Mhz] = 1 wave length in meteres (spelled with the European trailing e to minimize confusion with meter - a measurement device, i.e. Ohm meter, etc.). Divide that in half to get 1/2 wave length. Thus 150/F[Mhz]. Take that number, multiply by 39.3701 to get inches in a metere, then divide by 12 to get feet. I used 39.37/12 = 3.2808 rounded to 3.28 to convert from meteres to feet.
Final formula is (150/F[Mhz]) * 3.28 = 1/2 wave length in feet. Then multiply by 1, 2, 3, etc. until you exceed my self imposed limit of 125 feet (maximum you can fit on most city lots). Lengths shown are rounded to the nearest one tenth of a foot.

"Center" of band

Frequencies (in Mhz) used for the calculations were: 28.6, 24.93, 21.225, 18.11, 14.175, 10.125, 7.150 and 3.928. Yes, I understand that it has its focus on 75M phone and ignores 80M CW, but it also exceeds 125 feet for 75M phone.

#1/2W	10	12	15	17	20	30	40	75
1	17.2	19.7	23.2	27.2	34.7	48.6	68.8	125.3
2	34.4	39.4	46.3	54.3	69.4	97.2
3	51.6	59.2	69.5	81.5	104.1
4	68.8	78.9	92.7	108.7
5	86.0	98.7	115.9
6	103.2	118.4
7	120.4

Most easily used lengths are: 63', 74', 89' and 111.5'. OR, not very random if you want all band coverage (center of band).

"Full" band

Frequencies (in Mhz) used for the calculations were: 28.0-29.7, 24.89-24.99, 21.0-21.45, 18.068-18.168, 14-14.35 10.1-10.15, 7-7.3 and 3.928.

#1/2W	10	12	15	17	20	30	40	75
1	16.6-17.6	19.7-19.8	22.9-23.4	27.0-27.2	34.3-35.1	48.5-48.7	67.4-70.3	125.3
2	33.1-35.1	39.4-39.5	45.8-46.8	54.2-54.5	68.6-70.3	96.9-97.4
3	49.7-52.7	59.0-59.3	68.8-70.3	81.2-81.7	102.8-105.4
4	66.3-70.3	78.7-79.0	91.7-93.7	108.3-108.9
5	82.8-87.8	98.4-98.8	114.7-117.1
6	99.4-105.4	118.1-118.6
7	115.9-123

Most easily used lengths are: 63', 74' and 111.5'. 89' is omitted because it would be within about one foot in length of two bands on either side of it.
If you want to cover all of every band with minimum loading problems (that does not imply it will be perfect - only that it should load) 74' is your winner.
Department of redundancy department - Not very random to be able to load all bands.
W0IPL