Inverted-L (was OT: Vertical antenna)

> Going from loop to vertical involves two very different lob patterns. It
> was never mentioned if the antenna performance was to favor local or DX. Here
> is  one which it does not matter as it adapts for both.
>
> A nice compromise antenna which takes into account:
> ---high and low angle lobe patterns
> ---good match (resonant on 80m)
> ---small footprint
>
> ======DESCRIPTION===============================
>
>
>
>  INVERTED-L: 33 ft vertical, 33 ft top wire, feed at base against 12 16ft
>  radials. I use Radio Shack low loss 300 ohm tv wire for feed
>
>  According to calculations EZNEC had a 40ft top wire. In the field I
> trimmed it until we got an
>  acceptable match on several bands
>
>  For supports I have used the DK9SQ mast as the main and used the Black
> Widow  20ft
>  for the end support with great success
>  ----------------------------------------------------
>  I use RCA connectors for many of my antennas. I install male RCAs on wires
>
>  and interconnect with using DOUBLE FEMALES. For 300 ohm TV wire I will
> solder
>  short piece of speaker wire to each of the conductors and then securely
> tape
>  the  soldered area to the ribbon insulator body . To the end of each
> speaker
>  wire I  afix a MALE RCA. Generally I will make one speaker wire on each
> end a
>  little  shorter (3/4 inch) so I can tell easily identify which wire is
> which.
>  The RCAs  work great and it they break off in the field I carry wire nuts
> for
>  emergencies
>  ----------------------------------------------------
>  I have EZNEC pattern (PDF) for several bands and also a sketch for the
> 300
>  ohm connection if you want more details
>  ----------------------------------------------------
>  Note at the QTH I have used this for 80 and 160m with good success
> including
>  contacts with Japan on 160m. I am sure the key is the other fellows  has
> HUGE
>  arrays but it worked.
>
>  Hope this helps
>
>  Alan KB7MBI
>
>
>
>
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> (For the record, I am also addressing some off-reflector extensions of
> this thread with a single post.)
>
> We are still talking about an end-fed antenna for 80-10 which presents
> unique problems.  Trimming the horizontal length of up 30, out 30 for
> a good match will help a lot.  But that will not address avoiding an
> up to 10 dB loss problem in the radial system that can make it perform
> like a wet noodle dipole.
>
> Although there really is not that much published on this, LOCAL
> research, I repeat, RESEARCH, does indicate a lossy booby trap in what
> is done at the base with radials. Adding the high bands to the radial
> calculations takes away from using any insulated radials because the
> radials (MEASURED, not modeled) can have velocity factors as low as 45
> percent and as high as 80 percent laid on or notched into the ground.
> A range of 54 to 76 was measured in a single back yard, just moving
> the site and orientation of the measurement.  Picking and keeping an
> anti-resonant length for insulated radials, as in the vertical length,
> is an impossibility.
>
> If any of you want to prove this yourself, put down a 151 foot (46
> meter) dipole on the ground (DOG).  Insulate the ends so they don't
> short to ground and measure the resonance point and feed resistance.
> Use the handbook formulas to compute velocity factor.  Scan across 160
> through 40 meters and make a graph of the varying readings.  Let it
> lay on top of the grass, measure it, notch it in and re-measure.
> Measure in wet weather, and measure after things have dried out.
> Measure it in different places in your yard, note how it changes. Post
> your measurements as you go. Put down a 151' BARE WIRE dipole and lay
> it on top of the grass.  Measure. Water it with a garden hose and
> remeasure. Now notch it into the ground (needs to be in contact with
> the dirt all the way) and remeasure.  In particular note how the feed
> Z measurement levels out over frequency, how the Z remains more or
> less constant across the frequency range.  This exercise will help you
> in thinking about getting on 160 meters. It should also make you
> really suspicious of insulated radial claims for multiband
> applications.
>
> I have a list of call signs who are dismissive of these radial
> concerns AND ALSO argue that 0.3 dB is significant on RX.  This
> particular schizophrenia is really hard to understand.  I understand
> the reverse, someone who considers 0.3 dB significant being a really
> snotty radial purist.  He's sweating the little dB parts any place he
> can dig them up.
