MFJ 259B Analyzer Calibration
This is an MFJ procedure that does not contain any
information that would not be handed out by them. It is easy-access to a test
procedure, that is all it is. It is a shortcut to help you.�
This information is here only because it is the correct
way to calibrate the MFJ-259B analyzer. MFJ's first priority is making sure
people who can not send units back to MFJ or who want to verify calibration with
a correct reviewed and edited procedure have something easy to access. MFJ gets
all the credit for this procedure, no one else.
It is best that no one copy this, and start handing it out
in mass. The only reason for this is there should be a point of control of
information, so it can be corrected as errors are found.
Common Problems
This family of analyzers is dc-coupled from the bridge to the antenna port. The bridge detectors are NOT
frequency selective, and respond to anything from minor dc offsets through microwave
signals. This causes a potential problem if there is any voltage appearing
across the antenna port, from dc through microwave. (This is also true for competing
analyzers from other manufacturers.)�There are multiple reasons why, at
the time of design, these units were dc coupled with broadband detectors.
Hopefully someday a higher cost-design with selective detectors will become
available, but for right now this is all that is available for amateur use.�
Because the detector is broadband, and because it is dc
coupled to the antenna, any external voltage across the input port causes
measurement errors. It is the accumulated
voltage of multiple sources that is most important, not the strength of any individual signal.
Because of that, large antennas should be tested at times when propagated
signals in the range of the antenna's response are at minimum strength.�
A definite RFI improvement occurs with a bandpass
filter, but multiple-section bandpass filters cause impedance measurement problems.
Multiple-section filters behave like transmission lines of random line
impedances, loss, and lengths as frequency is varied. The best solution is to
use a single-stage bandpass filter
and dc isolation on large arrays or with long feedlines. I often use a good
1:1 isolation transformer for measurements, and often find a parallel L/C
filter (like the MFJ-731 Filter) useful.�� �
The detector diodes clearly stand out as the most easily damaged
devices in the analyzer. If you have a sudden problem, it is most likely a
defective detector diode.�
In order for the detectors to be accurate within a
fraction of a percent (one bit), detector diodes must have very low
capacitance and a very low threshold voltage. This means the diodes, through
necessity, must be low-power zero-bias Schottky microwave detector diodes. The
same characteristics that make them accurate and linear cause the diodes to be
especially sensitive to damage from small voltage spikes. ALWAYS
discharge large antennas before connecting them to the analyzer! Never apply
external voltages greater than 3 volts to the antenna port!
How This Unit Works
This is a
rough summary of how this unit works:
The MFJ-259B, and other digitized MFJ antenna analyzers,
compare three major voltages in a 50-ohm bridge circuit. They are:
Vz= Voltage across the load. This voltage is called�
Z in the alignment display menu
Vr= Voltage indicating bridge balance. This voltage
is called R in the alignment display menu
Vs= Voltage across a 50-ohm resistor between the RF
source and the load. This voltage is called S in the alignment display
menu�
�All voltages are converted through an eight-bit A-D
converter to a 256-bit digitized output with a test-display range of 0-255
bits. By knowing the ratio of these voltages, as compared
to the regulated RF source voltage, many different load parameters can be
calculated. An antenna analyzer could calculate everything (except sign of
reactance) from measuring only Vs and Vz, but at certain impedances any small error in
either Vs and Vz becomes critical. This is especially true when voltage is
digitized into a 256-bit format (~0.4% steps). At certain impedances, an almost immeasurable�
voltage change will cause a sudden large jump in the measured impedance
parameters.
To reduce display impedance jumps, SWR is weighed into the
calculation of reactance and resistance at low SWR values. (An SWR
bridge is most accurate when the load is closest to 50 ohms, which is a
primary measurement area where� impedance measurements through Vz and Vs
become critical.) By factoring in a direct SWR measurement from an internal
bridge, the analyzer can
check and "correct" any small level errors in Vs or Vz. This reduces the
impedance jump that would occur with a one-bit jump in voltage. This also why bits
must be calibrated for near-perfect accuracy. a one-bit error can cause a
resistive load to appear reactive (the total of Vs and Vz must always be 255
bits or less for a load to be considered resistive).
