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Antennas, Featured, General, Newsletter

Differential and Common Modes on Transmission Lines – Part I

Introduction

In Part I of this three-part series, we discuss what is meant by differential and common modes on RF transmission lines. Part II will discuss the construction of the Joe Reisert, W1JR, 1:1 balun [1] that may also be used as a common mode choke. Part III will present some test results for the common mode rejection of two common mode chokes, one constructed with #31 ferrite material and another constructed with #43 ferrite material.

Differential Mode

Two familiar balanced transmission line types that will support differential mode operation are open wire line and waveguide. This section will focus on open-wire lines. An ideal model of an open-wire line is shown in Figure 1. Current from the transmitter or other matched source enters the transmission line from the left. The transmission line may be thought of as an infinite number of distributed inductors and capacitors. Each infinitesimal length of the transmission line is made up of two tiny inductors, and each infinitesimal pair of lines forms a capacitor between them. All transmission line types, not only open wire lines, are characterized by values for inductance per unit length and capacitance per unit length.

Figure 1 Idealized Model of Open Wire Transmission Line. An open wire transmission may be modeled as an infinite number of distributed inductors and capacitors.

In reality, the conductors will have a resistance per unit length. If there is a dielectric present, as there might be in a window line, twin-lead or open wire line (the dielectric would be the spreaders and air), there will also be a leakage conductance through the dielectric between the conductors.

Consequently, all transmission lines are characterized by an impedance, Z0, that is defined by,

where,

Z0 is the characteristic impedance in ohms

R is the resistance of the wire per unit length

G is the leakage conductance through the dielectric per unit length

L is the inductance of the transmission line per unit length

C is the capacitance of the transmission line per unit length.

Years ago, it was quite common for roof-mounted television antennas to be fed with 300-ohm twin-lead. Twinlead is a parallel wire transmission line in which the conductors are spaced apart with plastic dielectric. The dielectric fills very little of the volume around the conductors. There is just enough plastic to cover the conductors and space them a small distance apart. Consequently, twin-lead will be treated as though it were an open-wire line. If we assume that the resistance of the wire and the leakage conductance are negligible, we can make the approximations that,

As a result, the impedance of the transmission line may be simplified to,

By making further approximations that the wire diameter, d, is much smaller than the center-to-center spacing of the conductors, D, and that the value of the dielectric constant filling the volume around the conductors is close to unity,

it is possible to approximate the values of L and C from,

where,

and,

where,

from which we get,

Furthermore,

Thus,

Substituting the numerical values, we have,

So, by making reasonable approximations, our estimate is very close to 300 ohms.

When driven by and terminated in its real, characteristic impedance, the currents and voltages anywhere along the open wire transmission line will be mostly uniform. Assuming that the wire transmission line is well made, dissipative losses in the conductors and leakage conductance will account for any nonuniformity. Since the currents in the transmission line conductors are equal and travel in opposite directions, the transmission line is said to be operating in differential mode. Simply stated, the transmission line operates in a single mode, and what you put in one end is mostly what you get out of the other end. The transmission line will not radiate signals, nor will it receive signals and noise.

Figure 2 is greatly oversimplified, but it is adequate to explain what is meant by differential mode. We note that if we take a snapshot of the currents on each half of the dipole, i1, and i2, they are in the same direction as are the currents, i1 and i2, in the open wire transmission line. From this, we may conclude that the transmission line is operating in differential mode while the antenna is operating in common mode, and that is what is causing the antenna to radiate RF in the first place. At least for this case, we have demonstrated that we may associate common mode currents with antenna radiation (and reception, too).

Transmission Lines

Figure 2. Balanced Open Wire Transmission Line Feeds a Dipole Antenna. The unbalanced transmitter or transceiver is transformed to a balanced transmission line with a balun. The transmission line operates in a single, differential mode because the currents are opposite while the antenna operates in a common mode because the currents are in the same direction.

Common Mode

For completeness, let’s begin by calculating the characteristic impedance of an unbalanced coaxial transmission line. Coaxial cable was first employed to prevent interference between transmission lines in transatlantic cables used for telegraphy prior to 1860. It was Oliver Heaviside who first described its theory of operation.

