here - Mini Circuits

James Hontoria, W1JGH
[email protected]
A 10 MHz to 6 GHz Power Meter
This power meter, based on a Mini-Circuits ZX47 power detector,
gives a direct display of –55 to +10 dBm power levels.
I was building the Modularized Spectrum
Analyzer described by Scotty Sprowls.
For detailed information about this spectrum analyzer, see www.scottyspectrum
analyzer.com. I ran into a problem when I
needed to align the analyzer. We are talking here about frequencies in the low gigahertz range. My frequency meter goes up
to 3.5 GHz and would give a frequency
reading but no indication of the power level
involved. My 100 MHz scope couldn’t cope
and was useless. I needed two kinds of measurements:
• Relative ones: Am I getting any gain or
loss? How much? Is the signal getting from
point A to B?
• Absolute ones: Am I getting the
10 dBm I need from the phase locked oscillators (PLOs)? Remember that when making
absolute measurements a sine wave shape is
assumed. Also, all of the power coming out
of the device must be measured: placing the
probe in parallel when the device is delivering power to another device will not measure
the true output. Most likely, and assuming
50 Ω impedances, it will measure 50% of the
power. Use a pigtail as shown attached to the
meter in Figure 1.
A Big Problem
With tiny (and I mean tiny) surface mount
components, taking your eyes from the circuit to glance at a meter a foot or two away
may result in the measuring probe slipping
away, with disastrous effects; if not to the
electronics, perhaps to yourself due to the
adrenaline jolt. When measuring voltages I
could bring my handheld DVM very close to
the point of measurement to see the results,
but not my heavyweight HP 435B power
meter. I needed a hand-held device with
local readout. This is particularly important
in today’s crammed circuits where you don’t
dare to glance away from the point of mea-
Figure 1 — The finished assembled power meter.
surement for fear of the probe slipping.
The solution
I was looking for a way to enhance the
“Pocket dBm RF Power Meter” by Steve
Whiteside, N2PON in the August 2008
issue of QST, so it would measure into the
gigahertz range. During that search I discovered the Mini-Circuits power detectors. See
Figure 2 — A Mini-Circuits ZX47 –40+ power
detector module.
Reprinted with permission © ARRL
Figure 2. The Mini-Circuits ZX47 power
detectors measure RF power from 10 MHz
to 8 GHz and, depending on the detector
chosen, –50 dBm to +15 dBm, displaying
the results directly in dBm. This is especially
convenient because with its small size, the
readout can be at the place of measurement.
These devices are very linear, have a wonderful dynamic range and are tiny. Besides,
their data sheets include response curves that
allow for a close calibration without the need
for an external reference. Figure 3 shows the
output voltage versus input power response
curves for the ZX47 –40+ power detector.
I ordered one of them and ran a few tests
to verify how close the response was to the
published curves and found a general agreement of between 1 and 2 dBm. The detectors
are not cheap (about $90 each) but they beat
by a mile (and in some cases parsecs) the
cost of commercial units.
Among other things, the combination
QEX – July/August 2011
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Figure 3 — This graph shows the ZX47 –40+ power detector output voltage versus input
power at 25°C. This graph is reproduced from the Mini-Circuits data sheet for the detector.
of a VFO at 1013.3 MHz and this meter
allowed me to set up the spectrum analyzer’s
cavity band pass filter to a loss of –10 dB in
no time flat.
Mini-Circuits offers four detectors in
its ZX47series. The linear span is approximately as follows :
Model 60: –55 to + 0 dBm
Model 55: –50 to +5 dBm
Model 50: –45 to +10 dBm
Model 40: –40 to +15 dBm
These ranges are good up to 6 GHz, but
beyond that the range is smaller. Their output
voltage is 0.6 to 2 V. Since its high power
range may be increased by using an attenuator, my favorite is Model 60.