>
> Don't wonder if this is truthful or not, or worry that it's not the
> common wisdom (whatever that is).  Just go out and measure it
> yourself, and spend a contemplative cup of coffee at a quiet time
> about how YOUR measured results will effect use of radial wires on/in
> the ground. In analyzing this, remember that this scales to 30 feet on
> 10 meters quite nicely, that the competition is multi-element yagis,
> and if anything, ground losses on 10 meters are MORE significant than
> low bands where the enemy has more of the same constraints.
>
> Now contemplate how the ENDS of insulated wires are going to corrode
> and arc through (that's a voltage point at the wire ends) over time
> and change the radial system behavior over time.
>
> You could prove in this bad behavior on 160 (where radials are common
> and an everyday issue) if you want by putting down 120 insulated 250'
> radials and do a time study. You don't hear about this, proving it's a
> disaster, because people want to spend their precious constructing
> time and even scarcer construction dollars on something that will
> work, not disproving an idea that won't work.  That's NOT a dig at
> anyone, radial construction time and money when you're raising a
> family and/or building a career IS precious.
>
> Insulated radials are subject to resonance effects which depend on
> today's ground moisture to set today's velocity factor over/in your
> particular dirt and complicate the performance of the radials in the
> same way that the length of the vertical complicates selecting lengths
> there.  The difference is that you get it set for the vertical wire
> and you are done.  This becomes a ridiculous moving target for
> choosing a decent multi-band length with an insulated wire on the
> ground.
>
> If you're looking for some validation in the commercial world, the
> simple commercial reality is that most people simply do not want to
> deal with radials, will short-cut the procedure and then blame the
> awful results on the antenna itself.  Radials are a total commercial
> nightmare for the ham market.   All the commercial manufacturers avoid
> this conundrum by using some counterpoise technique on the high bands.
>
> If the radials are not dense, the vertical wire will get the blame. It
> will get the blame regardless of whether it is straight up or an L.
> But the 1000 pound gorilla in the room was always the radials.  I do
> not know why hamdom seems so oddly dismissive of this.  Putting
> radials down IS a real PITA.  But 60 bare wire radials buried just
> under the sod are completely invisible from the start, and lack of
> this commercial FCC grade treatment of the problem is why so many
> installations of an otherwise great stealth antenna fail.
>
> When you are stealth, you have to squeeze every last dB drop of blood
> out of that ground turnip.
>
> 73, Guy.

> Your post is a little elliptical, but am I to understand that you are saying that there
> are resonant effects noted with in-ground radials when the wire is insulated, but not when
> it's bare?
>
> If that's true it's interesting and I hadn't heard it before. Most writers on the subject
> simply say that if the wires are in or on the ground to ignore the question of resonance
> and just make them as long as possible -- and they don't mention the use of insulated or
> bare wire.
>
> I have always thought that the connection to ground from an in- or on- ground radial
> system was primarily capacitive and that insulation or lack thereof was irrelevant.
>
> I'm not challenging what you say, just interested in the idea. I've always used insulated
> wire just to improve resistance to corrosion.
>
> On 12/20/2010 9:28 AM, Guy Olinger K2AV wrote:
>> (For the record, I am also addressing some off-reflector extensions of
>> this thread with a single post.)
>>
>> We are still talking about an end-fed antenna for 80-10 which presents
>> unique problems.  Trimming the horizontal length of up 30, out 30 for
>> a good match will help a lot.  But that will not address avoiding an
>> up to 10 dB loss problem in the radial system that can make it perform
>> like a wet noodle dipole.
>>
>> Although there really is not that much published on this, LOCAL
>> research, I repeat, RESEARCH, does indicate a lossy booby trap in what
>> is done at the base with radials. Adding the high bands to the radial
>> calculations takes away from using any insulated radials because the
>> radials (MEASURED, not modeled) can have velocity factors as low as 45
>> percent and as high as 80 percent laid on or notched into the ground.
