THE IMAGE SPEED DURING THE OPTICAL-ELECTRONIC SURFACING THE PLANET

In this paper, a formula is obtained for calculating the velocity of an image in the plane of image fixation during a space survey of the planet's surface with the aid of an on-oard optoelectronic device. The ideal task is considered: the Earth is modeled by an absolutely rigid homogeneous ball, rotating uniformly around the fixed axis, and the satellite's center of mass describes a fixed Keplerian orbit, in one of the focal points of which the center of the Earth is located. The axis of sight has a direction in the nadir, i.e. passes through the center of the Earth. The main focus of the "cosmic camera" is in the center of mass of the satellite P, and the plane of fixation of the images is perpendicular to the viewing axis and is located at the focal distance d behind the point P. The obtained analytical formula for calculating the velocity field of motion of image points in the model problem under consideration when shooting in a nadir is of fundamental importance for solving the inverse problem when reconstructing a "blurred" image. The formula is important for calculating and optimizing the parameters of the compensators used in practice to "smear" the image. In addition, the resulting formula is useful for verifying numerical algorithms that model the "smear" effect. It can be used in planning work programs for remote sensing of the Earth.

satellite, Keplerian orbit, speed of image movement, nadir, spacecraft, remote sensing of the Earth

1. Butyrin S.A. Kinematic synthesis of the software angular motion of the spacecraft in the optoelectronic survey of the Earth // Izvestiya Samarskogo nauchnogo tsentra Rossiyskoy akademii nauk (Bulletin of Samara Scientific Center of the Russian Academy of Sciences). 2007. V. 9. № 3. P. 664−670. (in Russ.)

2. Butyrin S.A. Software complex for calculation and visualization of routes of opticalelectronic survey of the Earth // Izvestiya Samarskogo nauchnogo tsentra Rossiyskoy akademii nauk (Bulletin of Samara Scientific Center of the Russian Academy of Sciences). 2007. V. 2. P. 11−17. (in Russ.)

3. Mashtakov Ya.V., Tkachev S.S. Construction of the angular motion of an Earth remote sensing satellite while tracing the routes on the Earth's surface // Preprints of Keldysh Institute of Applied Mathematics RAN. 2014. № 20. 31 p. (in Russ.)

4. Tikhonov A.N., Goncharsky A.V., Stepanov V.V. Inverse problems of image processing / In: Incorrect Tasks of Natural Science. Moscow: MSU Publishing House, 1987. P. 185−195. (in Russ.)

5. Duboshin G.N. Celestial Mechanics. Main tasks and methods. Moscow: Nauka Publ., 1975. 800 p. (in Russ.)

6. Murray C.D., Dermott S.F. Solar System Dynamics. Cambridge University Press, 1999. 606 p.

7. Vilke V.G. Theoretical Mechanics: a textbook and a practical work for academic baccalaureate. Moscow: Yurait Publ., 2016. 311 p. (in Russ.)

8. Zhilenev M.Yu., Vintaev V.N. The formula for calculating the image motion of the planets with orbital shooting optoelectronic equipment // Telecommunications (Telecommunications and Radio Engineering). 2011. № 7. P. 2−7. (in Russ.)