DE1920004A1 - Omnidirectional antenna system - Google Patents

Description

Omnidirectional antenna system The invention relates to an omnidirectional antenna system for the ultra-short wave range, especially for several television frequency ranges.

Certain antenna systems exist for radio and television reception usually from an antenna for the short-medium-long wave broadcast range and several antennas in the ultra-short wave television range.

Each television area has its own dipole antenna with directors and reflectors provided. The individual antenna dipoles are over crossovers coupled to a common antenna lead. There are more in front of the receiving device Crossovers provided in order to separate the frequency bands again and the assigned To supply input circuits of the receiving device.

These known antenna systems have a directional effect and must therefore be aligned to the assigned transmitter in order to achieve the antenna gain to be able to exploit. Such antenna systems can only be set up by a specialist can be carried out optimally with the aid of measuring devices.

The number of such antenna systems, which increases with the density of radio traffic, e.g. for the reception of several separate television programs, has led to that in many areas all elevated sites are already dense with such Antenna systems are occupied. These offer because of the apparent irregularity their emitter and reflector systems, which are often oriented in different directions an ugly sight. Since their parts are essential for good reception in the ultra-short wave range, especially with television, necessarily protrude above the roof structure of the building it is hardly possible to arrange them in such a way that they are out of the field of vision an observer on the ground or in the opposite building lie. It would therefore be highly desirable for such antenna systems to be so inconspicuous as possible and as regularly as possible.

It is the object of the invention to provide a broadcast antenna system for the ultra-short wave range, especially for several television frequency ranges create whose elements can be assembled by a non-specialist without alignment can be, which reduces the cost of decoupling means and which by a symmetrical design looks much nicer.

The omnidirectional antenna system for the ultra-short wave range, in particular For several television frequency ranges, according to the invention, consists of a broadband dipole and an antenna broadband amplifier directly downstream for the entire Frequency range, as well as coupled with the broadband dipole, to the individual frequency ranges coordinated district directors.

With this design of the antenna system, the district directors take over The selection and coupling of the various frequency bands is independent of the direction to the broadband dipole. It is no longer necessary to align the antenna system, because the antenna voltage emitted at the broadband dipole is almost independent of the angle of incidence the transmitter waves is. The all-round reception angle of 3600 is bought because the new antenna system does not provide any antenna gain. However, this can be done by the Broadband antenna amplifier directly downstream of the broadband dipole will. Since the antenna signals via the antenna broadband amplifier directly d it antenna crossovers are not required known he antenna systemsO The output signals of the antenna broadband amplifier can be chosen larger than the antenna signals of known antenna systems, so that the useful-to-noise ratio can be improved. The number of district directors does not play a role in the new antenna system, so that an expansion of the Antenna installation on a new frequency range poses no difficulty. Important in the design of the new antenna system is only that the broadband dipole is matched to the geometric center frequency of the entire frequency range.

r the formation of the district directors applies accordingly that they matched to the geometric center frequencies of the individual frequency ranges and that the mean circumference of a district director is approximately equal to the corresponding half a wavelength is designed.

Particularly good selection and coupling results were obtained with a Embodiment achieved, which is characterized in that the broadband dipole is designed as a cross dipole, its four half loops on a quarter and the two full loops to half the wavelength of the center frequency for the whole Frequency range are designed and that the circle directors as endlessly wound Circular coils are formed.

If you accept another small antenna loss, then you can the district directors are made much simpler. For example, they are like that manufacturable that they along as a multiple zigzag angled single turn of the circumference are formed.

The symmetrical design of the new antenna system and its spatial Arrangement are favored by having the district directors for the various Frequency ranges are arranged centrally around the broadband dipole and that they are staggered according to the size of their diameter in different planes around the broadband dipole are arranged. The district directors are aligned so that the levels of the individual turns of the circular coils spiraling progressively tangential to Circular path run the circle director and that the levels of the turns of the circle coils are aligned with the broadband dipole to ensure a sufficiently good coupling to achieve broadband dipole. The cross dipole as a broadband dipole is included advantageously from a sheet metal strip or a metallized plastic strip shaped.

This makes the new antenna system insensitive to direction improved that between the 90 ° offset half loops of the cross dipole shielding plates are inserted in the middle.

All the components of the new antenna system can be used in one Hermetically sealable housing can be accommodated. A corresponding constructive Design is characterized in that the circle directors in a hemispherical Plastic cover and housed by a round plastic cover plate are hermetically sealed and that the circle directors are on the inside of the Cover and the broadband dipole and the antenna broadband amplifier on the Inside of the cover plate are attached. The cover only receives one shot for the antenna mast, preferably in the middle of the round cover plate, through which the antenna lead is passed at the same time. The entire antenna arrangement however, it can also be connected directly to the roof structure with the cover plate will.

The antenna lead is then laterally at the transition between the Cover plate and the hemispherical cover hood led out.

A coaxial or flat band broadband cable is used as the antenna conductor used, which is connected directly to the output of the antenna broadband amplifier and is routed to the crossover network upstream of the receiver. These According to a further embodiment of the invention, antenna derivation can be carried out simultaneously the supply of the DC voltage for the antenna broadband amplifier take over.

Since the new antenna system no longer has a directional effect, enables you can also have multiple transmitters in one frequency range without adjusting the antenna elements can only be received by setting the receiving device.

The invention is based on an exemplary embodiment shown in the drawings explained in more detail.

1 shows the plan view of an antenna arrangement according to FIG Invention and FIG. 2 shows a section through the antenna arrangement according to FIG. 1.

