Sunday, November 17, 2019

Homebrew construction of 2 and 4 port splitters/combiners for the LF-MF-HF(30 kHz-30 MHz) frequency range.

Note:

This is a follow-up of a previous article, "Characterizing the Mini-Circuits ZFSC-4-3, ZFDC-20-3, ZFSC-4-1-BNC+ and ZFSC-2-1+ well below their designed frequency range" - link.

Comment:
All of the devices described here could also be used to combine signals from multiple sources.  Unless the signals being combined are "phase coherent" (e.g. from the same signal source) the insertion loss will be the same as that in splitter operation.

"Rolling your own" splitter for LF through HF (<30kHz-30MHz):

Unless you get the Mini-Circuits devices for cheap at a swap meet or via a surplus outlet, their cost may be a bit prohibitive for casual use in the shack.  How about making your own splitter that will work over the 30 kHz-30 MHz range?

Why would one want this?  There are a number of modern Web-Based SDR receivers that cover from (literally!) audio through 30 MHz - and in my case, I have a number of KiwiSDR receivers - link that are connected to an antenna system that is capable of intercepting signals over this range.  If one has several such receivers, it can be a challenge to find a splitter that works well over this range - particularly the low end - as described in the article linked above.

Figure 1:
A two-transformer splitter/combiner.  L1 transforms the impedance at
J1 to half that value and L2 splits the signal itself.  R is twice the system impedance
- 100 ohms in a 50 ohm system.  The tap on L1 is at 0.707 times of the total
number of turns:  A tap at 7 of 10 total turns is "close enough" while C is a high-
frequency compensating capacitor.  L2 is a bifilar-wound transformer with the
two sets of windings connected in series at the common point.
Click on the image for a larger version.
To do this, ferrite - rather than iron-powder - cores would be used, the most common types using mix 31, 43, 61, 73 and 75 - and the most useful of the lot for the low-frequency end are types 73 and 75.  Not having a complete assortment of the ferrite types on hand, I used what I had and the use of a binocular core with mix 43 and a ferrite with mix 75 is discussed here.

Two-transformer splitter/combiner:

A common splitter topology consists of two cores:  One to transform the impedance to half that of the characteristic system impedance and a second to split the signal two ways as depicted in Figure 1.  The inductance of L1 and L2 should be high enough to present a reactance of 3-10 times the system impedance at the lowest frequency.

Figure 2:
Measured insertion loss of a transformer using two BN43-202 cores wound
with 30 AWG wire:  10 turns, tapped at 7 turns for L1 and 10 bifilar turns
for L2.  R = 100 ohms and C = 62pF.
The required number of turns to achieve the desired low-frequency response
increases the stray capacitance, undesirably increasing loss at the
high-frequency end of the HF spectrum.
Click on the image for a larger version.
Figure 2 shows a tested version of this transformer, the details noted in the caption.  According to this diagram the insertion loss is a nominal 3-ish dB from 50 kHz to 1 MHz, dropping down to about 5 dB loss between 20 kHz and 10 MHz and nearly 6dB at 30 MHz.  Capacitor "C" was made variable, adjusted for lowest loss, improving the highest end by a bit over 1dB, and its value measured.

For LF and HF use, this splitter is just "OK" - the loss being an extra 3dB at the high end of the spectrum:  If preceded with amplification, this loss may be tolerable - but note that even the nominal 3dB loss of a 2-way splitter should be of concern at the higher HF bands as signals - and the natural noise floor - can be quite weak and additional loss can drop the receiver's noise floor below that, potentially causing the loss of reception of weaker signals.

Much of the high-frequency loss is due to the inter-winding capacitance.  Experimentally, versions were constructed using wire with PTFE ("Teflon") insulation and comparing it with another with the same number of turns of the 30 AWG enamel and the losses for the PTFE wire version were 1.5-2dB lower - but fewer turns could be passed through the core and low-frequency response suffered.

Figure 3:
In this form, the primary (connected to J1) has 1.414 times as many turns
as each of the two identical secondary windings.  The value of R is half that
of the characteristic system impedance, or 25 ohms for a 50 ohm system:
Parallel 51 ohm resistors were used for a nominal 25.5 ohms.
Typical turns values are 10/7 turns, 14/10 turns and 20/14 turns for the
primary and bifilar secondary, respectively.  For the center-tap, the windings
of the secondary are connected as if they were in series.
Click on the image for a larger version.
If a higher-permeability material (like 73 or 75 mix) were used for the core rather than 43, fewer turns could have been used to maintain the inductance and low-frequency response and it is likely that the high-frequency loss would be reduced.

