Advanced instruments inc, Accuracy & calibration – Analytical Industries GPR-2000 ATEX Portable Oxygen Analyzer User Manual

Advanced Instruments Inc.

9

Accuracy & Calibration

Single Point Calibration: As previously described the
galvanic oxygen sensor generates an electrical current
proportional to the oxygen concentration in the sample gas.

Absolute Zero: In the absence of oxygen the sensor exhibits
an absolute zero, e.g. the sensor does not generate a current
output in the absence of oxygen. Given these linearity and
absolute zero properties, single point calibration is possible.

Pressure: Because sensors are sensitive to the partial pressure
of oxygen in the sample gas their output is a function of the
number of molecules of oxygen 'per unit volume'. Readouts in
percent are permissible only when the total pressure of the
sample gas being analyzed remains constant. The pressure of
the sample gas and that of the calibration gas(es) must be the
same (reality < 1-2 psi).

Temperature: The rate oxygen molecules diffuse into the sensor is controlled by a Teflon membrane otherwise known as an
'oxygen diffusion limiting barrier' and all diffusion processes are temperature sensitive, the fact the sensor's electrical output
will vary with temperature is normal. This variation is relatively constant 2.5% per ºC.

A temperature compensation circuit employing a thermistor offsets this effect with an accuracy of better than +5% (over the

entire Operating Range of the analyzer) and generates an output function that is independent of temperature. There is no error
if the calibration and sampling are performed at the same temperature or if the measurement is made immediately after
calibration. Lastly, small temperature variations of 10-15º produce < 1% error.

Accuracy:

In light of the above parameters,

the overall accuracy of an analyzer is affected by two types of errors: 1) those

producing 'percent of reading errors', illustrated by Graph A below, such as +5% temperature compensation

circuit,

tolerances

of range resistors and the 'play' in the potentiometer used to make span adjustments and 2) those producing 'percent of full
scale errors', illustrated by Graph B, such as +1-2% linearity errors in readout devices, which are really minimal due to today's
technology and the fact that other errors are 'spanned out' during calibration. Graph C illustrates these 'worse case'
specifications that are typically used to develop an transmitter's overall accuracy statement of < 1% of full scale at constant
temperature or < 5% over the operating temperature range. QC testing is typically < 0.5% prior to shipment.

Example: As illustrated by Graph A any error, play in the multi-turn span pot or the temperature compensation circuit, during
a span adjustment at 20.9% (air) of full scale range would be multiplied by a factor of 4.78 (100/20.9) if used for
measurements of 95-100% oxygen concentrations. Conversely, an error during a span adjustment at 100% of full scale range is
reduced proportionately for measurements of lower oxygen concentrations.