Let’s determine the characteristic impedance of RG-400/U since our common mode chokes were constructed using this type of coax. RG-400/U was chosen because of its high power handling capability and small outer diameter. If the inner diameter of the coax shield is much greater than the diameter of the center conductor,

where,

d is the diameter of the coaxial transmission line center conductor
D is the inner diameter of the coaxial transmission line shield,

the inductance per unit length and capacitance per unit length for coaxial cable are approximated by the formulas,

where,

from which we obtain,

As before,

Substituting the numerical values, we have,

Again, reasonable assumptions lead us to the expected result.

When we speak of common mode for transmission lines, we are discussing signals that may enter or leave the conductors in the same direction. The most common cause of common mode current is an unbalanced transmission line. Imagine, if you would, a dipole antenna being fed by the coaxial transmission line of Figure 3. The currents inside the coax will be opposite. Now, suppose that the currents in the coax reach the antenna. If we take a snapshot of the currents on each half of the dipole, i4, and i2, they correspond to the directions of the currents, i3, and i1, on the inside of the transmission line (but not their amplitudes). From this, we may conclude from the currents on the antenna that the antenna operates in common mode, as before.

However, we also notice that there are currents, i5, on the outside of the coax shield and the current, i1, on the center conductor that are in the same direction. These currents operate in common mode. The outside of the coaxial cable shield operates as a single conductor transmission line, a distinct mode. This mode operates separately from the mode represented by currents i3 and i1, which operate in, essentially, differential mode. Thus, we have a transmission line system that operates in two distinct modes. The outer cable shield will radiate upon transmit and will be susceptible to receiving signals and noise upon receive.

Figure 3. Common Mode Currents on Unbalanced Coaxial Transmission Line. Because of its construction, there is no way to keep the current i3 from dividing into currents i4 and i5. Since currents i1 and i5 are in the same direction, they operate in common mode. Since the currents i1 and i3 are in opposite directions, they operate in differential mode. Thus, we have a transmission line system that operates in two distinct modes. The common mode conductor will radiate and also be susceptible to receiving signals and noise.

To reiterate, since one side of our dipole antenna is connected to the shield, any current that is traveling inside the shield may split between the antenna and the outside of the shield. In this configuration, there is nothing to stop this from happening. Now, we have a center conductor and the outside of the shield acting like a pair of conductors with currents traveling in the same direction. This is very much like a single wire transmission line, and the outer shield will radiate and receive power quite nicely in common mode. Another observation is that the currents on the antenna halves are asymmetric, and this asymmetry will corrupt the antenna pattern. Notice that the current on the outer shield may be returned to the chassis of the transmitter. This can become very unpleasant for the operator.

A remedy for this is to convert the unbalanced coaxial line to a balanced line where it feeds the antenna and provides a means to suppress current i5. This is done with a device called a choke balun (balanced-to-unbalanced). The choke balun effectively disconnects the inner shield from the outer shield so that most of the current will no longer flow on the outer shield. Can there still be common mode currents on the coax? The answer is yes. The shield can still couple some of the antenna’s radiated emission back to the shack, or signals and noise on the shield may originate from elsewhere. Either or both may occur because it’s not unusual to place a choke balun at the feedpoint of the antenna. RF can still couple to the coax beyond where the choke is located. For this reason, it is not unusual to place another choke at another current maximum on the coax outer shield where it may be effective and at a location that is close to the entrance to the shack. This point on the transmission line may be found with a clip-on antenna current probe like the MFJ-854 [2], or by modeling the antenna in something like EZNEC [3]. It is incorrect to assume that the placement of a common mode choke is arbitrary. If we want the common mode choke to work, it should be located near a voltage null on the outside coax shield. Another effective way to reduce the common mode signals and noise on the outer shield from reaching the shack is to bury at least some of the coax.

Baluns may be constructed from sections of coax or from wire or coax wrapped on ferrite cores. Baluns constructed from coax alone, rely upon the electrical length of the coax to work, so they tend to be narrow band. Baluns constructed from coax are more practical for UHF and VHF because of the short length of transmission line required. Coax baluns do not possess the same choking properties that ferrite baluns have.

