© Special Astrophysical Observatory of the Russian Academy of Sciences
designed by GGA
The instrument setup at R=100.000 enables the observation of stars in the 11m-12m range under normal weather conditions (with a seeing quality ~1.5”) using one-hour exposures and achieving a signal-to-noise ratio of 100. The expected ultimate accuracy for radial velocity measurements of cool stars is 1 m/s or better, while the precision for magnetic field measurements of cool stars is anticipated to be 1 G or better. In its final configuration, the spectrograph will be equipped with an interferometric control system utilizing a vacuum-stabilized Fabry-Perot interferometer to achieve exceptionally high wavelength calibration precision of 50 cm/sec.

The Spectrograph Design

The design of the spectrograph is founded on the traditional optical configuration referred to as the "white pupil" (Dekker et al. 2000). Unlike conventional spectrograph designs, the "white pupil" offers several significant benefits. Key advantages include a reduction in the entrance aperture of the projection camera and minimized stray light. The optical arrangement of the spectrograph is illustrated above (for further details, see Valyavin et al. 2014) and comprises the following components: Slit assembly 1 fed with five fiber terminations Off-axis main collimator 2 and transfer collimator 5 with parabolic- shaped surfaces Mosaic of two echelle gratings 3 Flat mirror 4 Cross disperser 6 -- a combination of a prism and a grating CCD detector 8 Focusing camera 7

Parameters

Collimator -- focal distance 2175 mm, diameter 187 mm Echelle gratings’ blaze angle -- 75.5° (R4). Cross disperser prism’s glass -- PBM2Y Ohara Cross disperser grating -- 200 groovs/mm operating in the first order. The refraction angle -- 40° CCD detector -- 4k x 4k chip with a pixel size of 15 μm (http://www.e2v.com) Focusing camera -- a F/2.35 lens combination consisting of six spherical optical elements with an effective focal length of 470 mm.

References

Dekker et al. 2000 // Dekker, H., D’Odorico, S., Kaufer, A., Delabre, B., & Kotzlowski, H. 2000, Proc. SPIE 4008, 534 Valyavin et al. 2014 // Valyavin, G. G., Bychkov, V. D., Yushkin, M. V., Galazutdinov, G. A., Drabek, S. V., Shergin, V. S., Sarkisyan, A. N., Semenko, E. A., Perkov, A. V., Sazonenko, D. A., Kukushkin, D. E., Bakholdin, A. V., Burlakova, T. E., Kravchenko, V. M., Kudryavtsev, D. O., Pritychenko, A. M., Kryukov, P. G., Semjonov, S. L., Musaev, F. A., & Fabrika, S. N. 2014, Astrophysical Bulletin, 69, 224
Main Parameters Data Processing News Gallery
© Special Astrophysical Observatory of the Russian Academy of Sciences
designed by G.A. Galazutdinov
The instrument setup at R=100.000 enables the observation of stars in the 11m-12m range under normal weather conditions (with a seeing quality ~1.5”) using one-hour exposures and achieving a signal-to-noise ratio of 100. The expected ultimate accuracy for radial velocity measurements of cool stars is 1 m/s or better, while the precision for magnetic field measurements of cool stars is anticipated to be 1 G or better. In its final configuration, the spectrograph will be equipped with an interferometric control system utilizing a vacuum-stabilized Fabry-Perot interferometer to achieve exceptionally high wavelength calibration precision of 50 cm/sec.

The Spectrograph Design

The design of the spectrograph is founded on the traditional optical configuration referred to as the "white pupil" (Dekker et al. 2000). Unlike conventional spectrograph designs, the "white pupil" offers several significant benefits. Key advantages include a reduction in the entrance aperture of the projection camera and minimized stray light. The optical arrangement of the spectrograph is illustrated above (for further details, see Valyavin et al. 2014) and comprises the following components: Slit assembly 1 fed with five fiber terminations Off-axis main collimator 2 and transfer collimator 5 with parabolic- shaped surfaces Mosaic of two echelle gratings 3 Flat mirror 4 Cross disperser 6 -- a combination of a prism and a grating CCD detector 8 Focusing camera 7

Parameters

Collimator -- focal distance 2175 mm, diameter 187 mm Echelle gratings’ blaze angle -- 75.5° (R4). Cross disperser prism’s glass -- PBM2Y Ohara Cross disperser grating -- 200 groovs/mm operating in the first order. The refraction angle -- 40° CCD detector -- 4k x 4k chip with a pixel size of 15 μm (http://www.e2v.com) Focusing camera -- a F/2.35 lens combination consisting of six spherical optical elements with an effective focal length of 470 mm.

References

Dekker et al. 2000 // Dekker, H., D’Odorico, S., Kaufer, A., Delabre, B., & Kotzlowski, H. 2000, Proc. SPIE 4008, 534 Valyavin et al. 2014 // Valyavin, G. G., Bychkov, V. D., Yushkin, M. V., Galazutdinov, G. A., Drabek, S. V., Shergin, V. S., Sarkisyan, A. N., Semenko, E. A., Perkov, A. V., Sazonenko, D. A., Kukushkin, D. E., Bakholdin, A. V., Burlakova, T. E., Kravchenko, V. M., Kudryavtsev, D. O., Pritychenko, A. M., Kryukov, P. G., Semjonov, S. L., Musaev, F. A., & Fabrika, S. N. 2014, Astrophysical Bulletin, 69, 224
Main Parameters Data Processing News Gallery