XMM-Newton Users Handbook

next up previous contents
Next: 3.4.2 RFC chip arrays Up: 3.4 REFLECTION GRATING SPECTROMETER (RGS) Previous: 3.4 REFLECTION GRATING SPECTROMETER (RGS)

3.4.1 Diffraction Geometry

The diffraction geometry of the reflection gratings is illustrated in Fig. 76. Light strikes the gratings at an angle of incidence $\alpha $ with respect to the plane of the grating, and emerges at angle $\beta$ given by the dispersion equation


\begin{displaymath} \cos \beta = \cos \alpha + m \lambda / {\rm d} \end{displaymath} (1)

where $\lambda$ is the radiation wavelength, d the grating spacing, and m the spectral order. The RGS is designed for use with negative orders, $\beta > \alpha$.

Figure 76: Schematic drawing of a grating, including some of the key dispersion angles.
\begin{figure} \begin{center} \epsfig{width=.52\hsize,file=figs/rgs_grating.ps} \end{center} \end{figure}


European Space Agency - XMM-Newton Science Operations Centre