Single-transformer splitter-combiner:

Another common splitter/combiner is the form depicted in Figure 3, using a single core - and potentially this can reduce loss compared with a device with two cores.

In this system the primary should consists of 1.414 times (e.g. the square root of two) as many turns as each of the secondary windings.

Figure 4:
The insertion loss of the described two-way splitter using 24 AWG wire on
an FT50-75 core:  It is well below 4dB over the range of 10 kHz to 60 MHz.
Click on the image for a larger version.

Both a binocular and toroidal core were tried and better results were obtained with the FT50-75 core than the available BN43-202 binocular core - both because the higher permeability improved the low-end response and larger wire could be used for the toroid:  Capacitance was reduced on the toroid because the turns could be spread out rather than being tightly overlaid as the case of the binocular core, and high-end losses were further-reduced by laying the turns of the secondary next to each other rather than the higher capacitance resulting from the two conductors being twisted as is commonly done with Bifilar windings.

The results of this work are visible in Figure 4.  For this transformer, two parallel secondary "bifilar" windings consisting of 14 turns each were carefully and neatly laid down using 24 AWG enamel wire with 20 turns of 24 AWG over the top.  As can be seen, the results are excellent:  The insertion loss is below 3.6dB from 10 kHz to 60 MHz and the overlaid Smith chart shows the VSWR to be pretty well-behaved, never exceeding 1.5:1 over this range.

Figure 5:
The port-to-port isolation is quite good over the range of 100 kHz to
30 MHz.  The peculiarly-flat isolation limit of the bottom "trough"
of the graph is a result of the value of "R" not being exactly 1/2 of the
impedance value of the system used for testing:  If R is made variable,
higher isolation may be obtained in the middle of the range - but the
difference between that and the fixed resistors used was only an
ohm or two.  In practice, high values of isolation can be obtained only
if the source and load impedances are purely resistive, but since
practical antennas, amplifiers, receivers and filters will not be perfect
sources and loads, such high isolation cannot be achieved in practice.
Click on the image for a larger version.
Additional tests were run to determine the port-to-port isolation of this splitter - the results being visible in Figure 5.  Over the range of 100 kHz through 60 MHz, the isolation exceeds 15dB, exceeding 25dB from abut 100 kHz through 30 MHz.  During testing, the same device had been constructed using smaller 30 AWG wire and the results were worse above 10 MHz (by 2dB at 30 MHz) - likely a result of the skin effect losses of this smaller wire.

A four-way splitter:

I happened to have a need to take signals over a wide frequency range and split it four ways - specifically, to several KiwiSDR receivers, stand-alone web-based receivers capable of reception over the 5kHz-30MHz range - so I decided to construct a splitter using the configuration described above.  To do this, I would need three splitters:  A pair of splitters to feed the four outputs and one more splitter to feed the aforementioned two splitters.  This splitter is depicted schematically in Figure 6:
Figure 6:
For a 50 ohm system, resistors "R" are 25.5 ohms (two 51 ohm resistors
in parallel) and capacitors "C" are 47pF NPO/C0G types used to "flatten"
the response to 30 MHz.
The as-built splitter uses FT50-75 cores wound with 24 AWG, the dual
secondary windings consisting of 14 turns and the primary with 20 turns.
The dual secondaries are laid parallel rather than twisted to minimize stray
capacitance.  The center-tap is connected as if the two secondary windings
were placed in in series.
Click on the image for a larger version

This splitter consists of three of the two-way splitters connected as described:  FT50-75 cores wound with 14 turns, each of two parallel 24 AWG conductors for the secondary overlaid with 20 turns of 24 AWG for the primary.  During testing it was observed that the addition of capacitors "C" slightly reduced (by nearly 1 dB) the insertion loss at 30 MHz at the expense of increased loss (about 2dB) at 60 MHz - but because the target high-end limit was 30 MHz, this was considered to be acceptable.

The end result was an insertion loss (see Figure 7) of less than 7 dB from 20 kHz through 30 MHz, rising to 8 dB and 9.3 dB at 10 kHz and 60 MHz, respectively, being under 6.3dB between 50 kHz and 10 MHz.  In testing port-to-port isolation, the worst case results were those obtained from the same transformer (e.g. T2 or T3) and this value was at least 15dB from 50 kHz to 30 MHz.