Part II of this three-part series will discuss the construction of a Joe Reisert, W1JR, 1:1 balun that may also be used as a common mode choke.

References

  1. Reisert, Joe, Simple and Efficient Broadband Balun, Ham Radio, September 1978, pp. 12-15. https://worldradiohistory.com/Archive-DX/Ham Radio/70s/Ham-Radio-197809.pdf
  2. https://mfjenterprises.com/products/mfj-854
  3. https://www.eznec.com/
Antennas, Featured, General, Newsletter

DIY 6m Moxon Antenna

1 Comment
6m Moxon antenna
6m Moxon based on a plan by Bruce Walker N3JO

The ARRL book Magic Band Antennas for Ham Radio by Bruce Walker N3JO has the plans for a 6m Moxon Antenna that I found interesting because, instead of wire or tubing, it uses 3/4″x1/8″ aluminum stock available in hardware stores in 4′ or 8′ lengths.  No bending, just drilling!  I’ve worked on it bit by bit over the last few months or so, and the CQ VHF contest this weekend gave me the extra push I needed to get it up into the air!

I got 8′ sections of the aluminum stock, but I cut the center of the parasitic element (the longest piece) into 2 pieces of less than 4′ each, in case I want to pack the antenna into a car.

The boom is PVC pipe, and for the spacers between the active element and the parasitic element, I used a 1-1/2″x3/4″ vinyl substitute for wood used for trim, which is also available in hardware stores.  I cut it down to 3/4″ wide strips for the insulators between the ends of the elements.  Unlike the book, I used the full width to attach the elements to the boom so that the U-bolts could be attached beside, instead of under and through, the elements.  (It was not at all clear to me from the book’s drawing — no photographs — how the parasitic element was attached to the boom given the bolt positions as drawn.  Also, I may have misunderstood if the author meant 1″ ID or 1″ OD pipe; since it is Pipe, I assumed it was ID.)

I made a coil balun as described in the book, and the UHF connector is mounted on a right-angle piece of plastic cut from an inexpensive outlet box which is a trick suggested in the book.

I put Noalox on the stainless steel nuts and bolts to prevent them from “welding” themselves together and also to protect the aluminum from the stainless steel.

I changed my ideas on how to get it up into the air a couple of times, and today I finally just went and got an MFJ-1911 lightweight fiberglass mast and a set of MFJ-2830X guy rings at our local “candy store.”  (I wish there were a ring in the set with an even larger center hole.)  I did not extend it to the full 20′ (yet, anyway) because I was concerned that the antenna was too heavy, so it is only about 14′ up in the air now.

I used hose clamps (threaded through a water drain tube, so the clamps don’t cut into the mast) above each exposed joint in the mast to give added protection against the “twist lock” mast unlocking and collapsing into itself.  I put another one around the base with loops of paracord through it that I can hold down with tent stakes, in addition to putting the base of the mast against one of the raised garden beds to keep it from slipping.  (I’m sorry, I don’t recall which video blogging ham I learned those hose clamp tricks from.)

6m Moxon antenna
6m Moxon based on a plan by Bruce Walker N3JO before it was raised up

The 6m Moxon Antenna ended up being tilted slightly (actually, rotated around to be almost upside-down!), but I’ve got some U-bolt saddles on order to fix that.  (They’ll be the two pieces of metal besides the aluminum elements that aren’t stainless steel.  Unfortunately, I used a smaller size U-bolt than what seems to be the “standard” for antenna masts of about 2″ inside diameter for the U-bolts.)  I made an extension that screws in above the vertical piece of PVC pipe through the boom so that I could add support ropes for the insulators far out from the center of the antenna, but I haven’t put it on yet to save weight.  (I may replace the mast with a heavier-weight product from MFJ to allow this and to raise it higher.)

6m Moxon antenna
6m Moxon based on a plan by Bruce Walker N3JO

As you can see below, the minimum SWR is 1.0 at about 52,140 MHz, not the point in the 6m band where I would like it for FT8, but at least it is in the lower half of the band.  (I haven’t thought about how to tune it or if I need to.  But I do know that I want to replace the thin coax feeding the antenna now with LMR-400.)

