Calculation of strain – Campbell Scientific 4WFB120, 4WFB350, 4WFB1K 4-Wire Full Bridge Terminal Input Module User Manual

4WFB120, 4WFB350, 4WFB1K 4 Wire Full Bridge Terminal Input Modules

6. Calculation of Strain

H

L

G

Vx

H

L

or AG

H

R1

R2

R3

Rg

FIGURE 6-1. Strain Gage in Full Bridge

Figure 6-1 is the diagram of the strain gage in the full bridge configuration
provided by the terminal input module. The result of the datalogger's full
bridge measurement when a multiplier of 1 and an offset of 0 is used is the
measured bridge output in millivolts divided by the excitation in volts (1000
mV=1V):

1000

1000

3

2

1

2

⋅

=

⋅

+

−

+

⎛

⎝

⎜

⎞

⎠

⎟

Vout

Vin

R

R

R

R

R

R

g

g

6.3.

The result is output in the units of millivolts output per volt of excitation
because the output voltage is small relative to the excitation voltage; these
units allow the result to be a larger number easier for the datalogger to display
and store (see data format discussion in the datalogger manual). The output is
a ratio because: 1) the datalogger's ratiometric measurement technique allows
this ratio to be more accurate than the measurement of the output voltage
(errors in the excitation and measured output cancel). 2) This ratio can be used
directly in the calculation of strain.

When strain is calculated the direct ratio of the voltages (volts per volt not
millivolts per volt) will be used:

Vout

Vin

R

R

R

R

R

R

g

g

=

+

−

+

3

2

1

2

6.4.

If the previous equation is taken as the result when the gage is unstrained, then
when the gage is strained it will change resistance by

∆

R

g

. The equation for

the bridge output is:

Vout

Vin

R

R

R

R

R

R

R

R

strained

g

g

g

g

=

+

+

+

−

+

∆

∆

3

2

1

2

6.5.

15