Figure 7:
This shows the typical insertion loss of the as-built four-way splitter
depicted schematically in Figure 17.  The insertion loss is less than 7 dB
from at least 20 kHz through 30 MHz with the VSWR being 1.5:1
or less over that same range.
Click on the image for a larger version.
This four-way splitter was built into a small die-case box for mechanical rigidity and electrical shielding.  Inside the box, pieces of plastic tape were affixed to the bottom and the lid to eliminate the possibility of inadvertent shorting of connections to the case:  Details of the mechanical construction may be see in Figure 8.

To reiterate:  It was determined that with the number of turns required to obtain good response into the LF range (e.g. below 30 kHz) that the use of twisted bifilar windings was NOT indicated:  Doing so resulted in excess loss (3-6dB) by the time one got to 30 MHz.  As indicated, the use of thicker insulation (e.g. PTFE versus enamel) reduced this loss somewhat, but using the smallest wire on hand with the only available 75 mix toroid, too few turns could be wound to afford the needed inductance for the desired low frequency respons:  The best-results with the materials on-hand were obtained by simply laying the "bifilar" windings parallel to each other.  In this case, 24 AWG enamel wire was used, a compromise between lower skin-effect losses and the ability to fit the required number of turns on the FT-50 core.

Comment:  There are other splitter topologies available that have their own sets of advantages and disadvanges.  While some of these may be discussed in (a) future article(s), they are beyond the scope of this article - which is the construction of a very simple, straightforward device that is suitable for the task at hand.

Conclusion:

If one needs a very wide-range splitter for broadband receivers that cover from LF through HF - such as some modern "Direct Sampling" SDRs (e.g. the KiwiSDR) there are some commercially-available devices that may be found that will work well - if you can find them surplus, or are willing to pay for them.  If you are willing, a perfectly suitable device may be constructed inexpensive using a minimal complement of components.

Figure 8: 
The as-built 4-way splitter. capable of useful operation from below 20 kHz to above 30 MHz.
As described in the text, the cores are FT50-75 wound with 24 AWG wire, wired "dead bug"
inside a small die-cast aluminum box.  The resistors "R" and compensating capacitors "C"
may be easily seen.  The bottom of the box and the lid (not visible) are insulated with a piece
of plastic tape - this this case, 1" (25mm) wide PET (Polyester) tape.  If I'd had some on hand,
I would have wound the transformers on slightly larger toroids to spread out the windings a bit.
Click on the image for a larger version.
* * *

This is a follow-up of a previous article, "Characterizing the Mini-Circuits ZFSC-4-3, ZFDC-20-3, ZFSC-4-1-BNC+ and ZFSC-2-1+ well below their designed frequency range" - link.



Stolen from ka7oei.blogspot.com


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Wednesday, November 6, 2019

Characterizing the Mini-Circuits ZFSC-4-3, ZFDC-20-3, ZFSC-4-1-BNC+ and ZFSC-2-1+ well below their designed frequency range

Figure 1:
The collection of devices to be tested - plus a few 50 ohm terminators.
Click on the image for a larger version.
Note: 

There is a follow-up article, "Homebrew Construction of 2 and 4 port splitter-combiners for the LF/MF/HF frequency range" link.


Rummaging through a box of RF stuff I ran across several multi-port devices made by Mini-
Circuits Labs that I'd picked up over the years - typically at amateur radio swap meets.

The "official" specs of these devices are easy to find (at least for the newer "plus" versions) but what if, like me, one was interested in using them at frequencies below their official design specs - such as the lower amateur bands, including 80, 160, 630 and 2200 meters?  How much "extra" design margin was built into these device?

Wielding my DG8SAQ Vector Network Analyzer, I decided to find out.  For these measurements I limited the range to between 10 kHz and 60 MHz.  I also built several homebrew versions to see if I could, for little cost, come up with suitable versions of my own - and these are described in the follow-up article linked at the top of this page.

Comment:
All of the devices described here could also be used to combine signals from multiple sources.  Unless the signals being combined are "phase coherent" (e.g. from the same signal source) the insertion loss will be the same as that in splitter operation.  They will be referred to only as "splitters" in this article to minimize clutter.

Figure 2:
 Insertion loss of the ZFSC-4-3 from 10 kHz to 60 MHz.
Even though the "official" low-frequency specification is 10 MHz,
it should be quite usable on 160 meters (down to at least 1.8 MHz).
Click on the image for a larger version.
ZFSC-4-3 four-way splitter:

This device, equipped with BNC connectors, has an "official" frequency range of 10-300 MHz (the currently-offered "plus" version has the same ratings), splits the signal 4 ways with a theoretical insertion loss of 6 dB, but practically speaking, the actual loss is rated as being closer to 6.4 dB over the lower end of the design range.  Although this device - and others below - are billed as a splitters, they may be used to combine disparate signals from multiple sources onto a single line with the same amount of insertion loss.

