Discretization with respect to time parameter.

n context of the condition ( Generic parabolic PDE setup ) we introduce partition of the interval $\left[ 0,T\right]$ : MATH We define to be the class MATH We introduce the notations MATH for .

We aim to approximate the solution of the problem ( Weak formulation with respect to time parameter ) with a function from $S_{\tau}^{q}$ for fixed and vanishing $\Delta t$ . We calculate for $v\in S_{\tau}^{q}$ and : MATH Note that MATH We continue MATH The equation ( Time-weak problem ) transforms into MATH for any . Thus, . We replace with $w\in S_{\tau}^{q}$ : MATH We can switch former problem for the latter if we can prove later that both problems have a unique solution. We merge conditions and arrive to MATH At this point we fix $T_{n}$ and take a with support within . We arrive to the following problem.

Problem

(Discontinuous Galerkin time-discretization) In context of the condition ( Generic parabolic PDE setup ) we seek $v\in S_{\tau}^{q}$ such that for every and any , MATH

Note that the solution of the equation ( Generic parabolic PDE problem ) satisfies the above problem.

Notation.

Index.

Contents.