Fluke 1595A User Manual

11

Introduction and Specifications

Specifications

is converted to temperature by dividing 0.03 ppm by 1.0 × 10

6

and then multiplying by 1.02. The result is then

divided by W

T90

sensitivity, dW/dT, at 0.01 °C, which is 0.004. The final result is 0.000008 °C. After multiply-

ing by W

T90

(1.612), the uncertainty of the RTPW resistance ratio, when applied to 157 °C, is 0.000013 °C.

2.2.5.3.5 Measurement Noise at 0.01 °C

During measurement of the RTPW, it is observed that the standard error of the mean is 0.0000018 Ω. To

convert this value into temperature, divide by the resistance sensitivity (dR/dT) of the SPRT at 0.01 °C. dR/dT

at 0.01 °C is 0.1 W/°C (see tip below). The result is 0.000018 °C. Multiplying by W

T90

(1.612) yields 0.000029

°C.

Tip:

Most SPRT calibration reports list the Temperature versus W values of the SPRT in a table.

Typically, the dT/dW value at each temperature will be included in the same table. dR/dT can be

calculated by inverting dT/dW and multiplying by the RTPW of the SPRT. Also, dW/dT can be calculated

by simply inverting dT/dW.

2.2.5.3.6 Uncertainty of the TPW Cell

Uncertainty of the temperature of the triple-point of water cell must also be included. For this example, the

standard uncertainty of the triple-point of water cell is 0.000050 °C. Multiplying by W

T90

(1.612) results in

0.000081 °C.

2.2.5.3.7 Reference Resistor Drift

Possible drift of the 25 W reference resistor between the TPW measurement and the 157 °C measurement must

be accounted for. To reduce the possible error, both measurements should be taken in close proximity in time.

For this example, the 24-hour stability specification will be used. This requires that both measurements are

taken within the same 24-hour period. The standard uncertainty due to drift of the reference resistor is 0.125

ppm. This is converted to temperature by dividing 0.125 ppm by 1.0 × 10

6

and then multiplying by 1.612. The

result is then divided by W

T90

sensitivity (dW/dT) at 157 °C which is 0.0038. The result is 0.000053 °C.

2.2.5.3.8 Combining the Uncertainties

At this point, all of the uncertainties can be combined by root-sum-square (RSS) since they are uncorrelated.

Even though the 1595A resistance ratio accuracy is used twice in the calculation, both measurements are con-

sidered uncorrelated.
This RSS sum produces a combined standard uncertainty of 0.000115 °C. Multiplying by the coverage factor

(k = 2) results in a total expanded uncertainty of 0.000230 °C.
In this example, it is assumed the SPRT did not drift between the measurements at the TPW and 157 °C. It

may be necessary to add an additional uncertainty that accounts for SPRT drift.

2.2.5.3.9 Measuring With Calibration Report RTPW

In this example, the SPRT is monitored by periodically measuring its RTPW in a TPW cell but the original

RTPW from the SPRT calibration report is entered in the 1595A, not the measured RTPW. This requires a dif-

ferent set of specifications to be used in the measurement uncertainty.
The uncertainty of this measurement is based on four uncorrelated uncertainties. These uncertainties are:

●

●

Resistance accuracy of the 1595A when measuring the SPRT at 157 °C

●

●

Measurement noise at 157 °C

●

●

Uncertainty of the SPRT resistance at the triple-point of water

●

●

Drift of the RTPW of the SPRT

2.2.5.3.10 Resistance Accuracy at 157 °C

The resistance of the SPRT at 157 °C is 41.1 Ω. Using the 25 Ω internal reference resistor, the 1595A one-

year resistance standard uncertainty is 2.5 ppm. This uncertainty, in terms of temperature, is calculated by first

dividing 2.5 ppm by 1.0 × 10

6

then multiplying by 41.1 Ω. The result is then divided by the sensitivity (dR/dT)