RU2595566C2 - Method of adjusting impedance of antenna feeder device - Google Patents

Abstract

FIELD: radio engineering and communication.

SUBSTANCE: during adjustment of impedance in AFD are placed along AFD radiator matching elements, which are made in form of two metal plates and current-conducting rubber gasket between them; to vary impedance variation of dimensions and selection of type of current-conducting rubber, from which there is a gasket, wherein each of matching elements fixed current-conducting rubber gasket and is integrated in distributed impedance line, where matching elements are connected in parallel in a coaxial line, as a result, each matching element has contact with another matching element by means of connection to centre conductor of coaxial transmission line with radiating braiding each of matching elements has contact to radiating braiding.

EFFECT: technical result is providing broadband matching impedance of antenna with output impedance of transmitter in a band covering 1:20; best matching antenna feeder device (AFD) in a wide range; and highest structural strength of self-bearing centre conductor.

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Description

The invention relates to antenna technology and can be used in small vibrator antennas for radio communications, navigation.

Closest to the proposed method is the method [1], comprising adjusting the impedance of the antenna-feeder device (AFU) by coating the metal emitter with a layer of magnetodielectric.

The disadvantage of the proposed method is the decrease in the efficiency of the AFU due to the presence in the design of dissipative elements.

The objective of the invention is the provision of broadband matching of the impedance of the antenna with the output impedance of the transmitter in the overlap band of 1:20.

The problem is achieved in that in the method of adjusting the impedance of the AFU, including the operation of placing along the emitter of the AFU matching elements, according to the invention, each matching element is made in the form of two metal plates and a conductive rubber gasket between them, while the impedance is changed by changing the dimensions of the gasket and choosing the type conductive rubber of which the gasket is made.

The figure shows the matching element, which is a self-supporting central conductor (1), a conductive strip (2) made of electrically conductive rubber, contact fasteners of a rubber strip (3), dielectric fasteners (4), as well as two metal plates.

The proposed method works as follows.

The AFU is made in the form of an open at the end of a coaxial transmission line containing a grounded self-supporting central conductor and a radiating braid, and the radiating part can be made of either a metal pipe of arbitrary cross-section or metal cables (wire version). Matching elements, each of which is a conductive rubber gasket (2), mounted on a self-supporting central conductor (1) and clamped between two metal plates, are combined in a distributed impedance line (LRI): each of the elements is in contact with the other by attaching to the central the conductor of the coaxial transmission line with a radiating braid, each of the elements also has contact with the radiating braid. The distribution of the impedance value of the matching elements along the length of the LRI is selected in such a way as to minimize the reflected wave from the open end of the coaxial line and thereby ensure the best AFU matching in a wide range. A distinctive feature is the parallel connection of LRI elements, which ensures the greatest structural strength of the self-supporting central conductor. When the matching elements are connected in series, their placement in the body of the self-supporting conductor and the weakening of the AFU design are inevitable.

Information sources

1. Levin B.M. "Vibrator antennas for shipborne radio communications." - St. Petersburg: Abris, 1998 - 440 s. S.142.

Claims (1)

A method of adjusting the impedance in an antenna-feeder device, including the operation of arranging matching elements along the AFU emitter, characterized in that each matching element is made in the form of two metal plates and a conductive rubber gasket between them, while the impedance is changed by changing the dimensions of the gasket and choosing the type of conductive the rubber from which the gasket is made, each of the matching elements being fixed by a conductive rubber gasket and combined into a line distributed th impedance, namely matching elements are connected in parallel to a coaxial line, thereby each matching element is in contact with another member by terminating connection to the center conductor of the coaxial transmission line to the radiating sheath, wherein each of the matching elements is in contact with the radiating sheath.

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