RU80021U1 - SURFACE ELECTROMAGNETIC WAVE RADAR STATION - Google Patents

Abstract

The technical solution (utility model) relates to radar, in particular, to the design of radar stations on a surface electromagnetic wave. The essence of the claimed technical solution lies in the fact that in a radar station on a surface electromagnetic wave containing a transmitter, transmitting and receiving transducers of an electromagnetic wave to a surface electromagnetic wave and vice versa, an underlying surface, a transmission line of a surface electromagnetic wave, a receiver, transmitting and receiving transducers are made in in the form of an antenna of one or more emitters located on the underlying surface, while the transmission line of the surface hydrochloric electromagnetic wave is a continuation of the underlying surface and the underlying surface and the transmission line of the surface electromagnetic wave is a boundary between two media, where complex dielectric constant ε 'of the second medium is determined by the formula (ε' = ε ₂ -i60 λ σ _2), and the value (60 λ σ ₂ ) is greater than ε ₂ , where λ is the working wavelength, σ ₂ is the specific conductivity of the second medium, ε ₂ is the relative dielectric constant of the second medium. 8 cpf, 1 ill.

Description

The technical solution (utility model) relates to radar, in particular, to the design of radar stations on a surface electromagnetic wave.

A known radar station on a surface electromagnetic wave (SEW), comprising, a transmitter, transmitting and receiving converters of an electromagnetic wave into a surface wave and vice versa, an underlying surface, a transmission line of a surface electromagnetic wave, a receiver, wherein the transmitting and receiving converters are made in the form of an antenna from one or several emitters located on the underlying surface, made in the form of a metal or metallized structure of arbitrary shape and ol transverse, sectional surface wave transmission line is a boundary between two media and is a continuation of the underlying surface. [one].

The disadvantage of this station is its low efficiency, due to the ineffective coordination of the underlying surface and the transmission line of sew.

The closest technical solution to the claimed one is a radar station on a surface electromagnetic wave, containing a transmitter, transmitting and receiving transducers of an electromagnetic wave to and from a surface wave, an underlying surface, a transmission line of a surface wave, a receiver, wherein the transmitting and receiving transducers are made in the form of an antenna from one or more emitters located on the underlying surface, made in the form of a metal or metallized structure and arbitrary shape and

arbitrary cross-section, the surface wave transmission line represents the interface between two media and is a continuation of the underlying surface. [2].

The disadvantage of this station is its low efficiency, due to the inefficient excitation of the SEW and the ineffective coordination of the underlying surface and the transmission line of the SEW at the junction.

The claimed technical solution is based on the task of creating such a radar station on a surface electromagnetic wave, which will provide greater efficiency due to more efficient excitation of SEWs and coordination of the underlying surface and transmission line of SEWs at their junction.

The essence of the claimed technical solution lies in the fact that in a radar station on a surface electromagnetic wave containing a transmitter, transmitting and receiving transducers of an electromagnetic wave to a surface electromagnetic wave and vice versa, an underlying surface, a transmission line of a surface electromagnetic wave, a receiver, transmitting and receiving transducers are made in in the form of an antenna of one or more emitters located on the underlying surface, while the transmission line of the surface hydrochloric electromagnetic wave is a continuation of the underlying surface and the underlying surface and the transmission line of the surface electromagnetic wave is a boundary between two media, where complex dielectric constant ε 'of the second medium is determined by the formula (ε' = ε ₂ -i60 λ σ _2), and the value (60 λ σ ₂ ) is greater than ε ₂ , where λ is the working wavelength, σ ₂ is the specific conductivity of the second medium, ε ₂ is the relative dielectric constant of the second medium.

Figure 1 shows a radar station on the sew.

The radar station on the SEW contains a transmitter 1, transmitting 2 and receiving 3 transducers of electromagnetic waves to the surface and back, the underlying surface 4, transmission line 5, receiver 6.

Transmitting 2 and receiving 3 converters of electromagnetic waves in

surface are located on the underlying surface 4, while the transmission line 5 of the surface electromagnetic wave is a continuation of the underlying surface 4, and the underlying surface 4 and the transmission line 5 of the surface electromagnetic wave are the interface between two media, and the complex permittivity ε 'of the second medium is determined by the formula (ε '= ε ₂ -i60 λ σ _2), a value (60 λ σ ₂₎ is greater than ε _2, where λ - the working wavelength, σ ₂ - conductivity of the second medium, ε ₂ - relative permittivity about itsaemost second medium. In some cases, for more efficient excitation of SEW, the underlying surface 4 is made in the form of a metal or metallized structure (including a metal mesh) of arbitrary shape and arbitrary cross section. It is advisable and more economical to perform the underlying surface 4 in the form of a coating, which is a thin (not less than the thickness of the skin layer) film. It can also be a paint with a metal powder having a high conductivity. The underlying surface 4 is an area essential for the excitation of surface electromagnetic waves, having a high relative conductivity σ for a given working wavelength λ.

