Section 7. Installation
290
3. Perform the simulated deployment calibration as follows:
a. For the first point, set variable
SimulatedFlowSignal
=
300
. Set variable
KnownFlow
=
30.0
.
b. Start the calibration by setting variable
CalMode
=
1
.
c. When
CalMode
increments to
3
, for the second point, set variable
SimulatedFlowSignal
=
550
. Set variable
KnownFlow
=
10
.
d. Resume the deployment calibration by setting variable
CalMode
=
4
4. When variable
CalMode
increments to
6
, the deployment calibration is
complete. Calibrated multiplier is
-0.08;
calibrated offset is
53.9
.
5. To continue this example, suppose the simulated sensor multiplier and offset
drift. Simulate a seven-day service calibration to correct the drift as follows:
a. Set variable
SimulatedFlowSignal
=
285
. Set variable
KnownFlow
=
30.0
.
b. Start the seven-day service calibration by setting variable
CalMode
=
1
.
c. When
CalMode
increments to
3
, set variable
SimulatedFlowSignal
=
522
. Set variable
KnownFlow
=
10
.
d. Resume the calibration by setting variable
CalMode
=
4
6. When variable
CalMode
increments to
6
, the calibration is complete. The
corrected multiplier is
-0.08
; offset is
53.9
.
FieldCal() Two-Point Slope and Offset
'This program example demonstrates the use of FieldCal() in calculating and applying a
'multiplier and offset calibration. A multiplier and offset calibration compares signal
'magnitudes of a sensor to known standards. The calculated multiplier and offset scale the 'reported
magnitude of the sensor to a value consistent with the linear relationship that
'intersects known points sequentially entered in to the FieldCal() KnownVar parameter.
'Subsequent measurements are scaled by the new multiplier and offset.
'This program demonstrates the multiplier and offset calibration with the following procedure:
' -- Simulate a signal from a flow sensor.
' -- Measure the 'sensor' signal.
' -- Calculate and apply a multiplier and offset.
'You can set up the simulation by loading this program into the CR6 and interconnecting
'the following terminals with a jumper wire to simulate a flow sensor signal as follows:
'
U11
---
U
1
'For the simulation, the value of the calibration standard and the initial 'sensor' signal
'are set automatically. Start the multiplier-and-offset routine by setting variable
'CalMode = 1. The value in CalMode will increment automatically. When CalMode = 3, set
'variables SimulatedFlowSignal = 550 and KnownFlow = 10, then set CalMode = 4. CalMode
'will again increment automatically. When CalMode = 6 (occurs automatically after 10
Summary of Contents for CR6 Series
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Page 76: ...Section 5 Overview 76 FIGURE 20 Half Bridge Wiring Example Wind Vane Potentiometer ...
Page 80: ...Section 5 Overview 80 FIGURE 23 Pulse Input Wiring Example Anemometer ...
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Page 454: ...Section 8 Operation 454 FIGURE 104 Narrow Sweep High Noise ...
Page 459: ...Section 8 Operation 459 FIGURE 106 Vibrating Wire Sensor Calibration Report ...
Page 535: ...Section 8 Operation 535 8 11 2 Data Display FIGURE 121 CR1000KD Displaying Data ...
Page 537: ...Section 8 Operation 537 FIGURE 123 CR1000KD Real Time Custom ...
Page 538: ...Section 8 Operation 538 8 11 2 3 Final Storage Data FIGURE 124 CR1000KD Final Storage Data ...
Page 539: ...Section 8 Operation 539 8 11 3 Run Stop Program FIGURE 125 CR1000KD Run Stop Program ...
Page 541: ...Section 8 Operation 541 FIGURE 127 CR1000KD File Edit ...
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Page 610: ...Section 11 Glossary 610 FIGURE 137 Relationships of Accuracy Precision and Resolution ...
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