>> A range of 54 to 76 was measured in a single back yard, just moving
>> the site and orientation of the measurement.  Picking and keeping an
>> anti-resonant length for insulated radials, as in the vertical length,
>> is an impossibility.
>>
>> If any of you want to prove this yourself, put down a 151 foot (46
>> meter) dipole on the ground (DOG).  Insulate the ends so they don't
>> short to ground and measure the resonance point and feed resistance.
>> Use the handbook formulas to compute velocity factor.  Scan across 160
>> through 40 meters and make a graph of the varying readings.  Let it
>> lay on top of the grass, measure it, notch it in and re-measure.
>> Measure in wet weather, and measure after things have dried out.
>> Measure it in different places in your yard, note how it changes. Post
>> your measurements as you go. Put down a 151' BARE WIRE dipole and lay
>> it on top of the grass.  Measure. Water it with a garden hose and
>> remeasure. Now notch it into the ground (needs to be in contact with
>> the dirt all the way) and remeasure.  In particular note how the feed
>> Z measurement levels out over frequency, how the Z remains more or
>> less constant across the frequency range.  This exercise will help you
>> in thinking about getting on 160 meters. It should also make you
>> really suspicious of insulated radial claims for multiband
>> applications.
>>
>> I have a list of call signs who are dismissive of these radial
>> concerns AND ALSO argue that 0.3 dB is significant on RX.  This
>> particular schizophrenia is really hard to understand.  I understand
>> the reverse, someone who considers 0.3 dB significant being a really
>> snotty radial purist.  He's sweating the little dB parts any place he
>> can dig them up.
>>
>> Don't wonder if this is truthful or not, or worry that it's not the
>> common wisdom (whatever that is).  Just go out and measure it
>> yourself, and spend a contemplative cup of coffee at a quiet time
>> about how YOUR measured results will effect use of radial wires on/in
>> the ground. In analyzing this, remember that this scales to 30 feet on
>> 10 meters quite nicely, that the competition is multi-element yagis,
>> and if anything, ground losses on 10 meters are MORE significant than
>> low bands where the enemy has more of the same constraints.
>>
>> Now contemplate how the ENDS of insulated wires are going to corrode
>> and arc through (that's a voltage point at the wire ends) over time
>> and change the radial system behavior over time.
>>
>> You could prove in this bad behavior on 160 (where radials are common
>> and an everyday issue) if you want by putting down 120 insulated 250'
>> radials and do a time study. You don't hear about this, proving it's a
>> disaster, because people want to spend their precious constructing
>> time and even scarcer construction dollars on something that will
>> work, not disproving an idea that won't work.  That's NOT a dig at
>> anyone, radial construction time and money when you're raising a
>> family and/or building a career IS precious.
>>
>> Insulated radials are subject to resonance effects which depend on
>> today's ground moisture to set today's velocity factor over/in your
>> particular dirt and complicate the performance of the radials in the
>> same way that the length of the vertical complicates selecting lengths
>> there.  The difference is that you get it set for the vertical wire
>> and you are done.  This becomes a ridiculous moving target for
>> choosing a decent multi-band length with an insulated wire on the
>> ground.
>>
>> If you're looking for some validation in the commercial world, the
>> simple commercial reality is that most people simply do not want to
>> deal with radials, will short-cut the procedure and then blame the
>> awful results on the antenna itself.  Radials are a total commercial
>> nightmare for the ham market.   All the commercial manufacturers avoid
>> this conundrum by using some counterpoise technique on the high bands.
>>
>> If the radials are not dense, the vertical wire will get the blame. It
>> will get the blame regardless of whether it is straight up or an L.
>> But the 1000 pound gorilla in the room was always the radials.  I do
>> not know why hamdom seems so oddly dismissive of this.  Putting
>> radials down IS a real PITA.  But 60 bare wire radials buried just
>> under the sod are completely invisible from the start, and lack of
>> this commercial FCC grade treatment of the problem is why so many
>> installations of an otherwise great stealth antenna fail.
>>
>> When you are stealth, you have to squeeze every last dB drop of blood
>> out of that ground turnip.
