Good morning,

This question is: Taking measurements at the antenna and what they mean?

The antenna is a loaded vertical over a set of untuned radials. The feed is 50
Ohm coax with a 1:1 isolation transformer at the antenna. I intend to run a
separate coax for measurement purposes to the feed point, stimulate the antenna
with a 10 mw signal at the operating frequency, and measure the voltage across
the antenna feed and the ground connection.

Will the voltages indicate the relative RF impedance of antenna (including
loading coil) versus the ground? If the ground were near perfect the voltage at
the feedpoint should be close to zero. These voltages should indicate the power
disapation difference between the antenna and the ground.

Thanks,
Dan

In article , dansawyeror
wrote:

Good morning,

This question is: Taking measurements at the antenna and what they mean?

The antenna is a loaded vertical over a set of untuned radials. The feed
is 50
Ohm coax with a 1:1 isolation transformer at the antenna. I intend to run a
separate coax for measurement purposes to the feed point, stimulate the
antenna
with a 10 mw signal at the operating frequency, and measure the voltage
across
the antenna feed and the ground connection.

Will the voltages indicate the relative RF impedance of antenna (including
loading coil) versus the ground? If the ground were near perfect the
voltage at
the feedpoint should be close to zero. These voltages should indicate
the power
disapation difference between the antenna and the ground.

Thanks,
Dan

Hello, Dan. If we have a quarter wavelength monopole the voltage at the
feedpoint is at a minimum but definitely not zero even if we had a
perfectly electrically conducting (PEC) ground. If we had a PEC ground
and a monopole with no resistive (ohmic) losses then the impedance seen at
the feedpoint at resonance would be about 37 ohms resistive. The 37 ohms
is the radiation resistance of the antenna. This is where the RF power
gets "dissipated" when that power is radiated into free space.

If we use an electrically short antenna and put in say, a loading coil at
the feedpoint to resonate the monopole at the desired frequency, we are
looking at a radiation resistance of less than 37 ohms. It could be quite
small depending on how short the antenna is. If in addition we have
finite losses in the monopole structure, loading coil and in the
ground/radials, we are measuring a resistance that is the sum of all ohmic
losses and radiation resistance. And that's a classic problem - how to
separate out all these losses. Without making radiation pattern
measurements (to obtain total power radiated) about all you can do is
calculate the radiation resistance for a PEC monopole fed against a PEC
ground (or use an electromagnetics computation program like NEC to model
the structure.). The measured value less the calculated radiation
resistance would reflect the ohmic losses. And you still don't know how
much of this is ground loss without knowledge of the other ohmic losses.

There exits another direct measurement technique (Wheeler Cap) for
determing antenna efficiency that can be readily applied to antennas in
the GHz range but is not practical at HF because of the scaling factor
(compare the size of 2.4 GHz yagi or log-periodic with the same type at 14
MHz to put things in perspective). Sincerely,

John Wood (Code 5550) e-mail:
Naval Research Laboratory
4555 Overlook Avenue, SW
Washington, DC 20375-5337

............some "seat-of-the-pants" observations (to use an old aviator expression):
To judge the performances of two similar-sized mobile installations, note the value
of the shunt-C required across the feed-coax to provide good SWR 50 ohm match (or
shunt-L if that option is used).
The more C required (less capacitive reactance), the better [or similarly, the
less L (less inductive reactance), the better].
This method of match is actually a version of the classic "L-match" where the
mobile whip with its loading coil represents either R in series with Inductance, OR
R in series with Capacitance at the feedpoint....depending on whether the loading
coil is tuned slightly Below, or Above the resonant frequency. The shunt C (or L) is
the third element in the L-Match Equation. (Many readers will already know this)
Since standard antenna equations calculate the actual radiation resistance to be
very small in electrically- short mobile antennas, we know that with a perfect
ground, and zero-loss mast and coil, the feed-point resistance would be only the
radiation resistance of a few ohms, perhaps 2 to 5 (W8JI's web page calculates a
15 ft. antenna on 1.8 MHz to be only 1.22 ohms).
Therefore, if the mobile feedpoint was found to have low SWR 50 ohm match with
no shunt element, that would be very bad news........it would mean that perhaps 2
parts out of 50 were radiated, and the other 48 parts were loss! And of course,
here no shunt C (or L) would be required which is the worst news.
Conversely, back to "seat-of-the-pants thinking", the more C (or smaller L)
required, the smaller the feed-point impedance had to have been....meaning less
loss resistance included at the feedpoint.

