TY - JOUR
T1 - Backward Euler Schemes for the Kelvin-Voigt Viscoelastic Fluid Flow Model
JO - International Journal of Numerical Analysis and Modeling
VL - 1
SP - 126
EP - 151
PY - 2016
DA - 2016/01
SN - 14
DO - http://doi.org/
UR - https://global-sci.org/intro/article_detail/ijnam/414.html
KW - Viscoelastic fluids, Kelvin-Voigt model, a priori bounds, backward Euler method, discrete attractor, optimal error estimates, linearized backward Euler scheme, numerical experiments.
AB - <p style="text-align: justify; margin-bottom: 10px;">In this paper, we discuss the backward Euler method along with its linearized version
for the Kelvin-Voigt viscoelastic fluid flow model with non zero forcing function, which is either
independent of time or in $\rm{L}^∞(\rm{L^2})$. After deriving some bounds for the semidiscrete scheme,
a priori estimates in Dirichlet norm for the fully discrete scheme are obtained, which are valid
uniformly in time using a combination of discrete Gronwall&#39;s lemma and Stolz-Cesaro&#39;s classical
result for sequences. Moreover, an existence of a discrete global attractor for the discrete problem
is established. Further, optimal a priori error estimates are derived, whose bounds may depend
exponentially in time. Under uniqueness condition, these estimates are shown to be uniform
in time. Even when $\rm{f}$ = 0, the present result improves upon earlier result of Bajpai et al.
(IJNAM,10 (2013), pp.481-507) in the sense that error bounds in this article depend on $1 / \sqrt{\kappa}$ as
against $1 / \kappa^r$, $r \geq 1$. Finally, numerical experiments are conducted which confirm our theoretical
findings.</p>