Calibrating the MFJ-259B Antenna Analyzer
This
calibration procedure is the correct procedure for later MFJ-259B's. Disregard
any other information. Since MFJ-259B software has been changed under the same
model number, you may find some final performance
test steps not valid. These steps will involve parameters that do not appear
on the display.
Be sure you have printed a copy of the board layout
showing adjustment points, have read all this, and have suitable loads before
proceeding.��
Adjustments
This unit has tracking and gain adjustments for Vz, Vs,
and Vr. Tracking is set at low voltages (low bits). Gain is set at high
voltages or bits. Together they make the detector voltage output closely track
the actual RF voltage.�
This unit also has meter calibration adjustments. The
analog meters almost certainly suffer from some scale linearity problems, they
will be somewhat less accurate than the digital display. These adjustments only affect
analog meter readings. The meter adjustments
do not affect the display.
Quiescent current (bias) in the RF amplifier section is
adjustable. This adjustment directly affects output signal harmonic content.
Harmonics are worse with low supply voltages, and with low impedance loads. Be sure
you check the harmonics as outlined below, with a 1/4 wl open-circuit stub!!
Excessive harmonics can cause severe errors in measurement of
frequency-selective loads, even when dummy-load SWR tests appear perfect. Loads most sensitive to harmonic-induced errors
include, but are not limited to, antenna tuners, tank
circuits, very short resonant antennas, and distance to fault and stub length
measurements. If you notice something "funny" going on with a stub
measurement, it may be a fault of incorrect bias.�
Warning: Never calibrate around a sudden
"problem" that appears. If a detector suddenly shifts voltage, the
problem is almost certainly a defective detector diode. If the meter is recalibrated
with a defective (leaky) diode, the meter will probably NOT track correctly with
frequency.
Alignment
Tools and
Equipment:
[� ] #2 and
#1 Phillips-head screwdrivers
[� ] Digital
meter or accurate analog meter for
checking supply voltage
[� ] Small
set of non-metallic alignment wands for coils, or small jeweler's screwdrivers
for controls�
[� ] Power
supply, regulated to 12-volts + - 5%
[� ]
General-coverage receiver with level meter or Spectrum Analyzer (these are
optional with additional work and use of a stub)�
[� ] ~10 MHz
1/4wl open-stub,�for example 15� good-quality
solid-dielectric RG-8, UHF connector at on end, open on other (not needed with
analyzer or receiver)
[� ] 2.2-ohm 1/4 or 1/2 watt film resistor (not needed
with stub)��
[� ] Accurate
load set
to include:
A.����
Short
B.����
12.5-W
load
C.���
50-W
load
D.���
75-W
load
E.����
100-W
load
F.����
200-W
load
Note 1:
Loads must be constructed using physically small 1% carbon-film
resistors.�
-
DO NOT use large resistors. Acceptable results will be obtained when load resistors
are mounted in the very bottom of a UHF-male connector.�
-
The ideal
load resistors are surface-mount precision-resistors, but other styles will
work. It is acceptable to parallel multiple resistors to obtain low
resistances, but don't series connect more than two resistors!�
-
Never use physically
large resistors, such as 1-watt or larger resistors, unless you are absolutely
positive they are composition-types (very rare).�
-
Since the loads are used to
set the number of bits in critical calculations, the maximum reactance error
will always be worse than the percentage of resistive load error. A one bit
error in calibration (~ .4%) can shift a resistive load to read reactance.
Quick-connect loads can be made with surface mount� resistors
on a BNC male chassis mount connector with the bayonet removed. This makes
a �quick connect� connector that will slide directly into a type-N female.��In this
case, use a good UHF to BNC female adaptor for the 259 units. With a 269, the
load will plug directly in to the N female.�
Note 2: The power source should be the LOWEST expected
operating voltage. DO NOT use a standard "wall-wart" or batteries! You can
reduce voltage from a conventional 13.8v regulated supply by adding a few
series diodes. Silicon diodes will normally drop about 0.6volts or so per
diode. Three or four diodes will reduce place the voltage below 12 volts.
WARNING: The MFJ-1315 AC adapter or other
"wall-warts" should NOT
be used to power the unit for most alignment steps.�
Step 1
Visual
Inspection: Before, during, and after calibration, be mindful of physical condition.