When designing a radar station on the SEW, located on stationary or mobile marine and ocean objects, it is reasonable to use a sea or ocean surface with high conductivity as the underlying surface 4 and transmission line 5. Transmitting 2 and receiving 3 converters are made in the form of an antenna from one or more emitters located on the underlying surface 4. In some cases, it is advisable to at least one of the transducers of the electromagnetic wave to the surface to perform in the form of one or more log-periodic antennas, in the form of one or more asymmetric vibrator antennas with a top load, in the form of one or more mirror antennas, in the form of one or more microstrip antennas, in the form of one or more active ph th e antenna array (AESA). Use of these antennas

allows in each case (in a given range of operating frequencies) to provide a more efficient excitation and propagation of SEW and, thereby, increase the efficiency of the radar station on the SEW.

The transmission line 5 SEW is a macrostrip transmission line and, by analogy with other types of transmission lines of electromagnetic energy, requires coordination at the junction. In this case, matching of the underlying surface 4 with the transmission line 5 at the junction should be ensured. It is most important to ensure coordination when the electrical parameters (for example, conductivity) of the underlying surface 4 and transmission line 5 are significantly different. It is advisable to ensure a smooth transition from the point of view of excitation and propagation of SEW at the junction of the underlying surface 4 and transmission line 5. It is known that SEW is most effectively excited at the interface made in the form of a dielectric above the screen. By analogy, it is reasonable to connect the transmission line 5 and the underlying surface 4 so that the transmission line 5 will be on the underlying surface 4 at the initial section of the junction. In the case of the coastline of the sea, a smooth matching transition can be achieved by tilting the underlying surface 4 relative to the horizon in the initial section, exceeding the length of the tide - ebb zone.

Thus, the proposed technical solution allows for greater efficiency of the SEW radar both due to the use of more efficient electromagnetic wave transducers in the SEW, and due to the matching of the underlying surface with the transmission line at their junction.

Information sources.

1. RF patent No. 48075, cl. G01S 13/00 by application No. 2005113146 of April 29, 2005

2. RF patent No. 71448, cl. G01S 13/00 on the application No. 2007138177 of 10/15/2007 - the prototype.

Claims (9)

1. A radar station on a surface electromagnetic wave, comprising a transmitter, transmitting and receiving converters of an electromagnetic wave into a surface electromagnetic wave and vice versa, an underlying surface, a transmission line of a surface electromagnetic wave, a receiver, characterized in that the transmitting and receiving converters are made in the form of an antenna from one or several emitters located on the underlying surface while the transmission line of the surface electromagnetic wave is a longitudinal HAND underlying surface and the underlying surface and the transmission line of the surface electromagnetic wave is a boundary between two media, where complex dielectric constant ε 'of the second medium is determined by the formula (ε' = ε ₂ -i60λσ _2), and the value _{2 is} greater 60λσ ε _2, where λ is the working wavelength, σ ₂ is the specific conductivity of the second medium, ε ₂ is the relative dielectric constant of the second medium. 2. A radar station on a surface electromagnetic wave according to claim 1, characterized in that the underlying surface is made in the form of a metal or metallized structure of arbitrary shape and arbitrary cross section. 3. A radar station on a surface electromagnetic wave according to claim 1, characterized in that the underlying surface and the transmission line of the surface electromagnetic wave is a sea or ocean surface. 4. The radar station on a surface electromagnetic wave according to claim 1, characterized in that the interface of the transmission line of the surface electromagnetic wave at the junction with the underlying surface at its initial section is located on the underlying surface, while the specific conductivity of the second medium forming the underlying surface, greater than or equal to the specific conductivity of the second medium forming the transmission line of the surface electromagnetic wave at the junction. 5. A radar station on a surface electromagnetic wave according to claim 1, characterized in that at least one of the transducers of an electromagnetic wave to a surface electromagnetic wave is made in the form of one or more log-periodic antennas. 6. The radar station on a surface electromagnetic wave according to claim 1, characterized in that at least one of the converters of the electromagnetic wave into a surface electromagnetic wave is made in the form of one or more asymmetric vibrating antennas with an upper load. 7. A radar station on a surface electromagnetic wave according to claim 1, characterized in that at least one of the transducers of an electromagnetic wave to a surface electromagnetic wave is made in the form of one or more mirror antennas. 8. A radar station on a surface electromagnetic wave according to claim 1, characterized in that at least one of the transducers of an electromagnetic wave to a surface wave is made in the form of one or more microstrip antennas. 9. A radar station on a surface electromagnetic wave according to claim 1, characterized in that at least one of the transducers of an electromagnetic wave to a surface wave is made in the form of one or more active phased antenna arrays.