Figure 2 shows the measured insertion loss over the range of 10 kHz to 60 MHz.

Figure 3:
 Isolation of the ZFSC-4-3 from 10 kHz to 60 MHz between ports 1 and 2.
Click on the image for a larger version.
This shows us that down to about 1.8 MHz (160 meters) that the insertion loss (blue trace) is only slightly (0.15dB) higher than the rated specs - and the Smith chart (red trace) is also reasonably well-behaved.  The next marker to the left (#3) is placed at 100 kHz and we see that the insertion loss is closer to 9 dB and that the impedance has dropped to around 12 ohms - getting worse at 20 and 10 kHz where the losses are 20dB or more and the measured impedance is only a few ohms.

What this tells us is that this device is likely to be useful down to about 500 kHz, below which point the insertion loss and impedance mismatch start to become significant - likely due to the fact that the intrinsic impedance of the ferrite devices within the splitter has dropped too low at these frequencies to remain "transparent".

Figure 4:
 Isolation of the ZFSC-4-3 from 10 kHz to 60 MHz between ports 1 and 3.
Click on the image for a larger version.
Figure 3 shows the port-to-port isolation between ports 1 and 2 and the scene is similar:  The insertion loss curve is pretty flat to about 500 kHz where it starts to vary and much below 100 kHz, the isolation seems to increase, but this correlates to the insertion losses.

Figure 4 shows the port-to-port isolation between ports 1 and 3.  This is different from that in Figure 3 because a 4-way splitter actually consists of three two-way splitters:  One to split two ways, and this path is then split two more ways with ports 1 and 2 on one splitter and 3 and 4 on another - and cross-coupling to the "other" splitter is apparently not as good at frequencies below the design.

It is worth noting that all of the above measurements are contingent on all ports "seeing" a 50 ohm source and load - either from the instrument itself doing the port-to-port measurements, or by terminating the "unused" ports (e.g. those not involved in the measurements) with known-good 50 ohm loads.  It is likely that real-world devices (antennas, receivers, amplifiers, filters) connected to any splitter will not have as good a return loss (effectively, VSWR) as a load and this will affect the isolation and apparent insertion loss.

Despite what the "official" ratings say, this device would be suitable down to at least 160 meters (1.8-2.0) MHz and likely usable through the entire AM broadcast band and, possibly, the 630 meter band.
Figure 5:

Insertion loss of the ZFSC-4-1 splitter between 10 kHz and 60 MHz.
Click on the image for a larger version.

ZFSC-4-1-BNC+ four-way splitter:

This device, also equipped with BNC connectors, has an "official" frequency range of 1-1000 MHz, splits the signal 4 ways with a theoretical insertion loss of 6 dB, but practically speaking, the actual loss is rated as being closer to 6.4 dB over the lower end of the range.

Figure 6:
 Typical port-to-port isolation of the ZFSC-4-3 from 10 kHz to 60 MHz.
Click on the image for a larger version.
As Figure 5 shows, this device does a much better job at the low end of things than the ZFSC-4-3:  At 100 kHz, the insertion loss is only slightly (0.2dB) higher than at 1.8 MHz and Marker #3 at this frequency on the Smith chart shows a reasonable (approx. 1.5:1) VSWR.  By the time one gets to 20 and 10 kHz, the VSWR and insertion loss have risen - but not as bad as that of the ZFSC-4-3.

Figure 6 shows the typical port-to-port isolation (ports 1 and 2 in this case) showing that down around 100 kHz, the isolation has dropped to about 20dB - still reasonable, and comparable to the isolation to be expected at the high end (published specs, near 1 GHz) of the design frequency range.

Clearly, if one has the amateur 2200 and 630 meter bands in mind - or one is splitting signals above about 100 kHz to feed several receivers - this is a much better choice than the ZFSC-4-3.
 
Figure 7:
 Insertion loss of the ZFSC-2-1+ two-way splitter between 10 kHz
and 60 MHz.
Click on the image for a larger version.


ZFSC-2-1+ two-way splitter:

This device, equipped with BNC connectors, has an "official" frequency range of 5-500 MHz (the "plus" version has the same ratings), splits the signal 2 ways with a theoretical insertion loss of 3 dB, but practically speaking, the actual loss is rated as being closer to 3.3 dB over the lower end of the range.