On Thu, 08 Jun 2006 07:03:05 -0700, dansawyeror
wrote:

Ohm coax with a 1:1 isolation transformer at the antenna. I intend to run a
separate coax for measurement purposes to the feed point, stimulate the antenna
with a 10 mw signal at the operating frequency, and measure the voltage across
the antenna feed and the ground connection.

You seem to be implying more than one measurement, and that with those
measurements you can separately determine (radiation resistance + loss
resistance in the vertical and coil) and loss resistance in the ground
system.

Can you elaborate?

Perhaps a block diagram of your measurement setup might reveal what
you are thinking. (If you need a tool for drawing schematics in ascii
text, Google for AACircuit. Alternatively, sketch it, scan it and
publish it on a web site somewhere... DON'T attach it to your news
post.)

Owen
--

Thank you all for your replys, they were all interesting.

The first set of test measurements were taken on a 2-meter loaded vertical. Two
voltage readings were taken via a high impedance scope probe, one at the
feedpoint of the coax center connection, and the other from the connection of
the coax shield to the antenna ground. In this case the ground is a simple
raised metal 1/4 inch screen mesh about 10 square feet.

The antenna was tuned to resonance. The relative voltage readings were the
center conductor was 2x the ground reading. I do not have a way to measure
current at the base at this time.

However looking ahead, with power = iv would this imply about 2 times the energy
is being radiated from the vertical element as through the base?

Thanks Dan - kb0qil

dansawyeror wrote:
Good morning,

This question is: Taking measurements at the antenna and what they mean?

The antenna is a loaded vertical over a set of untuned radials. The feed
is 50 Ohm coax with a 1:1 isolation transformer at the antenna. I intend
to run a separate coax for measurement purposes to the feed point,
stimulate the antenna with a 10 mw signal at the operating frequency,
and measure the voltage across the antenna feed and the ground connection.

Will the voltages indicate the relative RF impedance of antenna
(including loading coil) versus the ground? If the ground were near
perfect the voltage at the feedpoint should be close to zero. These
voltages should indicate the power disapation difference between the
antenna and the ground.

Thanks,
Dan

On Sun, 11 Jun 2006 09:35:31 -0700, dansawyeror
wrote:

The first set of test measurements were taken on a 2-meter loaded vertical.

What frequency?

Two
voltage readings were taken via a high impedance scope probe,

This sounds like a set up to imagining better results than can be
obtained. Scope probes are not magic detectors and what you describe,
following, sounds like wishing:

one at the
feedpoint of the coax center connection, and the other from the connection of
the coax shield to the antenna ground.

A Scope probe has two (2) connections, and at any frequency in HF and
above, their separation is going to have a significant impact on
measurement. You never say just where the second lead goes for each
voltage reading. If you made NO second connection (and just left that
at up to the far end of the probe's connection to a mystery box) then
you have definitely confirmed that dream is in Technicolor and
surround-sound.

In this case the ground is a simple
raised metal 1/4 inch screen mesh about 10 square feet.

This is rather less than fully descriptive as 10 square feet can take
many forms.

The antenna was tuned to resonance. The relative voltage readings were the
center conductor was 2x the ground reading. I do not have a way to measure
current at the base at this time.

And this raises one particularly pointed question:
Ground was at what potential with respect to ground?

However looking ahead, with power = iv would this imply about 2 times the energy
is being radiated from the vertical element as through the base?

Hi Dan,

There is far too much ambiguity in what you post. What is posted is
fraught with conceptual problems. Basically, you've managed to obtain
two voltages whose relationship is meaningless at best. I'm sure the
potentials exist, but they define a circuit that has no practical
application (and that circuit is NOT the antenna NOR its ground
screen).

In short, just what do you think you are achieving (another
ambiguity)?

