DE4141783A1 - Car aerial for various frequency ranges - has single antenna rod with successive frequency range sections and parallel oscillation circuit for each higher frequency range - Google Patents

Abstract

The car aerial has a common antenna element (1) with the same foot point providing several different radiator sections for corresponding frequency ranges, the overall length of the antenna (1) corresponding to an even fraction of the operating wavelength for the lowest frequency range. The higher or highest frequency band section(s) has a parallel oscillation circuit acting as a blocking circuit for the higher frequency signals and as a low ohmic circuit for the lower frequency signals, provided by a conductor (5) parallel to the antenna element (1) and relatively insulated from the antenna line (3) and coupled to the corresponding antenna section at each end. The geometric length of the parallel oscillation circuit is defined by a given equation in terms of the mean operating wavelength. ADVANTAGE - Good reception characteristic for all frequency ranges.

Description

The invention relates to a rod antenna for motor vehicles, the simultaneously for the reception z. B. of radio broadcast signals in FM and in the AM area and for mobile radio (receiving and transmitting), e.g. B. in the C network and / or in the D network of the Deutsche Bundespost, is suitable, according to patent application No. P 41 02 845.

The principle of solution according to P 41 02 845 applies generally to Use of a single antenna element together for several, offset frequency bands. The as monopolies about portions designed on a conductive surface on the antenna element represent λ / 4 radiators that have a common base have and in their effective length by a parallel resonant circuit are limited for the assigned frequency range acts as a blocking circle. For the lower one This parallel resonant circuit has low impedance and frequency ranges interrupts the radiator sections assigned to the lower areas Not in terms of HF. The sections for the lower ones Frequency ranges on the radiator are measured from the common Base, so longer. The total effective length of the antenna element can e.g. B. 1/4 of the average operating wavelength of the lowest or a lower frequency range, just z. B. the FM range, correspond.

The multi-range antenna according to P 41 02 845 points to all Frequency ranges for which it is designed, excellent Radiant power on. It also has an inclined attachment (up to 40 ° inclination), e.g. B. on a vehicle roof, a good one Omnidirectional characteristic. Here is the circuitry comparatively small, and the antenna differs not externally of the usual radio broadcast antennas for Motor vehicles.

In connection with advanced theoretical and practical Investigations have now surprisingly shown that the principle according to P 41 02 845 is essentially generalizable Improvements in the basic structure of the antennas and enabled for conceptual design work.

As a result, the present invention has an object to further simplify the construction of the multi-range antenna, without adversely affecting the electrical properties be influenced, and also for the circuit arrangement Design principles for the predetermination and optimization of the Dimensional relationships in the different possible applications and conditions.

This object is achieved with the in the characterizing part of the features specified solved.

With the invention, the relationships between the line and the Field theory captured in such a way and for the representation of the  complex conditions even with an extremely simplified structure the circuit applied, the exact predetermination and Design of isolating and selection circuits especially for Antenna elements and the largely universal application of the Multi-range principles for different rod designs and also possible with different flat configurations.

The circuit effort can - in the sense of optimization - on one Minimum be reduced, and by recording and specifying the The proportion of parameters in an approximation equation becomes that is still indispensable in antenna development reduced empirical work.

The invention is described below with the aid of exemplary embodiments explained in more detail. Show in the accompanying drawing

Fig. 1: Application of the principle according to the invention in a short rod antenna with a coiled antenna conductor

• a) parallel resonant circuit at any point in the rod, without changes in the antenna wire spiral
• b) Arrangement for very high additional frequency range

Fig. 2: rod antennas - stretched antenna conductor - with parallel resonant circuit according to the invention

• a) with additional coil
• b) with a stretched ladder section
• c) with potty

Fig. 3: Base connection for a λ / 4 antenna

Fig. 4: Multi-range short rod antenna with flexible shaft, in an inclined version

Fig. 1 shows antenna elements 1 with a shorter than the effective length geometric length, as z. B. are known in automotive roof antennas. The actual antenna conductor 3 is wound onto the rod 2 made of a dielectric material. The stretched length of the antenna conductor 3 corresponds to 1/4 of the average operating wavelength λ₁ for radio broadcasting in the FM range. On the antenna element 1 - starting from the common base 4 - a radiator for mobile radio is divided, the effective length under certain conditions is advantageously equal to 1/4 of the average operating wavelength λ₂ for this frequency range. For this purpose, according to the invention, the elongated conductor part 5 is inserted axially parallel, preferably coaxially, into the rod 2 , ie inside the coil of the antenna conductor 3 . The conductor part 5 is, apart from the galvanic connection to the antenna conductor 3 at the end point 6 of the radiator section for mobile radio, insulated from the antenna conductor 3 . In the region of the length of the conductor part 5 l form - in simplistic approach - the conductor part 5, the capacitance and the inductance of the antenna conductor 3 a parallel resonant circuit which constitutes a trap for the mobile radio frequency range.