>>
>> 73, Guy.
>
>
> --
> Vic, K2VCO
> Fresno CA
> http://www.qsl.net/k2vco/
> ______________________________________________________________
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> Post: mailto:[hidden email]
>
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> Please help support this email list: http://www.qsl.net/donate.html
>

> It is a matter of loss or lack of it.  If you look at the takeoff patterns of a
> vertical antenna on a perfect ground and then with increasing loss, the pattern
> is modified to have increasing less energy on the horizon.  However, this is the
> loss factor, not necessarily due to lack of resonance.  As one removes the
> antenna network from direct ground, and substitutes radials, several things
> happen.  IF, and that is a big IF, the amount of coupling to ground is
> maintained with non resonant radials or resonant radials are used, eff and match
> will remain .  Example, a mag mount antenna or a ground plane vertical with
> three or four resonant radials works fine and any elevation.  Just a point of
> thought.
>
> Mel, K6KBE
>
>
>
>
>
>
> ________________________________
> From: Steve Ellington<[hidden email]>
> To: Guy Olinger K2AV<[hidden email]>; Vic K2VCO<[hidden email]>
> Cc: [hidden email]
> Sent: Mon, December 20, 2010 3:44:28 PM
> Subject: Re: [Elecraft] Inverted-L (was OT: Vertical antenna)
>
> Guy:
> Very interesting....
>
> Some of your comments were verified in a recent QST article.
>
> Mar 2010 - QST (Pg. 30)
>
> An Experimental Look at Ground Systems for HF Verticals
> The author experimented with resonant vs nonresonant radials on the ground
> and found performance improved when the radials were cut to electrical
> resonance vs just measuring them with a tape.
>
> Given this, it stands to reason that if the same radial field is used by a
> multiband vertical on a higher frequency, the high current point would be at
> some distance from the antenna's base thus reducing efficiency.
>
> Now here's the question....
> Folks assume ground radials to be (non resonant) but that isn't the case. So
> what would be the best solution for a multiband antenna with ground radials?
> Well if we follow this idea, we would need multiple 1/4 wavelength radials
> for each HF band for best performance.
>
> My inverted L is 50' up and 150' out. I use a separate elevated counterpoise
> for each band. I've found that a ground rod and some buried radials have
> virtually no effect. I just use them for lightning protection.
>
> Steve
> N4LQ
>
> ______________________________________________________________
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>
>
>
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>    Mel,
>
> I personally would not consider elevated radials that are non-resonant -
> but then all of my antennas are resonant.
>
> I could consider something "balanced", like a 43 foot vertical having 43
> foot elevated radials and being fed with parallel feedline to the
> location of the tuner.  I would equate that to a dipole having 43 foot
> elements on each side of the feedline, but oriented in a different
> fashion to take advantage of things like the low angle radiation of a
> vertical antenna.
>
> I am not on the edge of salt water, so the great low angle "advantage"
> of a vertical is not available to me.  I recently bought a (used) GAP
> Titan DX antenna, and installed it - it pales in comparison to my modest
> height resonant dipoles, and I have made comparisons with DX stations as
> well as distant domestic stations - the horizontal dipoles always are
> better.  I was expecting better results for the vertical on DX, but
> failed to find it.  (anyone want to buy a GAP Titan DX for about half
> the price of a new one?).
>
> 73,
> Don W3FPR
>
>
>
> On 12/20/2010 6:56 PM, Mel Farrer wrote:
>> It is a matter of loss or lack of it.  If you look at the takeoff patterns of a
>> vertical antenna on a perfect ground and then with increasing loss, the pattern
>> is modified to have increasing less energy on the horizon.  However, this is the
>> loss factor, not necessarily due to lack of resonance.  As one removes the
>> antenna network from direct ground, and substitutes radials, several things
>> happen.  IF, and that is a big IF, the amount of coupling to ground is
>> maintained with non resonant radials or resonant radials are used, eff and match
>> will remain .  Example, a mag mount antenna or a ground plane vertical with
>> three or four resonant radials works fine and any elevation.  Just a point of
>> thought.