73's
Richard Clark, KB7QHC

On Thu, 08 Jun 2006 07:03:05 -0700, dansawyeror
wrote:
This question is: Taking measurements at the antenna and what they mean?

Hi Dan,

Taking up your postings in reverse order, I can see one problem and
that is emblematic in the question above. Basically it defines a
solution in search of a question. The problem is to figure out what
question you answered by taking the measurements.

This is not an auspicious beginning.

The antenna is a loaded vertical over a set of untuned radials. The feed is 50
Ohm coax with a 1:1 isolation transformer at the antenna.

I intend to run a separate coax for measurement purposes to the feed point,

This single statement introduces too much complexity for your stated
goal of taking measurements. There are rather more conventional ways
to accomplish this.

stimulate the antenna
with a 10 mw signal at the operating frequency, and measure the voltage across
the antenna feed and the ground connection.

"And ground connection?" If your isolation transformer is working,
there is no need to - unless, of course, you are simply interested in
knowing this fact, or are going to put it to some particular purpose.
However, you are approaching this with no stated purpose, so this
ambiguity is simply accelerating your Drift velocity.

Will the voltages indicate the relative RF impedance of antenna (including
loading coil) versus the ground?

If you are treating the untuned radials in relation to ground, you
really need to describe ground. It is not so easily achived as
driving a nail into the mud and declaring that's your reference.

If the ground were near perfect the voltage at
the feedpoint should be close to zero.

"If" comes with magnitudes of error that can only be imagined. From
this point on, you can make your measurements and be guaranteed they
can fit any purpose - "If" you ignore the error.

These voltages should indicate the power
disapation difference between the antenna and the ground.

They will simply represent the potentials distributed throughout an
imaginary land mine field. Tap dance with care or you may have to
sign off as Stumpy.

73's
Richard Clark, KB7QHC

Hi Dan,

Taking up your postings in reverse order, I can see one problem and
that is emblematic in the question above. Basically it defines a
solution in search of a question. The problem is to figure out what
question you answered by taking the measurements.

This is not an auspicious beginning.

The antenna is a loaded vertical over a set of untuned radials. The feed
is 50
Ohm coax with a 1:1 isolation transformer at the antenna.

I intend to run a separate coax for measurement purposes to the feed
point,

This single statement introduces too much complexity for your stated
goal of taking measurements. There are rather more conventional ways
to accomplish this.

stimulate the antenna
with a 10 mw signal at the operating frequency, and measure the voltage
across
the antenna feed and the ground connection.

"And ground connection?" If your isolation transformer is working,
there is no need to - unless, of course, you are simply interested in
knowing this fact, or are going to put it to some particular purpose.
However, you are approaching this with no stated purpose, so this
ambiguity is simply accelerating your Drift velocity.

Will the voltages indicate the relative RF impedance of antenna (including
loading coil) versus the ground?

If you are treating the untuned radials in relation to ground, you
really need to describe ground. It is not so easily achived as
driving a nail into the mud and declaring that's your reference.

If the ground were near perfect the voltage at
the feedpoint should be close to zero.

"If" comes with magnitudes of error that can only be imagined. From
this point on, you can make your measurements and be guaranteed they
can fit any purpose - "If" you ignore the error.

These voltages should indicate the power
disapation difference between the antenna and the ground.

They will simply represent the potentials distributed throughout an
imaginary land mine field. Tap dance with care or you may have to
sign off as Stumpy.

73's
Richard Clark, KB7QHC

Dan, The only way you will get a valid measurement is with your
1:1 transformer, coax, and your vector voltmeter. I guess if you
are having problems with the vector voltmeter you can do the
same, with less accuracy, using a dual channel scope, and
directional coupler.

73,

Frank

On Sun, 11 Jun 2006 20:29:17 GMT, "Frank's"
wrote:

They will simply represent the potentials distributed throughout an
imaginary land mine field. Tap dance with care or you may have to
sign off as Stumpy.

73's
Richard Clark, KB7QHC

Dan, The only way you will get a valid measurement is with your
1:1 transformer, coax, and your vector voltmeter. I guess if you
are having problems with the vector voltmeter you can do the
same, with less accuracy, using a dual channel scope, and
directional coupler.