Figure 8:
Port-to-port isolation of the ZFSC-2-1+ two-way splitter between 10 kHz
and 60 MHz.
Click on the image for a larger version.
Figure 7 shows the measured insertion loss and surprisingly, it looks quite good down to 100 kHz - probably due, in part, to the fact that unlike the four-way splitters, there is likely only a single ferrite device contained within to incur losses at the low end where it "runs out" of inductance on the transformer.  Down at 20 kHz the loss has gone up by about 2dB and the impedance is in the area of 20 ohms, but this device may still be fairly usable in some applications.

Figure 8 shows the port-to-port isolation and this remains above 20dB down to about 250 kHz, quickly dropping to about 14dB at 100 kHz.

What this tells us is that this device is still likely to be usable down to 100 kHz if one is able to tolerate a couple of extra dB of loss and only mediocre isolation.

Figure 9:
Insertion loss of the ZFDC-20-3 20 dB coupler from 10 kHz
to 60 MHz.  Because the "Couple" port is pulling a slight amount of
energy from the through line, a small amount of insertion loss
is to be expected.
Click on the image for a larger version.
ZFDC-20-3 20dB directional coupler:

This device is not a splitter, but rather a device designed to directionally "siphon" a small amount of signal from the "through" line - but do this only in one direction.  This device is typically used to sample (with 20dB of attenuation) a signal on a given line, or if turned around to couple in the opposite direction it can insert a signal on this same line.  A common application of this device is to measure return loss (or VSWRm using a pair of these devices), allow non-intrusive monitoring of signals on a cable and it can be used to insert a signal on that same line - say for receiver sensitivity testing - on a cable that cannot be interrupted.  Unlike a splitter, connecting/disconnecting a device on the "Couple" port will have a very small effect on the through-signal.

Figure 10:
Forward coupling loss of the ZFDC-20-3 20 dB coupler from 10 kHz
to 60 MHz.
Click on the image for a larger version.


The "official" specs of the ZFDC-20-3 indicate a frequency range of 200 kHz to 250 MHz, but one can see in Figure 9 that the insertion loss is well below 1 dB down to around 20 kHz - although the VSWR at this frequency climbs to nearly 3:1:  At 50 kHz, the insertion loss is still only about 0.25dB and the VSWR is about 1.5:1 - still within the usable range for applications that can tolerate a small amount of degradation.

On the sample port we can see on Figure 10 that the coupling is ruler-flat down to at least 100 kHz and still staying within 1dB of the nominal value down to 10 kHz - but one should keep in mind the fact that the insertion loss and the varying impedance will likely affect the through-line's signals below around 50 kHz.
Figure 11:
Reverse coupling loss of the ZFDC-20-3 20 dB coupler from 10 kHz
to 60 MHz.  Because the coupling is 20dB in the forward direction,
the attenuation values depicted in the above graph should be reduced
by that amount.  The "bump" at the extreme low end is an artifact
of the configuration of the test instrument.
Click on the image for a larger version.

Figure 11 shows the "reverse" coupling loss (e.g. "directionality").  Ideally, no signal should be detectable when the "load" is a perfect, non-reflective 50 ohms but due to imperfections in the load, device, cabling and measurement will reduce this.

This shows that the absolute directionality+coupling exceeds about 60dB (about 40dB of directivity compared to the "forward" coupling) at all frequencies below 60 MHz down to about 20 kHz:  Values below about 70dB (the "floor" between 20 kHz and 10 MHz) are representative of the limits of the test instrument and its configuration so they may actually be greater than this.  Below about 15 kHz, the "bump" is mostly due to measurement artifacts - but this still indicates that the relative directionality is at least 30dB.

These measurements indicate that this device is usable down to 50 kHz with only minor degradation, and would probably work down to 25 kHz in applications where one can tolerate a bit of extra insertion and return loss.

Final comment about the Mini-Circuits devices:

In reviewing the above tests, it would appear that these Mini-Circuits four-way splitters and the directional coupler are generally useful down to about 1/10th of their "official" low frequency rating and that down to 1/5th of their low-frequency rating, they more or less meet their "official" specs.


Follow-up article:

I have built several homebrew versions of 2 and 4 way splitters to see if I could, for little cost, come up with suitable versions of my own that will work from below the LF range through HF - and these are described in this article:  "Homebrew Construction of 2 and 4 port splitter-combiners for the LF/MF/HF frequency range" link.

* * *

Stolen from ka7oei.blogspot.com


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