RU2018109031A

RU2018109031A - METHOD FOR REMOTE DETECTION AND SUPPORT OF RADIO-SILENT OBJECTS

Info

Publication number: RU2018109031A
Application number: RU2018109031A
Authority: RU
Inventors: Валерий Николаевич Шевченко; Игорь Владимирович Донец; Яков Аронович Рейзенкинд
Original assignee: Акционерное общество "Всероссийский научно-исследовательский институт "Градиент" (АО "ВНИИ "Градиент")
Priority date: 2018-03-13
Filing date: 2018-03-13
Publication date: 2019-09-16
Also published as: RU2018109031A3; RU2716006C2

Claims

1. A method for remote detection and tracking of radio-silent objects, which consists in selecting a transmitter emitting a spread spectrum radio signal, synchronously receiving a multi-beam radio signal from the N antennas, including the direct radio signal of the transmitter and the radio signals of this transmitter scattered by the objects, synchronously converting the radio signals received by the antennas into digital signals s _n, where n - the number of the antenna, which are stored and combined in the digital signal matrix S = {s _{_1, ..., s n, ...,} s N} T, which is formed of Dig oic direct signal s ', characterized in that the transformed line signal s' in a single-frequency matrix signals of complex phasing function A _ω, each of which includes a hypothetical signals scattered potential mobile and stationary objects in the expected areas of the delays and the angular directions on each of the expected frequency Doppler shift ω, the matrix signals A _{ω are} stored, the stored digital signals of the antennas s _n are combined into a vector signal

, the vector signal s is stored and converted into a signal of an element of a complex spatial-frequency-time-image for a zero value of ω = 0 Doppler frequency shift

where

- a Hermitian conjugate matrix with A ₀ using a signal

as an initial approximation, an auxiliary matrix signal depending on the previous solution is iteratively generated and stored

where

- z - i component of the image element vector

, k = 1, 2, ... is the iteration number, as well as the signal of the next approximation of the element of the complex spatial-frequency-temporal image

, where λ is the Lagrange multiplier, and the vector signal purified from the direct and scattered by stationary objects signals

until the current iteration number exceeds the specified threshold K, then from the cleared vector signal

for each expected non-zero value of the Doppler frequency shift ω form an initial approximation signal

, and then iteratively receive and store the auxiliary matrix signal

and the signal of the next approach

element of a complex spatio-frequency-temporal image until the current iteration number exceeds a predetermined threshold K, the generated image element signals are combined

into the matrix signal of the resulting complex spatio-frequency-temporal image H, after which the local maxima of the square of the module module of the matrix signal of the resulting image

where

-

component of the matrix signal H, determine the number of scattered radio signals, the parameters of which are the values of the Doppler frequency shift ω, time delay q and azimuth-elevation direction of reception

each scattered radio signal performs the detection, spatial localization and tracking of objects.