I asked this question here: https://math.stackexchange.com/questions/416885/checking-initial-condition-of-pde-is-satisfied-in-galerkin-method

But I did not receive the solution so I post it here.

The following is an argument I read, it is part of a proof of checking that **the solution given by the Galerkin method satisfies the initial conditions**.

From our weak formulation
$$\langle u', v \rangle_{V',V} + a(u, v) = \langle f, v \rangle_{V',V}$$
which holds for all $v \in L^2(0,T;V)$, we can pick $v \in C^1(0,T;V)$ with $v(T) = 0$ and integrate this equation in time and use integration by parts to obtain
$$\int_0^T -\langle u, v' \rangle_{V',V} + \int_0^T a(u,v) = \int_0^T\langle f, v \rangle_{V'V} + (u(0),v(0))_H.\tag{1}$$

Now we must use our Galerkin approximation
$$\int_0^T\langle u_m', v_n \rangle_{V',V} + \int_0^Ta(u_m,v_n) = \int_0^T\langle f, v_n \rangle_{V',V}\tag{a}$$
and do some integration by parts and pass to the limit to obtain 
$$\int_0^T -\langle u, v' \rangle_{V',V} + \int_0^T a(u,v) = \int_0^T\langle f, v \rangle_{V'V} + (u_0,v(0))_H\tag{2}$$
where $v \in C^1(0,T;H)$ with $v(T) = 0$. This works because we know $u_m(0) \to u_0$, the initial condition.

Comparing (1) and (2), we can conclude $u(0) = u_0$.

**Reasoning to obtain equation (2)**

We have the convergences $u_m \rightharpoonup u$ in $L^2(0,T;V)$ and $u'_m \rightharpoonup u'$ in $L^2(0,T;V')$, where the $u_m \in V_m$. Pick $v_n \in V_n$ such that $v_n \to v$ in $L^2(0,T;V).$ Note that $v_n = \sum_{j=1}^n a_{j,n}w_j$ where $w_j$ is an o.n basis of $H$ and o.g basis of $V$.

We obtain from (a) the equation
$$-\int_0^T\langle u_m, v_n' \rangle_{V',V} + \int_0^Ta(u_m, v_n) = \int_0^T\langle f, v_n \rangle + (u_m(0),v_n(0))_H$$
by IBP (and recall that $v \in C^1(0,T;V) \subset L^2(0,T;V)$ with $v(T) = 0$.)

My problem is, how to obtain (2) from here? Specificially, I don't understand why it is 
true that
$$\int_0^T \langle u_m, v'_n \rangle \to \int_0^T \langle u, v' \rangle_{V'V}.$$

I am fine with the other terms in the equation. Why is true that $v'_n \to v$ in $L^2(0,T;V)$? 

OK, so $v'$ exists and $v_n'$ probably exists assuming we can differentiate the coefficients. But why does it convergence to $v'$? No explanation is given anywhere.