Watch for missing or loose hardware. Do not tug, stress, or repeatedly
flex leads, or carelessly
flop or toss things about. Keep your bench clean. Follow these rules the entire time
you have the unit apart!
Step 2
Battery
Tray Removal: This step provides access to trim-pots and most inductor
adjustments.
[� ] Remove
last two batteries at each end of the tray.
[� ] Remove
two screws (right side) and extract the tray.
[� ] Always
position the battery tray to minimize strain on wires.�
Refer to the
board layout pictorial for specific control
locations.
Step 3
Band Overlapping: Each
band should overlap the next by a small amount to ensure gap-free coverage
from 1.8 MHz to 170 MHz. While viewing the LCD
Frequency Display, wiggle the bandswitch from side-to-side gently. Watch
for any display or meter dropout. Check each band as follows:
[� ] 114-170
MHz: Oscillator tunes from below 114.0 MHz to above 170.0 MHz. Check tune
for dead spots.
[� ] 70-114
MHz: Oscillator tunes from below 70.0 MHz to above 114.0 MHz
[� ] 27-70
MHz: Oscillator tunes from below 27.0 MHz to above 70.0 MHz.
[� ] 10-27
MHz: Oscillator tunes from below 10.0 MHz to above 27.0 MHz.
[� ] 4-10
MHz: Oscillator tunes from below 4.0 MHz to above 10.0 MHz.
[� ] 1.8-4
MHz: Oscillator tunes from below 1.8 MHz to above 4.0 MHz. Check tune for
dead spots.
While verifying overlap, check at least the lowest and
highest bands carefully for dead spots. The LCD
Display will indicate 000.000MHz if a dead spot occurs. Dead spots
generally indicate a defective tuning capacitor (TUNE).�
If you find the switch causes a dropout the switch
may have dry or dirty contacts, or poor solder joints. Check the solder joints first.
If you must clean and lubricate the switch, be aware it is a difficult task. The entire
board needs to be lifted from the case front. Dirty band-switch contacts may be restored with
spray tuner
cleaners. The best place to spray the switch is from
the front side (shaft side), right below the nut. You must remove the switch
indexing tab retainer nut and the
metal switch retainer (stop)
under the nut. Be sure the stop goes back exactly as removed.
To correct overlap problems, locate and retune the appropriate VFO
coil (see Pictorial for coil locations). Note that L1-L4 are slug-tuned and
require an insulated hex-head tuning wand. If you use the wrong size wand or a
worn wand, it will break a slug!�
Inductors L5 and L6 are located on the
component side of the board and are compression-tuned (press turns closer
together to lower frequency or spread apart to raise frequency). Make only
very small corrections--especially to L5
or L6--and recheck the band you are adjusting. You should also check the next
lower band after each adjustment to ensure that the lower band hasn't
moved excessively.
Important
Warning: VFO coils MUST be aligned from highest frequency to lowest
frequency. The next higher range affects next lower band the greatest amount.�
Do not attempt VFO coil adjustment unless you are experienced working
with VHF-LC circuitry or complex alignment procedures.�
Step 4
Harmonic Suppression/ Bias: Connect the analyzer exactly as
shown below.�
- �The impedance of the cable to the measurement device should match
the impedance of the measurement device.
- �The "T" must be connected either directly to or placed
within a few inches of the analyzer.
- �The power source must be the lowest expected operating voltage.
- �The measurement device must be well-shielded, and not pick up any
substantial signal from the analyzer when the "T" is
disconnected from the analyzer.
Step 5�
Harmonic Suppression
(bias
R89):
This adjustment reduces oscillator harmonics. Harmonics will cause incorrect
readings under some load conditions.�
WARNING:�
Incorrect
adjustment of R89� will NOT show when checking with resistive dummy loads!!!
The unit will appear to calibrate correctly, but will produce errors in
stub length, distance-to-fault, and other frequency selective functions.
