RU2015152359A - Resonance Radar - Google Patents

Claims (10)

1. Radar circular viewing, characterized in that it contains a stationary circular viewing antenna (SAKO) meter range EMW, including sector transmitting and receiving antennas oriented along the sides of the regular polygon, made with independent electronic scanning of the air space for reception and transmission, with frequency deviation in the region of frequencies of resonance of airborne objects (AT), and connected by resonant echo signals and radio interference signals to the signal inputs of the hardware cabin control and processing of radar signals directly, and by sounding signals (ZS) - with the hardware cabin through a multi-channel generator of sounding signals, the control and information inputs / outputs of the hardware cabin are connected by cable interface lines to a digital communication and data transmission radio station and the ground alien ”, and each sector transceiver antenna contains a transmitting antenna-feeder device (AFU) installed in one line on the mast antenna supports, receiving the true elevated AFU of the resonant echo signals and the receiving azimuthal AFU of the resonant echo signals. 2. The radar station according to claim 1, characterized in that the transmitting AFU of each sector antenna is a radiating antenna array with a vertical aperture of the antenna sheet, configured to simultaneously probe the space with a fan of spade-shaped radio beams in a sector of at least 90 ° in the azimuthal plane and in the sector 1.5-80 ° in the elevation plane and containing blocks of log-periodic vibrator antennas (LPAA) mounted vertically on the outer side of one common mast, each block of LPAA contains two crosswise mounted LPVA, powered from the corresponding channels of the multi-channel generator of high-frequency sounding signals (ZS). 3. The radar station according to claim 2, characterized in that the multi-channel generator of high-frequency ES is configured to generate, in each probe, the sensing of long and short resonant echo signals at the resonance frequencies of ballistic and aircraft HE, respectively. 4. The radar station according to claim 1, characterized in that the elevation receiving AFU of each sector antenna is made with a vertical opening of the antenna sheet and with the possibility of simultaneous reception of signals by a fan of shovel-like receiving radiation patterns (PDN) in a sector of at least 90 ° in the azimuth plane and in sector of 1.5-80 ° in the elevation plane and is a lattice of cross-shaped AE, placed vertically on one mast. 5. The radar station according to claim 1, characterized in that the azimuthal receiving AFU of each sector antenna is made with the azimuthal opening of the antenna sheet from cross-shaped antenna elements (AE), placed in horizontal rows on masts installed in one line, and each cross-shaped AE is two Nadenenko dipoles located perpendicular to each other and at an angle of 45 ° to the horizontal plane. 6. The radar station according to claim 1, characterized in that the hardware cabin contains interconnected by an interface communication line sector multichannel radio receivers for receiving resonant VO signals and interference from corresponding receiving sector antennas, a block of digital signal processing devices (DSP) and coordinate measurement HE, a unit for preparing radar data for external users of radar information (RLI), a unit for generating requests and processing signals “friend or foe”; stationary automated workstation (AWS) and remote operator AWS. 7. The radar station according to claim 6, characterized in that each sector radio receiver contains two blocks of multi-channel superheterodyne radio receivers for receiving and processing long and short resonant echo signals from ballistic and aircraft HE, and also contains a panoramic radio receiver with a frequency synthesizer connected via a signal input with the outputs of the receiving AFUs, and along the signal output with the DSP unit, and the amplifiers of the superheterodyne receivers are made logarithmic. 8. The radar station according to claim 6, characterized in that the DSP unit block is modular in design with programmable logic integrated circuits (FPGA) with reprogrammable memory and contains a control and data transmission server connected by interface lines, a DSP master and slave device, and a digital unit processing signals at frequencies f ₁ ^i, ₂ f ^i, respectively for each i-th sector circular scan, i = {1 ... 4}, synchronizer and input-output device for communication with the workstation, as well as - with external users and calculation GOVERNMENTAL. 9. The radar station according to claim 8, characterized in that each DSP master and slave device is equipped with two analog-to-digital converters (ADCs) of the DR-16 type, connected at the input to the outputs of the respective multi-channel radios, and at the output stream of digitized current instantaneous values radio signals - through the radar data preparation unit (RLD) with the control server, secondary processing of the RLD and data transmission, and the RLD preparation unit is equipped with a software device for digital forming of diagrams laziness (TSFDN) based on the assessment of the coherence of the echo signals received by each receiving AE AFU forming the total value of the vector of the received signal in each lobe fan TSFDN, calculating its maximum value and recording the angular direction BO on the maximum value of the total vector of the received signal. 10. The radar station according to claim 9, characterized in that the control server, secondary processing of the RLD and data transmission is made according to the scheme of an industrial electronic computer on two non-shell computers of the Core i7 series and two expanders - mezzanines of the 4 × 1 Gbit Ethernet and 4 series × RS422 with a block of reprogrammable Gard and Flesh memory.