Section 8. Operation
351
There are four delays per measure. The CR3000 processes the four sub-
measurements into the reported measurement. In cases of excitation reversal,
excitation time for each polarity is exactly the same to ensure that ionic sensors do
not polarize with repetitive measurements.
Read More A white paper entitled "The Benefits of Input Reversal and
Excitation Reversal for Voltage Measurements" is available at
www.campbellsci.com.
Ground Reference Offset Voltage
When MeasOff
is enabled (=
True), the CR3000 measures the offset voltage of
the ground reference prior to each VoltSe() or TCSe() measurement. This offset
voltage is subtracted from the subsequent measurement.
From Auto Self-Calibration
If RevDiff, RevEx, or MeasOff
is disabled (=
False), offset voltage compensation
is continues to be automatically performed, albeit less effectively, by using
measurements from the auto self-calibration. Disabling RevDiff, RevEx, or
MeasOff speeds up measurement time; however, the increase in speed comes at
the cost of accuracy because of the following:
1 RevDiff, RevEx, and MeasOff are more effective.
2 Auto self-calibrations are performed only periodically, so more time skew
occurs between the auto self-calibration offsets and the measurements to
which they are applied.
Note When measurement duration must be minimal to maximize
measurement frequency, consider disabling RevDiff, RevEx, and
MeasOff when CR3000 module temperatures and return currents are slow
to change.
Time Skew Between Measurements
Time skew between consecutive voltage measurements is a function of settling
and integration times, A-to-D conversion, and the number entered into the Reps
parameter of the VoltDiff() or VoltSE() instruction. A close approximation is:
time skew = settling time + integration time + A
-to-D conversion time + reps
where A-to-D conversion time equals
125
µs. If reps (repetitions) > 1 (multiple
measurements by a single instruction), no additional time is required. If reps = 1
in consecutive voltage instructions, add 15 µs per instruction.
Содержание CR3000 Micrologger
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Страница 200: ...Section 7 Installation 200 FIGURE 42 Running Average Frequency Response FIGURE 43 Running Average Signal Attenuation ...
Страница 485: ...Section 8 Operation 485 8 11 2 Data Display FIGURE 110 Keyboard and Display Displaying Data ...
Страница 487: ...Section 8 Operation 487 FIGURE 112 CR1000KD Real Time Custom ...
Страница 488: ...Section 8 Operation 488 8 11 2 3 Final Storage Data FIGURE 113 Keyboard and Display Final Storage Data ...
Страница 489: ...Section 8 Operation 489 8 11 3 Run Stop Program FIGURE 114 Keyboard and Display Run Stop Program ...
Страница 491: ...Section 8 Operation 491 FIGURE 116 Keyboard and Display File Edit ...
Страница 495: ...Section 8 Operation 495 Low power standby whenever possible Low power bus sets bus and modules to low power ...
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Страница 564: ...Section 11 Glossary 564 FIGURE 126 Relationships of Accuracy Precision and Resolution ...
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