Gauge factor
Gauge factor or strain factor of a strain gauge is the ratio of relative change in electrical resistance R, to the mechanical strain ε. The gauge factor is defined as:
where
- ε = strain =
- * = absolute change in length
- * = original length
- ν = Poisson's ratio
- ρ = resistivity
- ΔR = change in strain gauge resistance due to axial strain and lateral strain
- R = unstrained resistance of strain gauge
Piezoresistive effect
However, most commercial strain gauges utilise resistors made from materials that demonstrate a strong piezoresistive effect. The resistivity of these materials changes with strain, accounting for the term of the defining equation above. In constantan strain gauges, the effect accounts for 20% of the gauge factor, but in silicon gauges, the contribution of the piezoresistive term is much larger than the geometric terms. This can be seen in the general examples of strain gauges below:
| Material | Gauge Factor |
| Metal foil strain gauge | 2-5 |
| Thin-film metal | 2 |
| Single crystal silicon | -125 to + 200 |
| Polysilicon | ±30 |
| Thick-film resistors | 100 |
| p-type Ge | 102 |
Effect of temperature
The definition of the gauge factor does not rely on temperature, however the gauge factor only relates resistance to strain if there are no temperature effects. In practice, where changes in temperature or temperature gradients exist, the equation to derive resistance will have a temperature term. The total effect is:where
- α = temperature coefficient
- θ = temperature change