Factor of Safety or Probability of Failure?

Factor of Safety (Deterministic)

How is the acceptability of an engineering design assessed?

Rockbolting alternatives involving individual judgement. (Drawings based on a cartoon in a brochure on rockfalls published by the Department of Mines of Western Australia.)?

The classical approach used is to consider the relationship between the strength or resisting force of the element and the stress or disturbing force. The Factor of Safety of the structure is defined as FoS = strength or resisting force/stress or disturbing force and failure is assumed to occur when FoS is less than 1.

Probability of Failure (Probabilistic)

Rather than using a single calculated FoS , an alternative approach using probabilities can be used. This process begins by completing a series of calculations in which each significant parameter (random variable) is varied systematically over its maximum credible range in order to determine its influence upon the factor of safety.?

Common practice engineering implicitly considers those variabilities (uncertainties) by reducing resistance and increasing loadings to “prudent” values. It then expresses FoS as a single number. Probabilistic methods allow these uncertainties to be considered.

Most random variables for geotechnical applications have standard normal distributions of probabilities (including FoS). Example below.

Some random variables have a significant effect on FoS. For example, a simple example is drained cohesion c'. In the example below (from https://www.riskope.com/wp-content/uploads/2020/12/Riskope-The-Factor-of-Safety-and-Probability-of-Failure-relationship-1.pdf) a small cohesion variation leads to a significant change in probability of failure.

But why?

Well, the random variables involved in geotechnics (the parameters relating to the ground, generally) can have a significant effect on the factor of safety (as seen in the cohesion above). Just using single values for FoS determination cannot account for the uncertainties. So the real question becomes whether the FoS determined is sufficient?

These uncertainties can include:

1. drained shear strength parameters
2. undrained shear strength
3. vertical and horizontal variability in soil profile (in addition to variations in parameters associated with the same material
4. 3D effects

So - how well can you account for variabilities in each of these aspects to determine a single FoS?

Typically not very well.

The image below is from Silva et al, 2008 and shows the Probability of Failure vs. Factor of Safety for historical dams.

As you can see, a FoS of 1.5 presents an annual probability of failure between 1 x 10-1 and 1 x 10-6 , depending on the dam Category. This is a HUGE difference in probability.

Takeaway

We must consider whether a FoS deterministic approach is appropriate for the geotechnical application. Is the geological and geotechnical model complex, not well investigated or defined? Is the consequence of failure significant? Are the uncertainties well understood?

If there are any concerns with these, it may be beneficial to complete a probabilistic approach.

More Reading

https://www.rocscience.com/assets/resources/learning/hoek/Practical-Rock-Engineering-Chapter-8-Factor-of-Safety-and-Probability-of-Failure.pdf

https://www.riskope.com/wp-content/uploads/2020/12/Riskope-The-Factor-of-Safety-and-Probability-of-Failure-relationship-1.pdf

https://hatsconsult.com/published-paper-4