In the variant according to FIG. 1a, the conductor part 5 was inserted into the rod without the winding parameters of the antenna conductor 3 being changed. As FIG. 1b shows, there is of course the possibility of shortening the geometric length of the parallel resonant circuit arrangement by providing a closely wound region 31 of the antenna conductor as the inductor.

In the solution according to FIG. 1b, an antenna element 1 made of a plastic rod 2 with a coiled antenna conductor 3 was placed on a metallic rod part 71 . The antenna conductor 3 is galvanically connected to the rod part 71 at the beginning of the coil section 31 . At the same height, the ladder section 5 begins - the capacity. The electrical connection between rod part 71 and conductor part 5 is designated by 6 ; the conductor part 5 lies against the lateral surface of the rod 2 and is wound with the coil section 31 .

The radiator for the lower frequency range comprises the rod part 71 and the overlying region of the rod 2 with coil section 31 and coil 3 .

The solution of Fig. 1b lends itself when z. B. the effective length of the λ₂ / 4 section is very small and a short metallic rod part 71 does not affect the flexibility of the rod as a whole.

The axis dimension of the parallel resonant circuit - the length l of the conductor part 5 - results from the equation

Here are:
D mandrel diameter of the "coil" in the form of the coiled antenna conductor ( 3 ), here at the same time the diameter of the rod 2 ,
d diameter of the antenna conductor 3 ,
d _i diameter of the conductor part 5 ,
ε _r dielectric constant of the insulation between antenna conductor 3 and conductor part 5 ,
s slope of the antenna conductor helix

It is also conceivable to arrange the conductor part 5 axially parallel to the rod 2 outside the coil.

Fig. 2 shows variants of the application of the invention in a passive vehicle rod antenna. The geometric length of such a rod - as an elongated antenna conductor - usually corresponds to λ₁ / 4 for the FM range.

The radiator for the higher frequency range is HF-divided by a galvanic connection between the rod 7 and the additional axially parallel conductor part is also made here at the end point of the section with the effective length λ₂ / 4. Furthermore, the two conductors are insulated from each other by a dielectric.

Fig. 2a shows the rod 7 in combination with a coil 32. The rod section 72 , which is obtained by electrically interrupting the rod and conductor course in the region 73 , serves as the capacitance here. The dimension l is calculated according to the same equation as in the arrangement according to FIG. 1.

In Fig. 2b, the rod 7 is combined with an elongated conductor part 5. The mechanism of action for the parallel resonant circuit (and blocking circuit for the higher frequency range) can be explained here from the laws of wave resistance in two-wire lines.

The dimension l for this arrangement results in

Here are:
a center distance of rod 7 and ladder section 5 ,
d₁ diameter of the antenna rod 7 ,
d₂ diameter of the conductor part 5 .

In the variant according to FIG. 2c, the parallel resonant circuit - and blocking circuit for a higher frequency range - is formed by a blocking pot 8 in the line course of a passive rod antenna.

The dimension l results here

The second part of the equation, which in the present context is called L-C factor K is called and with which the different Field relationships in the basic, described here Variants are taken into account in the ideal conditions the locking pot solution is 1.

The locking pot solution can, as indicated, also with antenna elements with a coiled antenna conductor.

With FIG. 3, the inventive principle is illustrated for the Fußpunktanschluß.

The rod 2 of a λ / 4 antenna is mechanical and the antenna conductor 3 is galvanically connected to a metal plate 9 . The plate 9 is in turn galvanically contacted with the inner conductor 10 of a further coaxial cable 11 . At 12 , the antenna pad, for. B. a motor vehicle roof, and 13 denotes a plate made of a dielectric. Between the roof plate 12 (as a mass) and the metal plate 9 , a capacitance is formed via the dielectric 13 , which, according to the invention, is used particularly for the higher frequency range for the extremely precise adaptation of the antenna impedance to the impedance of the coaxial cable. The capacitance can be varied or specified and adjusted (adjusted) by selection of the dielectric, by the area of the metal plate 9 and by the distance h between the plate 9 and the roof plate 12 , ie the thickness of the dielectric material.