SWR curve hitting 1.0 at about 52,140 MHz
SWR curve hitting 1.0 at about 52,140 MHz

With much-appreciated help from my XYL Merle W1MSI, I was able to get the DIY 6m Moxon Antenna up late this afternoon and try it out before the band closed for the day.  The “magic band” did what it does, and I was able to make 27 QSOs on VHF with FT8, from my shack in FN42 (southern New Hampshire) to as far as EL98 (Florida) and  EN52 (Wisconsin).  So I think the antenna is working pretty well.  It is the first beam antenna at my shack.

For a while there, I was happily collecting DXCCs and US states on HF with SSB, but then I discovered FT8, and after that FT4, and now I’ve got grid squares to collect on VHF — so I have even more paper to chase!

Aron, W1AKI

Featured, General, Homebrewing, Newsletter, Station Equipment

Control Your Rig Remotely With This USB-Controlled Power Station

Introduction

Remote station operation has become more popular now that several rig manufacturers offer accessories to enable the radio amateur to do so. However, there is usually a large expense associated with acquiring these accessories. For some, it may not be cost-effective to own them for occasional use. In this article, we describe a solution for remote operation from another room of your home, your yard, or while on travel. It is also convenient for controlling on/off functions in the shack with the click of the mouse. The solution revolves around a Velleman relay card that can control a number of relays from a computer desktop.

The Power Station

This article describes a USB-controlled AC power strip, Figure 1, that was built around the Velleman K8090 8-Channel Relay Board in kit-form [1]. Varistors were added to the board as a recommended option [2]. The board can also be purchased fully assembled [3].

Figure 1. USB Controlled Power Strip. Each 15A duplex outlet is under USB control. There are just enough contacts on the barrier strip for 8 relays, neutrals, and grounds.

The PC communicates to the board via USB. A free, desktop, graphical user interface (GUI) is provided by Velleman for use as test software, or you may opt to purchase an application such as N-Button Lite [4].

Some type of rig interface is required to control your rig and audio from a PC. You may use the interface in your rig if it has one, or buy or build one of your own.

In order to log onto your computer, see your desktop remotely and hear rig audio, some kind of conferencing software is required. I use TeamViewer [5] to see my desktop and hear computer audio remotely.

Cautionary Notes

You will be dealing with AC line voltage in this project. Keep the clear polycarbonate cover on the enclosure while AC power is applied. Since the Velleman card operates on 12 VDC and control is over USB, all testing can be completed prior to plugging the AC line cord into the wall socket.

The FCC requires some means to disable the transmitter within 3-minutes if something goes wrong during remote operation. Velleman makes a WMT1206 Universal Timer Module with USB Interface [6] that should prove useful for this application. Its relay can handle 8A of AC. There are also similar USB timer modules available on eBay. It’s also a good idea to have the ability to reboot your computer remotely. The exact details of how to implement this FCC requirement are left to the reader but there are plenty of suggestions to be found online.

Kit Construction

An experienced kit builder can assemble and test the board in an afternoon. The added varistors are specified at 125J, 300VAC, 385VDC, and 4500A clamping peak current [7]. If these are not readily available, there are equivalents. A suggestion was made to thicken the circuit board traces that must handle the 16A relay current with additional solder. I didn’t care for this approach and opted to solder bus wire onto these traces, instead. You might find it ludicrous to solder #14 AWG buss wire onto the board, so your other option is to derate the relay capabilities to what the conductors can safely handle since the PCB traces have not been rated. For example, the ampacity of #20 AWG buss wire is at least 5A (11A at 75°C) [8], and that will be good for 575W. None of the circuits that I run from this PCB require anywhere near 575W.  Take care not to damage the PCB traces while soldering. Excessive heat will lift the PCB traces.