When R89 is set
properly, harmonic suppression of �30 to �35dBc should be possible across
most of the analyzer�s tuning range. This particular adjustment must be made
at the lowest expected operating voltage. Proper alignment requires a 12.0-volt
regulated supply as a power source. NEVER use an AC adapter or any supply
voltage higher than 12-volts when making this adjustment.�A calibrated spectrum analyzer works best for monitoring harmonic
output, but a well-shielded general-coverage receiver with signal-level meter
will also work.�The receiver MUST
be "T'd" into the analyzer just as the spectrum analyzer is, and the Tee
and resistor must be located at the analyzer connector.�If
you do not have a good-quality receiver or spectrum� analyzer, use the test mode of the
analyzer with a stub. Watch MFJ analyzer test-mode Vz. Test-mode Vz will roughly indicate
total harmonic voltage when the analyzer is set at the stub's exact resonant
frequency. Entering the test mode is described in Detector Calibration (Step
6).� ���
[� ] a. Install
either a 15� RG-8 open stub, or resistor and measurement device, and tune analyzer to approximately 10 MHz.�
[� ] b.
(stub and internal Vz use only) Observing Vz on the data
display (analyzer test mode), adjust frequency until the lowest fundamental
output reading (or lowest impedance) is obtained. You should clearly see the
MFJ analyzer's fundamental frequency
output voltage (Vz) go through a deep null.�
[� ] c. Observe the analyzer
frequency reading. This is the approximate resonant frequency of the stub, and
the test frequency.�
[� ] d. Without
changing the analyzer test frequency setting, observe the second
harmonic level. This harmonic will be at twice the MFJ analyzer frequency counter reading..
[� ] e. Adjust R89
for lowest 2nd harmonic meter reading on the receiver, lowest Vz test-menu reading,
or lowest harmonic level� on the spectrum analyzer. Be SURE the fundamental
frequency level remains nulled in the analyzer.�
WARNING:� Always repeat steps
(b) through (e) at least one extra time when relying on display Vz. The original null point of
any stub will shift if there is a substantial reduction in harmonics after R89
is adjusted. The original stub frequency, as observed at (c), will probably change slightly. It is NOT necessary to recheck
when doing a resistor load test with a good-quality spectrum analyzer
or receiver. With a resistor, exact test frequency is NOT critical.
NOTE: If you have a poorly performing spectrum
analyzer or receiver with limited dynamic range, use a stub with the spectrum
analyzer or receiver instead of a 2.2 ohm resistor. If you have a reasonable
quality spectrum analyzer or receiver (at least 50dB dynamic range) use a 2.2-ohm
non-inductive resistor in lieu of the stub, resistor adjustment is easier and
more accurate.
Detector
Calibration
Step 6:�
This critical sequence calibrates A-D conversion for various load conditions. If you
know your unit has been tampered with, preset trim pots R88,
R89, and R90 to their center positions before continuing. If you find any
control bottoms-out in adjustment, you almost certainly have installed an
incorrect load or the analyzer has a defective detector diode.��
To prepare for detector tracking alignment, place the
analyzer in Test Mode. Entering test
mode may be tricky with some units, and it may take practice. To enter Test
Mode:
[� ] Turn
power off.
[� ] Hold
down MODE and GATE� buttons while restoring power.
[� ] As
display comes up, slowly (about 1 second period) rock between pushing the MODE
and GATE switches alternately (the
best method is to use two fingers, and rock your hand from side to side
between the two buttons)
[� ] Confirm
analyzer has entered test mode (it may take more than one try).
[� ] Using
the MODE button, advance display to
the R-S-Z screen (shown below).
Note: If you go past the R-S-Z screen, you can still
see R-S-Z by pushing and holding the MODE button.
�
 10.000
MHz
�����������������������������������������������
Rxxx����� Sxxx���
� Zxxx
 �
�
[� ] Tune
analyzer operating frequency to approximately 10.000
MHz
[� ] Leave antenna
connector Open
[� ] Set R72
for Z=255
[� ] Install
the Short
[� ] Set R73
for S=255
[� ] Install 12.5-W
load
[� ] Set R90
for Z=051
[� ] Set R53
for R=153
[� ] Install 200-W
load
[� ] Set R88
for S=051
[� ] Set R72
for Z=204
[� ] Install 75-W
load
[� ] Set R89
for R=051
[� ] Install 12.5-W
load
[� ] Reset R90
for Z=051
[� ] Set R73
for S=204
[� ] Reset R53
for R=153
[� ] Install 200-W
load
[� ] Reset R88
for S=051
[� ] Verify
or set Z=204
[� ] Install 75-W
load
[� ] Reset R89
for R=051
Important Note:
Small single-turn trimpots are touchy to adjust
and tracking settings are somewhat interactive. If specified readings aren�t
obtained on the run-through, repeat the sequence a second time (accuracy
counts). When the sequence is complete, turn power off to remove the analyzer
from Test Mode.
