Revision as of 15:45, 23 January 2009

Theory[edit]

The left impedance is the signal generator which is generating enough power for 1 ampere.

This 1Amp. generates $P=I^{2}*R=50\ Watt$ in the right impedance.

The current sensor has 1 ohm transfer impedance, this means 1 ampere generates 1 Volt on the measuring part below.

The power in the lower 50 ohm impedance is $P={\frac {U^{2}}{R}}=20\ mWatt$

So 1 ohm: $10*^{10}log({\frac {0,02}{50}})\approx -33,98dB=-20*^{10}log(50)$

${\displaystyle Correction\ factor($

$P_{Measured}$ and $P_{Reference}$ in dBm.

On 10 MHz we have the following information:

So: $Imp.=-27,96-0.00+33.98=6,02dBohm$

$Imp.=$

Note:

This method is not a replacement for a real calibration.

@@ Line 19: / Line 19: @@
 = Calculation =
-<Math>Correction \ factor (dB)= P_{Measured} - P_{Reference} + 33.98</Math>
+<Math>Correction \ factor (dB)= P_{Measured} - P_{Reference}+ 33.98</Math>
 <Math>P_{Measured}</Math> and <Math>P_{Reference}</Math> in dBm.
+= Example =
+On 10 MHz we have the following information:
+*Calibration: 0 dBm.
+*Measurement: -27,96 dBm.
+So:
+<math>Imp.=-27,96-0.00+33.98=6,02 dBohm</math>
+<math>Imp.= </math>
 {{note|This method is not a replacement for a real calibration.}}