@article{Zubkov_Kosovtsov_Shcherba_Petliuk_Yunda_2023, title={METHOD OF SELF-DEFENSE OF GROUND (SURFACE) OBJECTS FROM HIGH-PRECISION RADAR MEANS OF AIR SURVEILLANCE }, url={http://ric.zntu.edu.ua/article/view/274440}, DOI={10.15588/1607-3274-2023-1-1}, abstractNote={<p>Context it is caused by the need to search for scientific and technical ways to ensure the effectiveness of protecting ground (surface) objects from high-precision guided missile weapons.</p> <p>Objective it is a necessity to ensure effective self-defense of objects from radar homing means.</p> <p>Method. Electrodynamic modeling of Echo signals from spatially distributed objects, taking into account the features of their design and related operational limitations.</p> <p>Results. Based on the analysis of the shortcomings of the well-known method of protecting stationary objects from radar surveillance and damage, based on the simulation of an effective reflection center outside the physical dimensions of the object, a new method of countering high-precision measurement of coordinates of stationary and mobile ground (surface) objects is proposed. The technique is based on the spatial deformation of the location of the effective target reflection center with dynamics that exceed the inertial capabilities of the auto-observation contour of the attacking missile (projectile). A structural and functional scheme of technical implementation of the methodology based on the first proposed relationship of simple design and technological solutions is proposed and justified.</p> <p>Conclusions. The analytical model of Echo signals of spatially distributed ground (surface) objects was further developed, which takes into account the specifics of their design, and on its basis, for the first time, a universal method of self-defense of objects from radar home-leading devices was developed, which is implemented in a patented method and complex to exclude damage to protected objects.</p>}, number={1}, journal={Radio Electronics, Computer Science, Control}, author={Zubkov, A. M. and Kosovtsov, Y. M. and Shcherba, A. A. and Petliuk, I. V. and Yunda, V. A.}, year={2023}, month={Feb.}, pages={6} }