Littrow expansion and its counterpart Littrow compression are optical effects associated with slitless imaging spectrographs. These effects are named after austrian physicist Otto von Littrow.[1]
In a slitless imaging spectrograph, light is focused with a conventional optical system, which includes a transmission or reflection grating as in a conventional spectrograph. This disperses the light, according to wavelength, in one direction; but no slit is interposed into the beam. For pointlike objects (such as distant stars) this results in a spectrum on the focal plane of the instrument for each imaged object. For distributed objects with emission-line spectra (such as the Sun in extreme ultraviolet), it results in an image of the object at each wavelength of interest, overlapping on the focal plane, as in a spectroheliograph.
The Littrow expansion/compression effect is an anamorphic distortion of single-wavelength image on the focal plane of the instrument, due to a geometric effect surrounding reflection or transmission at the grating. In particular, the angle of incidence
\thetai
\thetar
\thetar=-\thetai,
which implies
| d\thetar | |
| d\thetai |
=-1,
so that an image encoded in the angle of collimated light is reversed but not distorted by the reflection.
In a spectrograph, the angle of reflection in the dispersed direction depends in a more complicated way on the angle of incidence:
\thetar=-\arcsin(\sin(\thetai)+nλ/D),
where
n
λ
D
| d\thetar | |
| d\thetai |
\ne-1
for most values of
n
λ/D
For the special case where
nλ/D=-2\sin(\thetai),
the reflected ray exits the grating exactly back along the incident ray, and
d\thetar/d\thetai=1