One approach to computing a factor of safety with a finite element code is to reduce the soil shear strength in stages to bring a slope into a state of limiting equilibrium. A slope problem is solved for progressively lower shear strength until failure occurs. The factor of safety is defined as the ratio of the soil’s actual shear strength to the reduced shear strength at failure. This “shear strength reduction technique” has a number of advantages over method-of-slices analysis. First, the critical failure surface is found automatically and it is not necessary to specify the shape of the failure surface (circular, log spiral, piecewise linear, etc) in advance. Second, failure mechanisms involving deforming wedges of soil can be analyzed. Deforming wedges are important for rotational failure of retaining walls and sheet pile walls, and for 3D slope stability problems. This type of failure mechanism cannot be handled with the method of slices, which assumes failure only along discrete slip surfaces.

In this paper, the shear strength reduction technique is illustrated through a number of examples. The basic technique is demonstrated for a simple homogenous embankment. Then, two problems involving deforming wedges are analyzed: rotational failure of a cantilever sheet pile wall and 3D slope stability of a vertical circular hole. Finally, the stability of a gravity retaining wall is studied, comparing strength reduction factors of safety to traditional sliding and rotational factors of safety.

Since the factor of safety is defined as a shear strength reduction factor, an obvious way of computing it with a finite element code is to reduce the soil shear strength until collapse occurs. The resulting factor of safety is the ratio of the soil’s actual shear strength to the reduced shear strength at failure. This approach was used as early as 1975 by Zienkiewicz, Humpheson & Lewis (1975), and has since been applied by Naylor (1982), Donald & Giam (1988), Matsui & San (1992), Ugai (1989), Ugai & Leshchinsky (1995) and others.

To perform slope stability analysis with the shear strength reduction technique, simulations are ran for a series of trial factors of safety F^trial with the soil cohesion c and angle of internal friction ϕ reduced according to the equations:

Previous studies have found the limit state, by reducing the shear strength in small steps until collapse occurs. We have found that bracketing and bisection is faster. First, upper and lower brackets are established. The initial lower bracket is any trial factor of safety at which a simulation converges to equilibrium. The initial upper bracket is any trial factor of safety for which the simulation does not converge. Next, a point midway between the upper and lower brackets is tested. If the simulation converges, the lower bracket is replaced by this new value. If the simulation does not converge, the upper bracket is replaced. The process is repeated until the difference between upper and lower brackets is less than a specified tolerance.

To determine if a simulation has reached equilibrium, the numerical mesh is searched for the node with the greatest unbalanced force. This maximum unbalanced force is then normalized by the gravitational body force acting on that node. In a numerical simulation the unbalanced force will never be exactly equal to zero and an acceptable lower limit must be chosen. For...