I'm reading an article which claims the following result :
if $f : \mathbb{R}^{2} -> R$ is of the form : $\sin (N x_{1}) h (g^{-1}(x)) $ where $x = (x_{1},x_{2})$, $g$ is a diffeomorphism and h is $C^{\infty}$ and compactly supported on $[0,1]^2$ , then if we use the notation $<u> = \sqrt{1 + |u|^{2}}$ and $N_{1} = \pi* N *(1,0)$ then the Fourier Transform of f is such that, for all $M>0$ it exists $C_M$ so : 
$\widehat{f}(\omega) \leq C_{M}. \big( <\omega - N_{1} >^{-M} + <\omega + N_{1} >^{-M} \big)$
knowing that Fourier transform is defined as follows : 
$\widehat{f}(\omega ) = \int \exp(-ix.w)f(x)dx$
I was wondering which mathematical result could justify this estimation. Is it Payley-Wiener theorem ?


Here is a link to the article : (page 9) http://www.waveatom.org/papers/WaveatomsImage.pdf 

Thank you for your help .