Lateral Earth Pressure (Rankine)

Active vs at-rest vs passive

The earth pressure on a wall depends on wall movement:

• Active (K_a): wall moves AWAY from backfill. Soil expands, fails in shear, mobilizes minimum lateral pressure. Required movement: ~0.001H to 0.004H. The standard for design of cantilever and gravity walls.
• At-rest (K₀): wall does not move. Used for rigid walls (basement walls braced against the slab) or very stiff structures. K₀ is between K_a and K_p.
• Passive (K_p): wall moves INTO backfill. Required movement is much larger (~0.02H to 0.1H). Develops the maximum lateral resistance. Used to compute embedment pull-out resistance and toe resistance below the wall.

For a typical retaining wall, design uses K_a on the back face (driving force) and K_p at the toe (resistance), with FS > 1.5–2.0 against sliding and overturning.

Surcharge effects

Uniform surcharge q on the backfill adds K_a q H to the active thrust. The pressure distribution from surcharge is rectangular (constant with depth), unlike the triangular distribution from soil self-weight. Line surcharges (column footings, traffic loads) require Boussinesq's elastic solution and are not in this calculator.

Cohesive soil and the tension crack

For a c-φ backfill, K_a reduces the effective lateral pressure by 2c√K_a at every depth. This means the upper portion of the wall might compute negative active pressure — physically impossible because soil can't pull. A tension crack forms at depth z₀ = 2c/(γ √K_a). For design, ignore the tension zone (treat the upper soil as if it weren't there) and recompute the thrust from below z₀. Saturated cracks fill with water, adding hydrostatic pressure — so use K_a = 0.5 to 1.0 in the cracked zone for waterlogged conditions.

Wall friction (Coulomb)

Rankine assumes a smooth (zero friction) wall and horizontal backfill. Real walls have wall friction δ = (1/2 to 2/3) φ. Coulomb's earth pressure theory accounts for this and gives slightly lower K_a (cheaper design) and slightly higher K_p. For tall walls (H > 25 ft) or sloping backfill, use Coulomb. Rankine is conservative for active pressure.

Line of action

The triangular soil-weight pressure has its centroid at H/3 above the base. The rectangular surcharge pressure has its centroid at H/2. The combined line of action is a weighted average. This calculator reports the combined line of action above the base for the active thrust including surcharge.

Reference: Rankine, W.J.M. (1857). "On the Stability of Loose Earth." Phil. Trans. Royal Society, 147, 9-27. Das, B.M. (2014). Principles of Geotechnical Engineering, 8th ed., Cengage, ch. 13.