The Boonton meter is a great tool, and now reasonably priced for
amateurs on the used test equipment market. You did need the manual to
operate it, until you were very familiar with its several adjustments.
The Hewlett Packard vector impedance meters were easier to use. One
manin tuning knob. The 4800 covered low frequencies up to 500 kHz, and
the model 4815 went from 500 kHz to 110 MHz. This was in 1964, so UHF
was not as much of a concern as later. As I recall the two instruments,
which were daily use tools for me for awhile, they covered from a few
ohms to thousands of ohms resistance. I don't recall anything we could
not measure in our RFI work. Applications were for both series tuned
and parallel tuned high Q circuits, as well as room resonances on
shielded chambers of 30 feet by 15 feet in size. You just had to be
careful with the HP product as its probe had a FET in it. That may have
only been on the 4815. The 4800 had binding post inputs as I recall.
It has been many years.
-Stuart Rohre
K5KVH
Dr. Gerald N. Johnson wrote:
On Thu, 2008-05-08 at 15:17 -0700, Stuart Rohre wrote:
Incidental to L. B. Cebik's modeling of antennas of the end fed so
called Zepp type, (a dipole), he spoke on current balance and its effects.
Summary:
Although the traditional Zepp feeder was a balanced line, and in the
Zepp end fed, one wire does not connect to anything, with the other wire
to the end of the antenna, Cebik found this only caused a 10 per cent
difference in the line current in the two conductors when modeled.
The fact is that the unconnected wire still has stray capacitance to
space and the other wire. That causes a small current at the high
impedance end of the feed line, at the antenna. And the end impedance of
the half wave radiator is high enough its current is small so even at
the open end of the feed line the currents aren't wildly different and
so when transformed by a quarter wave the currents aren't badly out of
balance.
As a practical matter, you can use on a regular dipole center feed, the
cable choke to block current from the outside of the coax shield, as
long as the shield is being led off at right angles, and its effect is
to confine the currents to the inside shield and the center conductor
and in balance, (equal and opposite). This would force equal currents
into the dipole legs, if each is independent of other coupling such as
nearby conductors, trees, buildings, etc.
Folks usually use one type of coupling or another. A wound balun to
transform from balanced dipole center feed to coax, or a bead "balun" of
isolating ferrite beads to block outside the shield currents, or a cable
choke of coiled solenoidal coax to again block the outside the shield
current. Only one of these is needed or desirable, as the mechanically
loading on the antenna must be considered so as to not cause unfavorable
wire stress in winds.
The wound wire balun coils may have a different number of bands covered
than the bead choke. And depending on how you wind the cable choke, it
may cover fewer bands than exist from 2 to 30 MHz. You often found
those broken into cable chokes effective at 80 to 40m, (maybe 30m); and
others for 20m and up.
A lot of individual home built isolation devices in the above classes
have been built over the years. The problem is that there is no
comprehensive table of bands covered, losses, efficiency, power handling
for all types homebuilt and commercial except for what Jerry Sevick has
covered in his books as a result of experiments a number of years ago.
His work was done with some self built instrumentation, as Antenna
Analyzers were not widely available at that time. To his credit, in the
back of his first book, he included details on the measuring
instruments, and they were good basic instrumentation. He described how
he measured or estimated efficiency, measured balance, etc.
Its not hard to check the isolation properties of the current balun or
choke with a Boonton RX-meter that measures parallel R and C with an R
range from a few ohms to an open circuit and a C range from -10 or 20 pf
to 120 pf or something like with a frequency range from 500 KHz to 250
MHz. A vector impedance meter may work but I don't think it has as wide
a resistance range. I know the basic tool used by Collins transmitter
designers when developing PA plate feed chokes was that RX-meter and the
one I have is handy for such measurements though its not instant
reading.
Some additional information may be gleaned from the intensive work Frank
Witt did on tuners, which were mostly commercial tuners as I recall, but
most of those have a built in balun of the core type.
Since I've run into problems tuning the balun instead of the antenna and
know excess voltage on the balun will lead to core saturation, I much
prefer a balun on the input of the floating or balanced tuner or a
totally air cored link coupled tuner for balanced lines. I've built them
for 160 m through 70 cm, though some cover several bands.
-Stuart
K5KVH
73, Jerry, K0CQ
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