CS267613B1 - Portable antenna - Google Patents

Abstract

The solution concerns the field of portable antennas, intended primarily for portable and mobile radio stations. The possibility of use is expected mainly in the implementation of simple antennas, used in the form of suspension and suitable for the purpose of supplementing the accessories of portable and mobile radio stations on all VHF bands. The mentioned antenna solves the problem of independent optimization of the RF separation of the surface of the coaxial antenna feeder on the one hand and the antenna impedance on the other hand, which is made possible by the different environment inside and outside the sleeve. The essence of the above solution of a portable antenna consisting of the upper and lower parts of a dipole radiator is that the upper part of the dipole radiator is formed by a section of the inner conductor of the power coaxial cable, which is coaxially placed in the place of the removed inner conductor of the outer coaxial cable in the section of its dielectric insulation, provided with an outer shielding sheath, with which the section of the protruding shielding of the power coaxial cable is in galvanic connection and forms the lower part of the dipole radiator with it. The total length of the dipole radiator is formed by the sum of the lengths of its upper part and lower part.

Description

The invention relates to a portable antenna for portable and mobile radio stations.

It is known that a sleeve dipole type antenna forms the upper and lower part of a dipole radiator, while in conventional self-supporting sleeve dipole antennas, where the dielectric medium of the sleeve is air, the outer length of the sleeve is the lower part of the dipole radiator, given practically by its electrical internal length, which ensures the separation of the antenna system itself from the carrier system. With this solution, the inner and outer length of the sleeve do not differ significantly electrically and mechanically. The disadvantage of such a solution is that the final adjustment of the antenna impedance can be done only by the length of the upper part of the radiator, because the length of the lower part of the radiator, the so-called sleeve is predetermined by the RF requirement. separation of the antenna system from the power supply system resp. carrier, which is also relatively complicated in terms of production.

The above solution is eliminated by the solution of the portable antenna according to the invention, the essence of which consists in that the upper part of the dipole radiator is formed by a section of the inner conductor of the coaxial power cable, stripped of its shielding sheath along the length of this conductor section. The coaxial power cable is coaxially placed in place of the removed inner conductor of the outer coaxial cable in the section of its dielectric insulation. The shielding sheath of the outer coaxial cable is galvanically connected to the section of the projecting shield of the supply coaxial cable and forms with it the lower part of the dipole radiator.

The advantage of the antenna solution according to the invention, the sleeve of which is formed by a section of coaxial cable with conventional dielectric insulation, is that the length of the lower part of the radiator and the inner length of the sleeve can be set independently, so that it is possible to optimize RF. separating the surface of the coaxial antenna feeder on one side and the antenna impedance on the other, which is made possible by different environments inside and outside the sleeve. Another advantage is the possibility of faster setting of the required parameters of the antenna and its easier production.

The portable antenna according to the invention will be described in more detail in an exemplary embodiment according to the attached figure. It consists of an upper and a lower part of a dipole radiator and essentially forms a sleeve dipole antenna. The upper part AI of the dipole radiator A is formed by an inner section. conductor 1b of the supply coaxial cable 2, stripped in the length of the section of the inner conductor 1b of the shield 1a. Coaxial cable 2 »which at its upper end with a coupling member 2 ^and the lower end of the connector 2, ^e j coaxially mounted on the extracted points of the inner conductor of the outer coaxial cable in the region of its two dielectric isolation. The shielding sheath of the outer coaxial cable, with which the section of the projecting shield 1aa of the supply coaxial cable 2 P ° is in the galvanic connection 31 and forms with it the lower part A2 of the dipole radiator A.

Next, a practical embodiment of a portable antenna according to the invention will be described, consisting of an upper part A1 and a lower part A2 of a dipole radiator and essentially forming a sleeve dipole type antenna. In its implementation, it is advantageous that the section of dielectric insulation 2 provided with the outer shielding sheath 2, the so-called sleeve, is formed from a section of coaxial cable from which the inner conductor has been removed and replaced with a coaxial supply cable 2 of corresponding diameter. The total length of the lower part A2, the dipole radiator 2 J ^e sum of the length of the outer shielding shell so. Sleeve formed from the shield of the outer coaxial cable and the length of the portion protruding shielding laa power coaxial cable 2 · ° d space galvanic connection 31 with the upper edge of the sleeve, towards the upper parts A1 of the dipole radiator 2 · Since the lower part A2 of the dipole radiator 2 ^{and the} inner length of the outer shield 2, the so-called sleeve can be set independently, the high-frequency surface separation of the power coaxial cable 2 ^{and the} antenna impedance can also be set independently. This is made possible by different environments inside the quarter-wave sleeve, where the internal environment is dielectric insulation s £ 1, which shortens the actual electrical line length, and outside the quarter-wave sleeve, where the external environment is air s £ = 1, which does not affect the electrical length of the outer sleeve surface. .

CS 267 613 Bl

The optimal parameters of the sleeve dipole antenna are determined by the total length of the dipole radiator A, the mutual ratio of the lengths of its lower part A2 and upper part A1 and further electrical length of the inner space of the outer shield 2, the so-called sleeve. antenna passing through it coaxially. The portable antenna according to the invention can be used to construct a multi-element antenna to form its dipole emitter A.

The mentioned solution enables the realization of simple antennas, used in the form of suspension, suitable especially for purposeful addition of accessories of portable and mobile radio stations on all VHF bands.

Claims (1)

A portable antenna consisting of an upper and a lower part of a dipole radiator which form a sleeve dipole antenna, characterized in that the upper part (AI) of the dipole radiator (A) is formed by a section of the inner conductor (1b) of the coaxial power cable (1) placed in place of the removed inner conductor of the outer coaxial cable in the dielectric insulation section (2) of the outer coaxial cable, the shield sheath (3) of which is in galvanic connection (31) with the section (laa) of the projecting shield of the supply coaxial cable (1) lower part (A2) of the dipole radiator (A).