The purpose of this prototype unit does away with the need for an oscillator.
It offers a mains-derived and fully variable 50 hz AC volts down to millivolts
for comparison and to check accuracy, of two or more parallel connected multimeters.
Sometimes older instruments of this type are favoured to respond better at
low frequencies than higher audio frequencies, which are better suited for
measurement by wideband audio millivoltmeters.
It is to be called to attention that unless otherwise stated by the manufacturer,
both mechanical and digital multimeters display all pure and irregular wave shape
inputs including square, triangle, sawtooth and integrator, as readings in Mean or Average Form-factor.
Obviously the higher the mains transformer secondary voltage output delivered,
the higher the AC switched ranges or auto-ranging which can be measured.
The choice of transformer and resistor attenuator values can thus be adapted
to suit individual voltage range requirements.
Caveat: To comply with Health and Safety, ideally a small adhesive warning
sign should be affixed to the box lid to state “Danger Mains Inside”.
The prototype does not have one displayed as not being available.
However in this case a screwdriver is required to open the lid,
therefore that situation is in my control and at my risk.
Circuit description and calibration procedure
A small mains transformer, in this case delivers maximum 10v AC from a
secondary winding across a variable resistor network.
Incoming spiky noise is shunt-filtered by a 4.7n ceramic capacitor,
soldered to a mounted short tag strip.
AC feeds a multiturn pot VR1 which sets the reduced base voltage and
then in series to two tandem-wired 1k lin pots labelled coarse and fine.
For convenience of adjustment nearer to the hole in the box lid,
VR1 is recommended to be supported on the same tag strip.
The raw secondary 50 hz output waveform at my home is rather ragged as viewed
on my laptop pc scope.
So to improve the waveform to a more acceptable sinusoidal shape, this can be further
low-pass filtered by a single 2.2 mfd or two 1mfd polyester capacitors wired in parallel
across the two pots combination as shown.
Tip: Operationally, the sine shape on a scope improves if the coarse pot is kept
at lower levels, while using the fine pot for small range adjustments.
The calibrated Avo 8 MkIII test meter I possess, expectedly loads the commoned
monitoring line when in the lowest AC range position of 2.5v.
However this is immaterial as the other multimeter on test also responds
to the same volt drop.
If after building the cal aid unit correctly as shown in the prototype example photos,
this must next be established to be working correctly.
Don’t plug into the mains just yet.
Connect any good preferably calibrated multimeter to hand, via 2mm probes to the
2mm meter monitor sockets and a second meter if applicable to the main output
socket, in this case a BNC type via adaptors.
Turn both coarse and fine pots to maximum clockwise for full output.
Set the multimeters to a suitable AC volts range, in this case 0 to 10v if manual
and the other may auto-range if applicable.
For initial meter overload safety, using a trimming tool turn VR1 anticlockwise
at maximum resistance for very low output.
Plug the unit into the mains.
Then turn preset VR1 quickly clockwise to minimum resistance.
This test starts at high volts to compare the maximum end of each respective
10v meter display range for accuracy.
(The Avo is reputedly more accurate at the high end of its DC and AC scales.)
Then continue, slowly turning VR1 anticlockwise down to check their respective
2.5v ranges for accuracy. Stop at 0.5v.
Though absolute accuracy of the two or more meters under test isn’t guaranteed
at this stage, then turn the main coarse & fine pots slowly down to track the display or
scales points together and compare their very low AC volts and millivolts performances.
It will be seen on the Avo that useful scale resolution ceases at 100mV, but the
Beckman is capable of lower resolution to millivolts.
For any further sensitive electronic work, it is suggested to leave
VR1 AC base reference at about 0.5v to 1v AC across the coarse/fine pots.
The above tests should show the meters at least conform to “95% accuracy satisfaction”
as demanded by test equipment manufacturers and calibration houses.
The photo above of two meters on test with the same 5v AC readings,
seems to show they have acceptable 95% satisfaction, but it is also intriguing
to ponder on this thought-provoking question to finish the article:
What is the difference between accuracy and precision?
From what can be researched, accuracy is a measure of fine detail or small differences.
Precision is a measure of closeness to the true value.
It appears in life there is still much striving required to achieve perfection,
though common sense compromises sometimes have to be allowed!