Calibration Process - Campbell CR510 Operator's Manual

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Operator's manual (21 pages)

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In Figure 13.5-2, V

is a fixed resistor, R

and R

is the resistance between the excited

electrode and CR510 earth ground. With R

the network, the measured signal is:

= V

__________________

is the source of error due to the ground

loop. When R

is large the equation reduces to

the ideal. The geometry of the electrodes has a

great effect on the magnitude of this error. The

Delmhorst gypsum block used in the 227 probe

has two concentric cylindrical electrodes. The

center electrode is used for excitation; because

it is encircled by the ground electrode, the path

for a ground loop through the soil is greatly

reduced. Moisture blocks which consist of two

parallel plate electrodes are particularly

susceptible to ground loop problems. Similar

considerations apply to the geometry of the

electrodes in water conductivity sensors.

The ground electrode of the conductivity or soil

moisture probe and the CR510 earth ground

form a galvanic cell, with the water/soil solution

acting as the electrolyte. If current was allowed

to flow, the resulting oxidation or reduction

would soon damage the electrode, just as if DC

excitation was used to make the measurement.

Campbell Scientific probes are built with series

capacitors in the leads to block this DC current.

In addition to preventing sensor deterioration,

the capacitors block any DC component from

affecting the measurement.

13.6 CALIBRATION PROCESS

The CR510 makes voltage measurements by

integrating the input signal for a fixed time and

then holding the integrated value for the analog

to digital (A/D) conversion. The A/D conversion

is made by a 13 bit approximation using a digital

to analog converter (DAC). The result from the

approximation is DAC counts, which are

multiplied by coefficients to obtain millivolts

(mV). There are 10 calibration coefficients, one

for each of the 5 gain ranges for the fast and

slow integration times.

The CR510 has an internal calibration function

that feeds positive and negative voltages

through the amplifiers and integrator and

calculates new calibration coefficients. By

is the excitation voltage, R

is the sensor resistance,

[13.6-1]

) + R

SECTION 13. CR510 MEASUREMENTS

adjusting the calibration coefficients the

accuracy of the voltage measurements is

maintained over the -25 to +50 C operating

range of the CR510. Calibration is executed

under four conditions:

1. When the CR510 is powered up.

2. Automatically when Instruction 24 is not

contained in a program table.

3. When the watchdog resets the processor.

4. When the calibration instruction, Instruction

24, is executed.

AUTOMATIC CALIBRATION SEQUENCE

The primary advantage of automatic calibration

is that the CR510 is constantly calibrated

without user programming. The CR510 defaults

to automatic calibration when Instruction 24 is

not contained in a program table.

Every 8 seconds one part of a 22 part

calibration sequence is performed. Program

execution is interrupted (5.4 - 21.4 ms), when

necessary, for each part of the calibration.

Every 2.9 minutes (8 seconds * 22) ten

calibration coefficients are calculated. The

calculated coefficients are multiplied by 1/5, and

then added to 4/5 times the existing

coefficients. Averaging is done as a safeguard

against coefficients calculated from a noisy

measurement.

The above weighting of the newly calculated

coefficients results in a 15 minute time constant

(see Instruction 58) in the response of the

calibration to step changes affecting the

calibration coefficients (primarily temperature).

For most environmental applications a 15

minute time constant is acceptable. The

automatic calibration may result in the

calibration coefficients not being optimum for

applications that subject the CR510 to extreme

temperature gradients.

Automatic calibration extends the processing

time 5.4 to 21.4 ms when it is executed (every 8

seconds). If the processing time exceeds the

execution interval the CR510 finishes

processing the table and awaits the next

occurrence of the execution interval before

initiating the table. At the fastest execution

interval of 1/64 (0.0156) second the program

13-17

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Calibration Process - Campbell CR510 Operator's Manual

13.6 CALIBRATION PROCESS

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