>>
>> Mel, K6KBE
>>
>>
>>
>>
>>
>>
>> ________________________________
>> From: Steve Ellington<[hidden email]>
>> To: Guy Olinger K2AV<[hidden email]>; Vic K2VCO<[hidden email]>
>> Cc: [hidden email]
>> Sent: Mon, December 20, 2010 3:44:28 PM
>> Subject: Re: [Elecraft] Inverted-L (was OT: Vertical antenna)
>>
>> Guy:
>> Very interesting....
>>
>> Some of your comments were verified in a recent QST article.
>>
>> Mar 2010 - QST (Pg. 30)
>>
>> An Experimental Look at Ground Systems for HF Verticals
>> The author experimented with resonant vs nonresonant radials on the ground
>> and found performance improved when the radials were cut to electrical
>> resonance vs just measuring them with a tape.
>>
>> Given this, it stands to reason that if the same radial field is used by a
>> multiband vertical on a higher frequency, the high current point would be at
>> some distance from the antenna's base thus reducing efficiency.
>>
>> Now here's the question....
>> Folks assume ground radials to be (non resonant) but that isn't the case. So
>> what would be the best solution for a multiband antenna with ground radials?
>> Well if we follow this idea, we would need multiple 1/4 wavelength radials
>> for each HF band for best performance.
>>
>> My inverted L is 50' up and 150' out. I use a separate elevated counterpoise
>> for each band. I've found that a ground rod and some buried radials have
>> virtually no effect. I just use them for lightning protection.
>>
>> Steve
>> N4LQ
>>
>> ______________________________________________________________
>> Elecraft mailing list
>> Home: http://mailman.qth.net/mailman/listinfo/elecraft
>> Help: http://mailman.qth.net/mmfaq.htm
>> Post: mailto:[hidden email]
>>
>> This list hosted by: http://www.qsl.net
>> Please help support this email list: http://www.qsl.net/donate.html
>>
>>
>>
>>
>> ______________________________________________________________
>> Elecraft mailing list
>> Home: http://mailman.qth.net/mailman/listinfo/elecraft
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>> Post: mailto:[hidden email]
>>
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>> Please help support this email list: http://www.qsl.net/donate.html
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> ______________________________________________________________
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> "I personally would not consider elevated radials that are non-resonant"
>
>
> I guess I'm having a difficult time with that comment.  You can have a
> resonant system without the elevated radials themselves being
> "resonant"  ... i.e, any two of them acting like a resonant dipole.  If
> the elevated radials are shorter than a 1/4 wavelength, all that is
> required is that the vertical section be a little longer than a 1/4
> wavelength to compensate.  If the radials are longer than a 1/4
> wavelength, the vertical section needs to be shorter than a 1/4
> wavelength for resonance.
>
> Elevated radials are kind of like the lower half of a vertical 1/2
> wavelength dipole except that it is "fanned out" for symmetry, and if
> the radials are longer or shorter than half of a 1/2 wavelength dipole
> the feedpoint simply behaves similarly to an off-center fed dipole.  You
> can prove this to yourself with EZNEC ... start with a vertical section
> longer than 1/4 wavelength and see what length radials you need to have
> a resonant feedpoint.  Then do the same thing with different lengths of
> vertical sections and see the effect on radiation pattern.   I can tell
> you that it isn't a direct function of radial resonance.
>
> I could be wrong, but I don't see any need at all for the radials to be
> "resonant" on their own.  You want system resonance and generally
> speaking, for radiation effectiveness you want as long a vertical
> section as you can manage.  You might want to choose a vertical section
> somewhat longer than a 1/4 wavelength and radials correspondingly
> shorter than a 1/4 wavelength in order to take advantage of that
> "off-center feed" aspect I mentioned in order to get a 50 ohm match.
>
> The only situation where resonant radials might be required is if you're
> trying to decouple whatever is on the other side of the radials.  In
> that case, the radials act like a choke to keep current on the feedpoint
> side of the resonant radials.  You can see that effect with EZNEC as well.