The schematic shown in Figure 4 is quite
simple: one potentiometer sets the slope and
the other sets the intercept of the response
curves. Since — up to 6 GHz — the linear
portions are essentially parallel, the slope pot
is set once and left alone. As Figure 3 shows,
the 8 GHz output voltage curve is quite
noticeably different than the lower frequency
curves, and would require a different calibra-
Figure 4 — The schematic diagram of the power meter shows how simple this circuit is. Potentiometer R7 sets the detector slope for the
LCD voltmeter and R8 sets the display intercept. Once the slope is set no further adjustments are needed to that control. The intercept
potentiometer is adjusted for the appropriate frequency range.
Parts List
C1, C2
C3, C4
Enclosure
Lascar LCD
LED
Power Detector
Power Jack
Resistors
R1
R2
18
10 µF, 16V SMT 0805 Ceramic
(Mouser 81-GRM21BR61C106KE15 or equiv)
1 µF, 16V, 5% SMT 0805 Ceramic
(Mouser 81-GRM21BR71C105JA1K or equivalent)
Hammond 1590A (Mouser 546-1590A)
Lascar EMV1125 LCD voltmeter (Jameco 2113201)
Panasonic bi-color, LN11WP23 (Digikey P391-ND)
Mini-Circuits ZX47 –40+
Switchcraft 722A EG2209A (Jameco 281851)
SMD 0805, 1%
576 Ω
374 Ω
QEX – July/August 2011
R3
R4
R5
R6
R7
R8
SW1
SMA 90°
U1
U2
27 kΩ
2.21 kΩ
1.2 kΩ
0 Ω (jumper, if needed)
50 Ω (Mouser 652-3314G-1-500E)
(Digikey 3314G-1-500ECT)
1 kΩ (Mouser 774-296UD102B1N)
DPDT E-Switch EG2209A (Mouser 612 EG2209A)
Amphenol 132112 male/female elbow (Mouser 523-132112)
78M05 DPAK_3 (Mouser 863-MC78M05CDTG)
Charge pump voltage converter,
Maxim ICL7662EBA+ (Digikey)
Reprinted with permission © ARRL
(A)
tion. The intercept is a function of the frequency and is set at the time of calibration or
simply taken from the Mini-Circuits curves.
The user interface includes a Lascar EMV
1125 LCD digital voltmeter, a bicolor LED
(red when the switch is in calibration mode,
green when in measurement mode) and the
offset potentiometer. A calibration table is
pasted to the face of the box (not seen in any
of the pictures). The offset potentiometer is set
to the value in the table, which corresponds to
the frequency of the signal being measured.
The meter requires an external supply
from 12 to 20 V dc. Because of the sensor
current draw (about 120 mA), no attempt has
been made to use batteries.
Figure 5 depicts my original unit. The left
side of Part A has the 12 V jack. There was
a 7805 voltage regulator bolted to the box
floor underneath the circuit board and both
the regulator and circuit board were secured
by the screw visible at the top left corner of
the circuit board. The IC visible on the circuit board is a charge pump to get the –5 V
needed for the Lascar LCD voltmeter. I have
built a newer version and have moved all the
components to the printed circuit board. That
has simplified the wiring. Figure 6 is a picture
of the inside of the newer version.
Construction Notes
I used a Hammond 1590A cast aluminum
enclosure, and had to remove some material
from the corners to make room for the MiniCircuits sensor, as shown in Figure 7. I center punched the area and then used my drill,
being careful not to engage it and go through
the wall. The probe SMA hole offset is to
provide clearance for the LCD in the other
side of the box. Not shown here, there was a
hole drilled on the box “floor” to secure one
of the legs of the sensor.
Look again at Figure 6. Some versions of
the 7662 charge pump require that the LV pin
(pin 6) be tied to ground to ensure a negative
(B)
Figure 5 — My original unit. The left wall in Part A has the 12 V jack.
There is a 7805 voltage regulator bolted to the box floor underneath
the circuit board and secured by the screw at the upper left corner
which holds both the 7805 and the circuit board in place. The IC
visible on the circuit board is a charge pump device to get the –5 V
needed for the LASCAR LCD voltmeter. The latest version of the
meter has moved all the components to the circuit board, which has
simplified the wiring. Part B shows the front of the box, with the LCD
voltmeter, the Calibrate/Measure switch, the intercept potentiometer
control and the bi-color LED.
