--- title: "Grönwall-Bellman inequality" firstLetter: "G" publishDate: 2021-11-07 categories: - Mathematics date: 2021-11-07T09:51:57+01:00 draft: false markup: pandoc --- # Grönwall-Bellman inequality Suppose we have a first-order ordinary differential equation for some function $u(t)$, and that it can be shown from this equation that the derivative $u'(t)$ is bounded as follows: $$\begin{aligned} u'(t) \le \beta(t) \: u(t) \end{aligned}$$ Where $\beta(t)$ is known. Then **Grönwall's inequality** states that the solution $u(t)$ is bounded: $$\begin{aligned} \boxed{ u(t) \le u(0) \exp\!\bigg( \int_0^t \beta(s) \dd{s} \bigg) } \end{aligned}$$
Grönwall's inequality can be generalized to non-differentiable functions. Suppose we know: $$\begin{aligned} u(t) \le \alpha(t) + \int_0^t \beta(s) \: u(s) \dd{s} \end{aligned}$$ Where $\alpha(t)$ and $\beta(t)$ are known. Then the **Grönwall-Bellman inequality** states that: $$\begin{aligned} \boxed{ u(t) \le \alpha(t) + \int_0^t \alpha(s) \: \beta(s) \exp\!\bigg( \int_s^t \beta(r) \dd{r} \bigg) \dd{s} } \end{aligned}$$
In the special case where $\alpha(t)$ is non-decreasing with $t$, the inequality reduces to: $$\begin{aligned} \boxed{ u(t) \le \alpha(t) \exp\!\bigg( \int_0^t \beta(s) \dd{s} \bigg) } \end{aligned}$$
## References 1. U.H. Thygesen, *Lecture notes on diffusions and stochastic differential equations*, 2021, Polyteknisk Kompendie.