>
> 73,
> Dave   AB7E
>

> Guy:
> Very interesting....
>
> Some of your comments were verified in a recent QST article.
>
> Mar 2010 - QST (Pg. 30)
>
> An Experimental Look at Ground Systems for HF Verticals
> The author experimented with resonant vs nonresonant radials on the ground
> and found performance improved when the radials were cut to electrical
> resonance vs just measuring them with a tape.
>
> Given this, it stands to reason that if the same radial field is used by a
> multiband vertical on a higher frequency, the high current point would be at
> some distance from the antenna's base thus reducing efficiency.
>
> Now here's the question....
> Folks assume ground radials to be (non resonant) but that isn't the case. So
> what would be the best solution for a multiband antenna with ground radials?
> Well if we follow this idea, we would need multiple 1/4 wavelength radials
> for each HF band for best performance.
>
> My inverted L is 50' up and 150' out. I use a separate elevated counterpoise
> for each band. I've found that a ground rod and some buried radials have
> virtually no effect. I just use them for lightning protection.
>
> Steve
> N4LQ
>

>  Dave,
>
> If you read the radial tuning procedure in Low-Band DXing, you will find
> that it "all comes out in the wash".  Yes, your statements are correct,
> and in fact that is how I did mine. Although  I did not resonate my
> vertical monopole against any ground plane - I simply cut the lengths to
> what was stated in the article, and then cut each radial to resonate
> with that particular length of the "monopole".  If the result was
> slightly "off-center fed", so be it, the impedance and the resonance
> point obtained were a good match for 50 ohm coax, and I left it at that.
>
> OK, so the ideal impedance of a vertical antenna is 32 ohms - I got
> closer to 50 ohms which indicates a 15 ohm loss in signal efficiency.
> It matches my feedline nicely, and I an willing to accept the the 3%
> loss in efficiency that represents.
>
> The ground conductivity in my area is not the greatest, so I have
> accepted the logical consequences of that fact.
>
> 73,
> Don W3FPR
>
>
> On 12/20/2010 8:06 PM, David Gilbert wrote:
>> "I personally would not consider elevated radials that are non-resonant"
>>
>>
>> I guess I'm having a difficult time with that comment.  You can have a
>> resonant system without the elevated radials themselves being
>> "resonant"  ... i.e, any two of them acting like a resonant dipole.  If
>> the elevated radials are shorter than a 1/4 wavelength, all that is
>> required is that the vertical section be a little longer than a 1/4
>> wavelength to compensate.  If the radials are longer than a 1/4
>> wavelength, the vertical section needs to be shorter than a 1/4
>> wavelength for resonance.
>>
>> Elevated radials are kind of like the lower half of a vertical 1/2
>> wavelength dipole except that it is "fanned out" for symmetry, and if
>> the radials are longer or shorter than half of a 1/2 wavelength dipole
>> the feedpoint simply behaves similarly to an off-center fed dipole.  You
>> can prove this to yourself with EZNEC ... start with a vertical section
>> longer than 1/4 wavelength and see what length radials you need to have
>> a resonant feedpoint.  Then do the same thing with different lengths of
>> vertical sections and see the effect on radiation pattern.   I can tell
>> you that it isn't a direct function of radial resonance.
>>
>> I could be wrong, but I don't see any need at all for the radials to be
>> "resonant" on their own.  You want system resonance and generally
>> speaking, for radiation effectiveness you want as long a vertical
>> section as you can manage.  You might want to choose a vertical section
>> somewhat longer than a 1/4 wavelength and radials correspondingly
>> shorter than a 1/4 wavelength in order to take advantage of that
>> "off-center feed" aspect I mentioned in order to get a 50 ohm match.
>>
>> The only situation where resonant radials might be required is if you're
>> trying to decouple whatever is on the other side of the radials.  In
>> that case, the radials act like a choke to keep current on the feedpoint
>> side of the resonant radials.  You can see that effect with EZNEC as well.
>>
>> 73,
>> Dave   AB7E
>>
> ______________________________________________________________
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