Service manual
A
Calculating Multimeter Accuracy
Introduction This appendix shows how multimeter accuracy, measurement
uncertainty, and test accuracy ratio (TAR) values are defined and
calculated for the performance verification tests for the Agilent E1326B
multimeter.
See Table 4-1, "Performance Test Record for the Agilent E1326B
Multimeter" for 1-year specification values of multimeter accuracy,
measurement uncertainty, and test accuracy ratios (TARs).
NOTE
Multimeter accuracy, measurement uncertainty, and test accuracy ratios in
Table 4-1 are valid ONLY for the specified test conditions and
assumptions described in this manual. For the test conditions described,
all TARs exceed the 4:1 requirements of MIL-STD-45662A.
Multimeter
Accuracy
Definition
Multimeter accuracy is the expected accuracy of the measurement due
ONLY to the multimeter. The "Low Limit" entry in Table 4-1 is the
lower (-) value of multimeter accuracy, while the "High Limit" entry is
the upper (+ ) value of multimeter accuracy.
Measurement
Uncertainty
Definition
Measurement Uncertainty is the expected accuracy of the source used
to input signals to the multimeter. Since the Datron 4708 Autocal
Multifunction Standard is the source used for measurements in this
manual, the measurement uncertainty of the source is that of the
Datron 4708.
This value is shown in the "Measurement Uncertainty" column of Table
4-1. See the Datron 4708 User’s Handbook for additional information on
calculating measurement uncertainty for the Datron 4708 source.
NOTE
Measurement Uncertainty does not apply to the DC Voltage (Zero Volts
Input) test, since no input is applied.
Calculating Multimeter Accuracy A-1