Housing, Connectors, and AC Outlets

There are 8 duplex outlets in this project – each one under separate relay control. Each outlet has been wired with #14 AWG. Each relay is rated at 16A, resistive load (see the previous section for derating). The duplex outlets have been spaced far apart so that a variety of line cords and wall adapters will fit without interference. The control board is housed in a Bud Industries PN-1340-C polycarbonate enclosure [9] with a clear cover (not affixed), Figure 2. The clear cover provides visibility for the status lights on the PCB. Bud Industries also manufactures an internal aluminum panel, PNX-91440 [10], upon which the PCB and barrier strip have been mounted. Take care in locating connectors on the housing or the PCB will not fit. The PCB is fastened to the aluminum panel with 4-40 hex standoffs. The Bud Industries enclosure is fitted with 1/2-inch male terminal adapters [11] at either end. DC power for the relays enters the enclosure at the top left through a 2.1mm panel mount connector [12]. The relay power required is 12VDC at 400mA. A 12 VDC wall adapter with a 2.1mm plug can provide this voltage. AC power enters the housing through a cable gland at the lower left. Switchcraft makes the USB connector at the lower right. It converts USB A inside the enclosure to USB B on the outside. The connector was purchased from Newark [13]. The short USB jumper patch cord was purchased on Amazon [14]. A step drill [15] is the most effective way to bore the large holes in a polycarbonate or ABS case without cracking it.

Remote Control

Figure 2. Interior View of Control Board Enclosure. Eight 16A relays are visible. There’s not much space to spare. Take care in wiring the AC connections and in locating the connectors on the housing or the PCB will not fit.

Software Apps

The test software that is supplied by Velleman for the circuit card is adequate, or N-Button Lite [16] may be purchased Figure 3. A screenshot of the lower right corner of the monitor shows the buttons for N-Button Lite. The green buttons indicate that four of the eight relays are active. If you purchase the Bud enclosure with a clear polycarbonate cover as I did, you will be able to see all eight red indicator lights on the Velleman board, one for each relay. They will light when a relay becomes active.

Remote Control

Figure 3. Screenshot of PC desktop. N-Button Lite controls each of 8 relays.

References

References
[1] https://www.jameco.com/z/K8090-Velleman-8-Channel-USB-Relay-Card-Kit_2123952.html
[2] https://www.velleman.eu/products/spareparts/?code=vdr300
[3] https://www.amazon.com/Velleman-VM8090-8-Channel-Relay-Card/dp/B00CPCQ88Y
[4] https://www.serialporttool.com/GK/n-button-lite/
[5] https://www.teamviewer.com/en-us/?utm_source=google&utm_medium=cpc&utm_campaign=us|b|pr|19|jul|Brand-TeamViewer-Exact|free|t0|0|dl|g&utm_content=TeamViewer_Exact&utm_term=teamviewer&gclid=Cj0KCQjw5ZSWBhCVARIsALERCvzZflNoCfAiFgi9STEIDiJkCtRuazuukru
[6] https://whadda.com/product/universal-timer-module-with-usb-interface-wmt206/
[7] Velleman, op. cit. https://www.velleman.eu/products/spareparts/?code=vdr300
[8] https://en.wikipedia.org/wiki/American_wire_gauge
[9] https://www.budind.com/product/nema-ip-rated-boxes/pn-series-nema-box/ip65-nema-4x-box-with-clear-cover-pn-1340-c/ – group=series-products&external_dimension
[10] https://www.budind.com/accessories/aluminum-internal-panel-pnx-91440/
[11]https://www.homedepot.com/p/1-2-in-Male-Terminal-Adapter-R5140103/202043509
[12] https://www.amazon.com/2-1mm-DC-Power-Jack-Chassis/dp/B073PKZPQ7
[13] https://www.newark.com/switchcraft-conxall/ehusbbabxpkg/usb-adapter-type-b-rcpt-a-rcpt/dp/08N9043?gclid=Cj0KCQjw5ZSWBhCVARIsALERCvycmWj-i38ykHaPrlbG8Eb-uxCyxcpZzdNWmZ0r7Z2iV9zgd7CpVKAaAh5KEALw_wcB&mckv=_dc|pcrid||plid||kword||match||slid||product|
[14] https://www.amazon.com/inch-USB-2-0-Male-Cable/dp/B079ZP65SN?th=1
[15] https://www.homedepot.com/s/step%2520drill?NCNI-5
[16] Relay Pros, op. cit. https://www.serialporttool.com/GK/n-button-lite/

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