The classical random walk can be described as the evolution of the position $X_t$ of a walker for integers $t \geqslant 0$, where $X_0 = 0$ and $X_t = X_{t-1} + V_t$ for $t \geqslant 1$, where the "speed" $V_t$ at each time step is uniformly random $V_t \in_{\mathrm R} \{-1,+1\}$ and independent at each time step.
It is well-known that this process yields a position which obeys a symmetric binomial distribution with mean $0$ and variance $t$, and that $t^{-1/2} X_t$ tends to a Gaussian distribution with variance $1$.

I am interested in a variant in which the speed itself increases or decreases by random "boosts", behaving like a classical random walk, and where the position is governed by the speed as it evolves over time. That is, we have
$$\begin{aligned}
 X_0 &= 0              & V_0 &= 0 \\
 X_t &= X_{t-1} + V_t  & V_t &= V_{t-1} + A_t  & A_t \in_{\mathrm R} \{-1,+1\}.
\end{aligned}$$
**Question.** What is the probability distribution of $X_t$ as a function of $t$?

*Remark #1.*
This process is in effect a discrete-time variant of a second-order stochastic differential equation of a form
$$\begin{aligned}
  \frac{\mathrm dx}{\mathrm dt} &= v, & \frac{\mathrm dv}{\mathrm dt} = \xi_t
\end{aligned}$$
where $W_t = \int_{0}^t \mathrm d\tau \, \xi_\tau\,$;  though I do not know enough to be able to distil what probability density function one would expect for $x(T)$ from the references I found.

*Remark #2.* I originally requested an answer regarding the density function of the continuous version $x(t)$ as a fall-back. I have accepted an answer on that question for now; and that answer implicitly provides an answer for the discrete-time version in which the steps are normally distributed instead of being of fixed size. However, I will preferentially accept and reward any answer on the discrete-time version of the problem.