24 November 2013

Testing the ZS6RSH Measurement Procedure

The below table is developed as a teamplate for the Measurement Procedure now developed. This template is filled in using microsoft word embedded tables. The table is then simply copied onto the clipboard and pasted into the blog editor as below.

This table is also included in the RF Power measurements blog as written on 11/10/2013.

1
Heading
RF Power Measurements procedure.
2
Label
RF Power Measurements.
3
Date
11/22/2013.
4
Acknowledgements
1.      Author : ZS6RSH.
2.      Reference: EMRFD Section 7 paragraph 7.3.
5
Revision
Rev 1.
6
Revision History
A blog was first written on 11/10/2013. This procedure is being written ‘after the fact’ with the aim of testing the effectiveness of the measurement procedure.
7
Scope
Based on the recommendations in EMRFD it is valid to calibrate my homebrew RF power meter using DC power.  As confirmed in EMRFD, the calibration will be valid through the HF range and into VHF for the specified diode 1N4148. Since the resistors I have used for the dummy load are only 1/4watt rating it is only possible to calibrate between the voltage ranges of 1V-15V at this time. The lower app ~ 1 volt limit is due to the silicon diode becoming non-linear for voltages below that value. Thus the power measurement range will be approximately between +34dBm and +12dBm.
8
History
The accuracy of this DC calibration is primarily dependent on the accuracy of the DC voltage measurements (see UNCERTAINTIES below). Measurements have previously been carried out to understand the accuracy of my two DC voltmeters. The Fluke and Keithley. (Model numbers to be provided). These two meters read the same DC voltages to 2 decimal places over the range 15V – 1V. Refer to xxx For these measurements.
9
Configuration
 The homebrew RF Power meter is connected to a variable voltage DC power supply with a variable voltage range of 1VDC – 15VDC and a maximum current capacity of 1Amp. The DC voltage was measured using the Keithly voltmeter connected across the input of the power meter.
10
Test equipment specifications
1.      Keithley model xxx voltmeter.
2.      Homebrew variable voltage current limited, power supply.
3.      Connection leads. Regular leads that came with the voltmeter.
4.      Jumper leads used for the power connections.
11
DUT specifications
Homebrew RF Power meter including dummy load. Power range of 15V FSD, Approx +34dBm - +12dBm.
12
Workbench process
1.      Back off the calibration pot so that the meter cannot be overdriven.
2.      Set the power supply to 15V.
3.      Quickly adjust the cal pot to achieve FSD of 1mA.
4.      Turn off the power supply.
5.      Reduce the power supply voltage so that the meter shows decrements of 1/10 of a milliamp.
6.      For each 1/10 milliamp reduction, quickly record the voltage to 2 decimal places.
7.      Take 10 readings.
8.      Change the FSD to 10Volts.
9.      Take 10 readings as above.

13
Expected Results
The recorded voltages against the ammeter readings should represent the transfer characteristics of a silicon diode of type 1N4148
14
Uncertainties
1.      Dummy load change as a result of dissipation heating. Can be kept to a minimum if the tests are carried out quickly. This variation can be characterized in a separate set of measurements. However the plan is to build a dummy load with QRP power dissipation capabilities in the future.
2.      Specific transfer characteristics of the diode are unknown but will be discovered.
3.      Non linearities in the specific voltmeter readings. Already verified to not be an issue to 2 decimal places.
4.      Variations in ambient temperature during the test period. Not taken into account during this test but could be by recording the temperature for each measurement.
5.      Parallax errors from reading the analog ammeter. Can be read to the nearest 1/100th of a milliamp.
6.      Quick reading of the meters could result in a recording error.
7.      Calibration Graphing errors. However the data was recorded to 2 decimal places.
8.      It is uncertain that the RF Power Meter will record peak RF voltages according to the same transfer characteristics as at DC level. This is assumed to be the case based on the EMRFD reference in section 7 and nothing else at this stage. This consideration is beyond the scope of this set of DC measurements.
9.      RF coupling causing variations in load and measurement characteristics. The SWR was seen to be a flat 1:1 across the HF spectrum using an MFJ259B analyzer. As for 8 above, this consideration is beyond the scope of this set of DC measurements.

15
Preparation
Completed.
16
Perform validation measurements
Completed. The meter calibration pot was set to a minimum to start with to ensure that the meter would not be harmed by overdriving.
17
Perform the full measurement plan
Completed.
18
Observations
No unexpected variations or observations.
19
Change Control
No changes were made to the original plan.
20
Computation
Refer to the attached tables. For each recorded voltage a power value was derived using the formula P=Vpeak^2/2R.  This formula is valid since at RF the meter records peak RF power. The diode rectifies the AC signal and the capacitor charges to the peak value. This power was then converted to dBm and graphed. Thus a major assumption is made here that the power meter will in fact correctly record peak RF values in practice. This validation is beyond the scope of this set of DC measurements.
21
Analysis
The graph of the results shows an expected transfer characteristic in line with a 1N4148 diode over the measurement range.
22
Conclusions
The calibration curves are in line with the expected results and can reasonably be used to explore RF power measurements. Validation of the results, however, is needed in the future against a calibrated RF source.
23
Documentation
Completed


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