Figure 6 — A look inside the newest version of the meter. The trimmer is the slope
setting and the miniature potentiometer is for the intercept setting. Note the glob
of glue on the right securing the board to the detector.
Figure 7 —I used a Hammond 1590A cast aluminum enclosure and had to remove
some material from the corners to make room for the Mini-Circuits sensor. I center
punched the area and then used my drill, being careful not to engage it and go
through the wall. The probe SMA hole offset is to provide clearance for the LCD in
the other side of the box. Not shown here, there was a hole drilled on the box “floor”
to secure one of the sensor legs.
Reprinted with permission © ARRL
QEX – July/August 2011
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5 V output of the same level as the positive
input. Version 1.3 of the circuit board, which
is the one shown in Figure 6, requires installing a wire jumper to ground. Circuit board
version 1.4 has provision for a 0 Ω resistor
(R6) if needed.
Figure 8 shows the Lascar LCD voltmeter
control board on the inside of the Hammond
project case, with the circuit board and power
detector ready to be installed. Notice that the
wires from the display feed through a hollow stud on the back of the display, and they
attach to a row of holes along the top of the
control board and to the switch and R8 on the
circuit board.
Figure 9 shows the bottom of the circuit board, with a 90° angled SMA male to
female connector between the detector output and main circuit board. I used a ¼ inch
length of 141 coax between the SMA female
end and the circuit board. Do not solder the
coax to the SMA connector until you are sure
everything fits correctly.
Figure 10 is the circuit board artwork.
Note that this is a double sided circuit board,
with the traces on top of the board outlined in
black and traces on the bottom of the board
shown in lighter gray.
The circuit board file was created using
ExpressPcb. Because ExpresPcb requires
a minimum board size of 3.8 × 2.5 inches,
builders may want to join with a few others
to make the price more attractive (a good club
project?) or to include boards for other projects with the order. An alternative is to redo
the design using Eagle.
A color copy of this artwork, along with
the ExpressPCB file is available for download from the ARRL QEX files website:
www.arrl.org/qexfiles. Look for the file
7x11_Hontoria.zip.1
cally short GND to V+, damaging the meter.
Figure 11 shows the LCD voltmeter control
board, with the connections to the display.2
The meter is thus operated from a ± 5 V
split-rail supply. In order for the LCD to
read 2 V full scale the Ra (910 kΩ) and Rb
(100 kΩ) resistors must be installed and link
La must be cut. To set the decimal point so
that the meter reads directly in dBm, the decimal link DP1 must be shorted out.
Last, but not least, measure the input
voltage at IN-HI with an accurate DMM
and adjust CAL for the same reading on the
Lascar display.
Preliminary Calibration
The preliminary calibration uses the
Mini-Circuits data sheet curves. A more precise calibration will require comparison with
another power meter. The following is how
the preliminary calibration is performed.
If using the Lascar EMV1125, set it up
in accordance with its data-sheet and the
instructions above. If using any other meter,
Figure 8 —The LCD voltmeter comes with fairly long wires, which I used to connect it to the
circuit board.
Drilling the Enclosure Cover
The potentiometer requires a 5⁄16 inch
hole. The LED I used requires 3⁄16 inch and
the switch needs a ¼ inch hole for the shaft.
Remember: “Measure thrice, drill once.”
Refer your measurements to the centers of
the enclosure screw holes, not to its walls.
Then, transfer those measurements to the
cover.
Setting Up the LASCAR LCD
Voltmeter
The EMV1125 doesn’t require a split rail
power supply. It can happily run from a single rail. Under these conditions, however, the
signal must be left floating (totally isolated)
from the power supply and link L2 ties the
floating signal (INLO) to a reference voltage
(Com, held 2.8 V below V+). Since in the
power meter the signal is not floating, link
L2 must be cut. Leaving this link will basiNotes appear on page 21.
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QEX – July/August 2011
Figure 9 — I had to insert a ¼ inch length of 141 coax into right angled SMA connector, to
provide clearance between the detector and the circuit board. The coax (shield and center
conductor) should not be soldered to the SMA until the very end.
