What is the relationship between the sinc function and the Dirichlet kernel:
$$ \operatorname {sinc} (x)={\frac {\sin(x)}{x}} $$
$$ D_n(x)=\sum_{k=-n}^n e^{ikx}=1+2\sum_{k=1}^n\cos(kx)=\frac{\sin\left(\left(n +1/2\right) x \right)}{\sin(x/2)} $$
I'm primarily interested in their applications in Harmonic Analysis.
Thank you for your help!
You can think of the Dirichlet kernel as a periodic version of the sinus cardinalis: one the one hand $D_n$ is obviously periodic (with period $2\pi$). On the other hand, if $n$ is large and $x$ is small holds:
$$ \frac{\sin\left(\left(n +1/2\right) x \right)}{\sin(x/2)} \approx \frac{\sin\left(\left(n +1/2\right) x \right)}{x/2} = \frac{(n+1/2)}{2}\text{sinc}((n+1/2)x) $$
I.e. locally around $0$ it looks like a scaled sinc function. The same argument holds of course for any point $x=2\pi k$, $k\in\mathbb Z$.
Cf. this article What is the sum of a sinc function series sampled periodically . This article excellently describes the relation between the sum of a periodic sinc sampling function and the Dirichlet kernel function.