73,

Frank

Hi Frank,

Thanx for filling in one of the gaps, what I called the mystery box.
I'd forgotten Dan had been posting about his use of a vector
voltmeter.

Dan, this is one of your habitual problems of describing the problem
at hand. You are making presumptions that all your correspondence
before you has been held in suspension to consider every posting you
make ever after. Always fully describe what you are doing, and why
you are doing it.

However, the matter of making the measurement is still problematic.
Scope probes have spring-like clips used to secure them to the point
or wire they are measuring. These are properly called "hoods" and in
most cases are removed if you are going to probe a circuit board
trace. That probe end is coaxially surrounded by a ground ring, and
scope probes often came with an accessory kit that would have a
special adapter that fit on this and extended a barb like a bayonet.
This barb was an extension of that ground ring to find the ground
point for the circuit board measurement (it presumed a ground trace
was within a quarter inch or so of the measurement point).

Barring this fine touch, that same accessory kit would come with two
alligator leaded wires with snap attachments that would fit around the
probe/cable attachment to exposed ground of the coaxial cable.
Depending upon how high the frequency, or how fast the rise time of
the measurement, you could use the longer, or would be forced to use
the shorter lead. If you were out for accuracy, you used the barb
already mentioned.

This, of course, reveals the necessity of both grounding for
reference, AND making it a short path so as to not make your probe
part of the circuit. It hardly matters if you use a 10:1 or 100:1
probe, because if you don't use these short leads or the barb, your 2
meter antenna has probably just doubled its length in a very
unpredictable manner.

73's
Richard Clark, KB7QHC

All,

There have been replies with some good comments and recommendations for not
taking meaningless measurements.

First, the objective: Modeling software predicts a loaded vertical with a 'good'
ground will have a low input impedance. This is a step on the trail to measure
that impedance.

Second, a vector voltmeter, when feed by directional couplers can be used to
measure impedance angle and therefore resonance. It can also be use to measure
the forward and re-flected power.

The setup is a calibrated signal generator, connected to a 7904 scope (A plug
in) for reference purposes only, connected to a pair of couplers connected to
the vector voltmeter, connected to test antenna. The frequency is 147 MHz. The
system is near resonance. The voltage measurements are taken with a pair of 10x
probes, connected to a dual channel plug in (B plug in).

There is no significant change to the signal or the vector voltmeter readings
when the probe leads are attached. The phase changes by less the 10 degrees and
none of the amplitudes change noticeably. I do not believe the measurement
system is materially influencing the measurements.

The next step is to make a current probe to attach to the base of the antenna.
The result is the two 'independent' systems, the couplers and the vector
voltmeter, and the voltage and current probe, should yield similar antenna
impedances.

- Dan

dansawyeror wrote:
Thank you all for your replys, they were all interesting.

The first set of test measurements were taken on a 2-meter loaded
vertical. Two voltage readings were taken via a high impedance scope
probe, one at the feedpoint of the coax center connection, and the other
from the connection of the coax shield to the antenna ground. In this
case the ground is a simple raised metal 1/4 inch screen mesh about 10
square feet.

The antenna was tuned to resonance. The relative voltage readings were
the center conductor was 2x the ground reading. I do not have a way to
measure current at the base at this time.

However looking ahead, with power = iv would this imply about 2 times
the energy is being radiated from the vertical element as through the base?

Thanks Dan - kb0qil

dansawyeror wrote:

Good morning,

This question is: Taking measurements at the antenna and what they mean?

The antenna is a loaded vertical over a set of untuned radials. The
feed is 50 Ohm coax with a 1:1 isolation transformer at the antenna. I
intend to run a separate coax for measurement purposes to the feed
point, stimulate the antenna with a 10 mw signal at the operating
frequency, and measure the voltage across the antenna feed and the
ground connection.

Will the voltages indicate the relative RF impedance of antenna
(including loading coil) versus the ground? If the ground were near
perfect the voltage at the feedpoint should be close to zero. These
voltages should indicate the power disapation difference between the
antenna and the ground.

Thanks,
Dan