I am trying to deduce the dispersive estimate for free wave equation in $\mathbb{R}^{d+1}$ $$u_
{tt}-\Delta_{\mathbb{R}^d}u=0$$ The fundamental solutions are given by 
$K_t^0(x)=cos(t|\nabla|)\delta(x)$ and $K_t^1(x)=\frac{sin(t|\nabla|)}{|\nabla|}\delta(x)$. According to Tao's dispersive pde textbook, given a Scharwtz function $\phi(x)$, we have the following time decay
$$|K^0_t*\phi_\lambda(x)|\lesssim_{\phi,d}\lambda^d<\lambda t>^{-\frac{d-1}{2}}$$,
where $<y>=(1+|y|^2)^\frac{1}{2}$.
I am trying to deduce the above estimate using stationary phase method. Rewrite the LHS with Fourier transform, we get
$$LHS=\int_{\mathbb{R}^d}e^{it|\xi|+ix\cdot\xi}\hat\phi(\lambda^
{-1}\xi) d\xi$$
Since $D^2|\xi|$ degenerates in radial direction, in order to apply stationary phase I rewrote it in polar coordinates, where $\xi=rw, w\in S^{d-1}$
$$\int_0^\infty e^{itr}r^{d-1}\hat\phi(\lambda^{-1}r)\int_{S^
{d-1}}e^{irw\cdot x}dw dr$$
But I am not sure how to proceed from here.