Resolution is a measure of the ability to differentiate between one voltage and another. Obviously, the more bits of resolution (13 bits = 8192 counts) the more divisions of full scale. The more divisions of full scale, the higher the resolution of the measurement.

6.7 ENGINEERING UNITS

When a program uses an A/D board to acquire data, the data file is filled with numbers like those above.

To translate the A/D numbers back into the engineering units of the original measurement, we need to know:

The sensor's voltage output per engineering unit.

The full scale range of the board at the time the measurement was made. The resolution of the converter.

Here is an example from the application note on interfacing a Voland TA to a PC found elsewhere in this manual.

The TA measures resistance in grams between +500 and 500 grams. The voltage output of the instruments is +2.5 volts to 2.5 volts.

The voltage output corresponds to the grams of pressure exactly, so: +/- 500 grams = 1000 grams.

+/- 2.5 volts = 5 volts.

5 volts / 1000 grams = 0.005 volts per gram.

The A/D was set for +/- 2.5 volts = 5 volts full scale.

5 volts / 4096 counts = 0.00122 volts per bit.

If the number in the file for one reading was 3061, then 3061 * 0.00122 = 3.7366 volts.

3.7366 volts / 0.005 volts per gram = 747 grams. Now shift from full scale to +/- scale.

747 grams full scale 500 = 247 grams of positive pressure.

It may look like a lot of steps because it is presented that way here for clarity only. It could be expressed as a single equation in a spreadsheet.

6.8 CURRENT LOOP (4-20 mA)

Although the inputs of a CIO-DAS16 board are voltage inputs, it is easy to convert a current to a proportional voltage which may be measured by the CIO-DAS16 board. The current is converted to a proportional voltage by the formula V=I*R (Ohm’s law).

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Measurement Specialties CIO-SSH16 user manual Engineering Units, Current Loop 4-20 mA