Be particularly mindful of the total bits of Vz and Vs. If the sum of
these bits ever exceeds 255 with a resistive load, the analyzer will indicate
reactance.��
Display
Test and Analog Meter
Calibration
Step 7:
This step sequence checks meter calibration and verifies accuracy
of the LCD Display information.
Remove and re-apply power and enter the Real-Imaginary impedance mode R-X.
Readings + or - 10% of reading or� + or - 5 ohms of display, whichever is
larger, are considered within design specifications. Typically digital
readings are almost perfect with proper detector calibration. Analog meter
readings may be outside that range, and as much as 20% off with some load
values.��
[� ] Install 75-W
load
[� ] Verify
reading of R= 75 X=0 on LCD Display (�10%)
[� ] Install 50-W
load
[� ] Verify
reading of R=50 X=0 on LCD Display (�10%)
[� ] Set R67
for reading of 50 on the Impedance Meter.
[� ] Verify
reading of 1.0 SWR Meter (no deflection).
[� ] Install Open
load
[� ] Verify
reading above 400 on Impedance Meter
[� ] Install 100-W
load
[� ] Verify
reading of R=100 X=0 on LCD Display (�10%)
[� ] Verify
reading of 100 on Impedance meter (approximate).�
[� ] Set R56
for a reading of 2 (2:1) on the SWR Meter
[� ] Install 12.5-W
load
[� ] Verify a
reading of 4:1 SWR on LCD display (3.8-4.2 good)�
[� ] Verify
reading of >3 (greater than 3:1)
on SWR Meter
[� ] Install 200-W
load
[� ] Verify
reading of 4:1 SWR on LCD display (3.8-4.2 good)
[� ] Verify
reading of >3 (greater than 3:1)
on SWR Meter
�
Capacitance Mode
Check
Step
8:�
�
If you have a few precision capacitors, you can verify the calibration
between the ranges of 100 and 5000 pF. Read the analyzer manual for details of
capacitor measurement.����
[� ] Install
no load
[� ] Set Mode
to Capacitance
[� ] Set VFO
to 70 MHz
[� ] Verify 4-6
pF reading on LCD Display
�Frequency Counter
Check
Step 9:
These steps verify accuracy of the counter. Note that the
counter�s clock isn�t user-accessible, so no adjustments will be made. To
conduct this test, use a general-coverage receiver in AM mode.
�
[� ] Tune in WWV
on 5.0,10.0,15.0, or 20.0 MHz (frequency with best reception).
[� ] Install
a short clip lead or wire in the analyzer�s Antenna
jack.
[� ] Turn on
the analyzer and zero-beat the WWV
signal as closely as possible.
[� ] Compare LCD
Display reading to the WWV frequency being used.
[� ] Verify
agreement is within �5
kHz.
Advanced Modes
Check
Step 10:�
This sequence verifies operation of the analyzer�s
advanced features. To enter Advanced
Mode menu:
[� ] Turn
unit off.
[� ] Hold
down the MODE and GATE switches while turning power on.
[� ] Verify
�Advanced� appears on the LCD
Display.
[� ] Install Open
load
[� ] Tune VFO
to >170 MHz (top end of coverage
range)
[� ] Verify Z
= <650 W
with (about) 90�
phase shift
[� ] Install
RG-8 open stub
[� ] Tune VFO
for minimum Z reading (around 10
MHz)
[� ] Verify Z-min
= 0 to 2 W
[� ] Install 50-W
load
[� ] Set VFO
to 1.8 MHz �
[� ] Verify Z
= 50 W,
q
= 0�,
and SWR = 1 (�10%)
[� ] Enter RL
Mode (return loss)
[� ] Verify RL
= >42 dB, r
= 0, SWR = 1
[� ] Enter Match
Efficiency Mode (skipping DTF Mode)
[� ] Verify ME
@
100%� (approximate)
[� ] Press
and hold MODE and GATE buttons
to restore Main Modes
[� ] Remove
load and verify Z = >650 on LCD
Display
Conclusion:
Step 11:
[� ]
Reinstall battery tray
[� ] Confirm
charger jumper is set for type of batteries used (disable for alkaline).