Reprinted with permission © ARRL
Table 1
Calibration Factors
Frequency Range
Calibration Factor
MHz
10
47.4
50
43.9
100
47.9
200
44.2
300
44.1
400
43.8
500
44.5
600
44.3
700
46.1
800
44.0
900
52.0
1000
49.9
1050
48.1
(My signal generator does not go any
further)
set it up to display 2 V, but move the decimal
point to one decimal digit.
Refer to the schematic diagram in
Figure 4. It refers to the designation of the
potentiometers. This preliminary calibration
procedure is based on setting the slope with
R7 and the intercept with R8.
1) Set the switch to “Calibrate” position,
to ground the EMV 1125 input line; the bicolor LED should turn to red. Do not connect
any signal to the RF input of the ZX47. Turn
on the power supply.
2) Use a DMM to measure the voltage
at the ZX47 output (the top of resistor R1).
Suppose you measure 2.17 V
3) Adjust the slider of the slope potentiometer R7 (the small trimmer on the circuit
board) and measure the voltage at the arm.
For this example you should measure 2.17 V
× 0.4 = 0.868 V.
4) I used the Model 40 Mini-Circuits
detector, so I used the curves shown in Figure
3, reproduced from Mini-Circuits data sheet.
Use a signal generator to inject a 10 MHz
signal to the ZX47 –40+ RF input. Ideally,
the signal level should be in the center of
the range, which for the Model 40 is around
–15 dBm. In any case, do not exceed the
upper limit for the ZX47 detector you are
using. Read the voltage at the input side of
R1. Suppose you read 1.38 V.
5) Look at the Figure 4 graph. The thin
black line corresponds to 10 MHz and 1.38 V
corresponds to –14 dBm.
6) Set the switch to the “Measure” position; the bicolor LED will be green. Adjust
the intercept potentiometer (R8) until you get
the same dBm reading on the Lascar display.
Return the switch to “Calibrate” and make
a note of the reading on the display. That is
your set point at 10 MHz.
7) Set the switch to “Measure” again, and
you are ready to start measuring power in
the 10 MHz range. You can now experiment
Figure 10 — This control board is part of the Lascar voltmeter. The wires from the display
connect to the top row of holes.
Figure 11 — This is the
circuit board artwork. The
board is 2.4 × 1 inch.
with different frequencies and levels. For
example, my set point at 50 MHz is 44.7, and
at 1000 MHz it is 43.8. These set points are
the equivalent of calibration factors used in
other instruments. Table 1 shows the calibration table for my meter.
Background
With the Model 40, the response equation
at 10 MHz is: dBm (10 MHz) = 42 – (40 × V)
For example, a sensor voltage output of
1.3 V corresponds to a power input of
42 – (40 × 1.3) = 42 – (52) = –10 dBm at
10 MHz (the thin black line on Figure 3). For
other frequencies, the response equations are:
dBm (1000 MHz) = 41.7 – (40 × V)
dBm (2000 MHz) = 39.25 – (40 × V)
dBm (6000 MHz) = 44.7 – (40 × V)
dBm (8000 MHz) = 52 – (40 × V)
Since the lines are essentially parallel
(with the exception of the 8 GHz line) the
slope has been set as a constant at 40. The
intercepts are frequency dependent, howReprinted with permission © ARRL
ever. Based on the Mini-Circuits graphs, the
Model 40 power sensor should provide fairly
close results to the above formulae between
–35 and +15 dBm.
Jim Hontoria, W1JGH, received his first
Amateur Radio license in Spain at age 16.
Residing in New York since 1979, he is a deep
water sailor by inclination and a (now semiretired) mining engineer by profession. He
earned a US Amateur Radio license in 2006
and became an Amateur Extra in 2007. His
interests include all digital modes and radiorelated instrumentation. Jim is an avid experimenter and builder.
Notes
A color version of the circuit board pattern,
along with the ExpressPCB circuit board
file is available for download from the ARRL
QEX files website: www.arrl.org/qexfiles.
Look for the file 7x11_Hontoria.zip.
2
Figure 10 is from the Lascar Electronics
(4258 W 12 Street, Erie PA 16505) EMV
1125/2 data sheet. Displays are available
from Jameco Electronics.
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