Fig. 4 shows an example of the application of the solution features according to the invention in a motor vehicle short rod antenna with a flexible shaft, which was originally designed only for radio broadcast reception and a geometrically shortened λ / 4 radiator for FM signals and a capacitive for AM signals Represents decoupling element. The antenna was subsequently modified for simultaneous radio broadcast reception and mobile radio (sending and receiving) without the outer structure being changed.

The reception quality in the radio area is determined by the arrangement in no way impaired; for mobile radio is a Antenna with excellent signal performance and - despite the strong Inclination - good omnidirectional characteristics required. (The inclination was adopted from the radio-only variant, and theirs Retention was a requirement).

An arrangement according to FIG. 3 was chosen as the common base.

The λ₁ / 4 element for the FM range is composed of a conductor piece 14 , the screw connection 15 , the spiral spring 16 and the coiled antenna rod 3 on the rod 2 , which are galvanically contacted throughout. The screw connection 15 is provided so that the antenna rod with bending shaft can be detached from the lower antenna part 17 .

As a λ₂ / 4 radiator for mobile communications, a section from the base point to the spring-side termination of the screw connection 15 has resulted. The blocking circuit for the frequencies of the mobile radio is - with the length l - formed by the conductor part 5 protruding into the spiral spring 16 and the section of the spiral spring in this area. The distance and the insulation between the spring 16 , which forms the coil in the region l, and the capacitance in the form of the conductor part 5 are thereby fixed and ensure that all parts of the bending shaft are completely cast into a casing 18 made of a rubber-elastic plastic, the gives the bending shaft the outer shape and also supports the mechanical action of the spring 16 .

The signals arrive via the coaxial cable 11 in the active antenna switch and from there - separately - to the radio and the radio telephone.

The exemplary embodiments shown here already indicate that the invention in realizing a variety of and combination options. There is all variants common that the constructional and the technological effort is low and that the conceptual and development work through the arithmetical preparation of essential determination steps is simplified.

Claims (1)

Motor vehicle rod antenna for several separate frequency ranges according to patent application No. P 41 02 845, in which on a common antenna element with the effective length of an even fraction of the wavelength for the lowest or lowest frequency range, with a common base point, one or more λ / 4- Radiators for higher frequency ranges are divided in that a parallel resonant circuit is implemented in the line course of the antenna element at the upper end of the section for the higher or for a higher frequency band, which acts as a blocking circuit for the higher frequency band and is low-resistance for the low-frequency signals, characterized by the following characteristics:

• - The parallel resonant circuit is formed
  by a conductor part ( 5; 32; 8 ), which is axially parallel to the antenna element ( 1; 7 ) and insulated from the antenna conductor ( 3; 31; 7; 72 ), arranged above the associated radiator section and at the end point ( 6 ) of the associated radiator section is galvanically connected to the antenna conductor ( 3; 7 ), and
  through the antenna element ( 1; 7 ) in the area of the conductor part, both with the common geometric length l,
• - The parallel resonant circuit consists of the pairing
  a coiled antenna conductor ( 3; 31 ) with an elongated conductor part ( 5 ) or with a locking pot ( 8 ), or
  of an elongated antenna conductor ( 7 ) with a coil ( 32 ) in an area ( 72 ) or with an elongated conductor part ( 5 ) or with a locking pot ( 8 )
• - The geometric length l of the parallel resonant circuit for a frequency band with the average operating wavelength λ₂ is determined in high approximation according to the equation
• - The LC factor K in the equation for dimension l is
  for the pairing of coiled antenna conductors ( 3; 31 ) and elongated conductor part ( 5 ) or elongated conductor part ( 72 ) and coil ( 32 ): for the pairing of elongated antenna conductors ( 7 ) and elongated conductor part ( 5 ): and for the arrangement with locking pot ( 8 ): K = 1,
• - The base connection ( 9 ) of the antenna element ( 1; 7 ) to ground is flat and, by a preselectable or adjustable distance h to the connection surface ( 12 ), forms a predeterminable capacitance for the higher or highest frequency range for coordination between the base impedance of the antenna element and the impedance of the coaxial cable ( 11 ) is used.