[� ]
Reinstall cover
�This completes calibration.
�
�
�
�
�
�
�
�
�
�
MFJ-259B Calibration Checklist
Make a Xerox
copy and check each box as you proceed down the calibration list.
�
Physical Condition
[� ]
Hardware, batteries okay
�
Harmonic Check
[� ]
Suppression -35 dBc or better
�
Overlapping
[� ] All
bands have sufficient overlap
�
Binary Cal: 10 MHz
[�
] Open
[� ] R72 for
Z=255
[� ] Short
[� ] R73 for
S=255
[� ] 12.5-W
[� ] R90 for
Z=051
[� ] R53 for
R=153
[� ] 200-W
[� ] R88 for
S=051
[� ] R72 for
Z=204
[� ] 75-W
[� ] R89 for
R=051
[� ] 12.5-W
[� ] R90 for
Z=051
[� ] R73 for
S=204
[� ] R53 for
R=153
[� ] 200-W
[� ] R88 for
S=051
[� ] Verify
Z=204
[� ] 75-W
[� ] R89 for
R=051
�
Analog Cal: 10 MHz, values �10%
[� ] 75-W
[� ] Verify
R= 75 X=0
[� ] 50-W
[� ] Verify
R=50 X=0
[� ] Set R67
for 50 on Imp Meter.
[� ] Verify
1.0 on SWR Meter
[� ] Open
[� ] Verify
>400 on Imp Meter
[� ] 100-W
[� ] Verify R=100
X=0
[� ] Verify
100 on Imp Meter�
[� ] R56 for
2 (2:1) on SWR Meter
[� ] 12.5-W
[� ] Verify
4:1 on LCD (3.8-4.2)�
[� ] Verify
>3 on SWR Meter
[� ] 200-W
[� ] Verify
4:1 on LCD (3.8-4.2)
[� ] Verify
>3 on SWR Meter
�
Capacitance Mode Check
[� ] Open
[� ] Set VFO
to 70 MHz
[� ] Set Mode
to Capacitance
[� ] Verify C@4-pF
�
Counter Check
[� ] Counter
Okay
�
Advanced Modes
[� ] Tune to
170 MHz
[� ] Open
[� ] Verify
<650, Phase @
90�
[� ] 3�
RG-58
[� ] Tune for
Z-min (@150
MHz)
[� ] Verify
Z= 0-2 W
[� ] 50-W
[� ] Tune to
1.8 MHz �
�
[� ] Verify
Z=50 W,
q=0�,
SWR=1
[� ] Advance
to Return Loss
[� ] Verify
RL=>42dB, r=0,
SWR=1
[� ] Advance
to Match Efficiency
[� ] Verify
ME @
100%
[� ] Restore
Main Modes
[� ] Open
[� ] Verify
Z=>650
�
End of Procedure
�
�
Pictorial Diagram of Analyzer Board
Locations for
trimpots and inductors
�
�
�
�
Loads Using Standard-Value Resistors
�
�
�
�
�
-
Install resistors all the way down in the connector, the goal is zero
lead length
.
- Use precision 1% carbon or metal film 1/8th-1/4 watt resistors
�
�
12.5W
= (4) 50-ohm or 15W
and 82W
in parallel
�����������������������������������
50W
= 49.9-ohm� or 100W
and 100W
in parallel
�����������������������������������
75W
= 75-ohm or 150W
and 150W
in parallel
�����������������������������������
100W
= 100W
�����������������������������������
200W
= 200-ohm or 100W
+ 100W
in series
�Important Note: These simple HF loads will not be accurate for SWR
checks above
30 MHz. Only precision terminations should be used in the VHF
region,
and even then there can be some errors.
The MFJ-259B does not correct for connector impedance bumps or the electrical
length between an external load and the bridge inside the unit.
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