Non-linear time history analysis obtains the response of the structure in which any non-linear elements have been defined. Time history analysis consists in reaching a solution of the following equation of the t time variable:
M * a(t) + C * v(t) + N (d(t)) = F(t)
with known initial values d(0)=d0 and v(0)=v0,
where:
M - mass matrix
K - stiffness matrix
C = α * M + β * K - damping matrix
N - internal force vector which is in a non-linear relation to the d shift vector
α - coefficient defined by a user
β - coefficient defined by a user
d - shift vector
v - velocity vector
a - acceleration vector
F - load vector.
A load vector is assumed as 
, where n denotes a number of force components, Pi - i-th force component, φi(t) - i-th time-dependent function. The excitation may be expressed in the following form: 
, where Idir denotes a direction vector (dir = x, y, z) whereas 
is an accelerogram.
To solve a non-linear task of time history analysis, the predictor-corrector approach is employed (see Hughes T.R.J., Belytschko T. Course notes for nonlinear finite element analysis. September, 4-8, 1995).
The input parameters defined for a non-linear time history analysis are almost identical to the parameters defined for a linear time history analysis. The non-linear parameters are identical as those for non-linear static analysis.