The embodiment of an omnidirectional antenna system according to the Invention is for the frequency ranges I - VHF from 47 to 68 MHz, II-VHF from 87.5 up to 104 MHz, III-VFH from 174 to 230 MHz and IV / V-UHF from 470 to 860 MHz.

As can be seen from the section according to FIG. 2, all components are the new antenna arrangement in a hermetically sealed housing. This case consists of a round plastic cover plate 17 and a hemispherical one Plastic cover 18.

On the cover plate 17 is the broadband antenna amplifier 12 and the broadband dipole 10 attached.

The broadband dipole 10 is via the connection cable 11 directly with the Input of the antenna broadband amplifier 12 connected, while at the output of the antenna broadband amplifier 12 the antenna lead 13 is connected directly, the antenna is attached to the mast provided, then the round cover plate carries 17 preferably in in the middle a receptacle 19 for the antenna mast, which is the same as a screw receptacle can be formed. The antenna down conductor 13, which is a coaxial or flat band broadband cable can be, is also guided through this receptacle 19 of the cover plate 17 and then continues in the hollow antenna mast. Use suitable decoupling agents the antenna broadband amplifier 12, the DC supply voltage on the antenna down conductor 13 are transferred.

The antenna arrangement can also be installed directly with the cover plate without the antenna mast attached to the roof structure of the building. The recording 19 is omitted and the antenna lead 13 is laterally at the transition between the cover plate 17 and the hemispherical cover 18 carried out.

The broadband dipole 10 is made of a sheet metal strip or a metalized one Plastic tape shaped as a cross dipole with four half loops. This broadband dipole 10 is tuned to the entire frequency range from 47 to 860 MHz. The half loops are to a quarter of the wavelength of the geometric center frequency of approximately 200 MHz of this frequency range. A complete loophole that each other opposite half loops, is accordingly to half the wavelength designed for this center frequency. In order to achieve greater insensitivity to direction can reach between the half-loops of this KreRuz dipole offset by 900 10 shielding plates can be inserted in the middle. These shielding plates can be at the joint two adjacent half loops can be attached and then stand as a bisecting line between the half loops.

For the selection and coupling of the different frequency bands are so-called circle directors 14, 15, 16 arranged around the broadband dipole 10. How out Fig. 1 can be seen, these circle directors are as endlessly wound circular coils formed, the mean circumference to the geometric center frequency of the individual frequency band under consideration is tuned, i.e. approximately half of it Wavelength corresponds to this center frequency. The district director 14 is for the Frequency range IV / V-UHF from 470 to 860 MHz is provided and based on the geometric Center frequency tuned around 630 MHz. The district director 15 is for the Frequency range III-VHF from 174 to 230 MHz provided and based on the geometric Center frequency of about 200 der tuned. The two neighboring frequency ranges I and II for VHF and FM from 47 to 68 MHz and 87.5 to 104 MHz are via one common circle director 16 coupled to broadband dipole 10. This district director 16 is therefore extended to the geometric center frequency of approximately 70 MHz Frequency range from 47 to 104 MHz.

These district directors 14.15 and 16 assign according to theirs assigned center frequencies of different sizes. You can therefore, as especially FIG. 2 shows, in several planes corresponding to the size of the diameter staggered around the broadband dipole 10 are arranged centr4isch. The levels of individual turns of these circle directors run tangential to the circular path of the Circle director and are so inclined m Breitban @ Dipol 10 that the coupling to the Broadband dipole. is optimal. These llreiselJirelAtoroll 14,15 and 16 on the inside of the hood 18.

Should such an antenna system cover a wider frequency range the entire frequency range from 47 to 860 MHz can be extended, then is only another circle director with a correspondingly matched diameter in the plastic cover 18 accommodating0 The new antenna system does not provide any antenna gain.

However, the signals on the antenna lead are transmitted immediately downstream antenna broadband amplifier 12 so far amplified that a cheap Useful interference ratio can be achieved.

Favorable values are achieved when the number of turns a circle coil of a circle director is chosen as large as possible. If you let one additional antenna loss, then simpler circle directors can also be used that are angled several times in a zigzag shape only along their circumference are. The additional antenna loss can be caused by the downstream broadband antenna amplifier 12 to be balanced.

Claims (20)

Claims Omnidirectional antenna system for the ultra-short wave range, in particular for several television frequency ranges, consisting of a broadband dipole (10) and a broadband antenna amplifier (12) connected directly downstream for the entire Frequency range, as well as coupled with the broadband dipole (1Q), to the individual Frequency ranges (I-VHF, II-FM, III-VHF, IV / V-UHF) coordinated district directors (14,15,16). 2. Omnidirectional antenna system according to claim 1, characterized in that that the broadband dipole (10) on the geometric center frequency of the entire frequency range is matched. 3. Omnidirectional antenna system according to claim 1, characterized in that that the circle directors (14, 15, 16) on the geometric @ center frequencies of the individual frequency ranges are matched and that the mean circumference of a Circle director each to approximately half the wavelength of the assigned center frequency is designed. 4. Omnidirectional antenna system according to claim 2, characterized in that that the broadband dipole (10) is designed as a cross dipole, its four half loops on a quarter and its-two full loops on half the wavelength of the Center frequency are designed for the entire frequency range 5. Omnidirectional antenna system according to claim 4, characterized in that the cross dipole (10) consists of a sheet metal strip or a metallized plastic tape. 60 omnidirectional antenna system according to claims 4 and 5, characterized in that that between the half loops of the cross dipole (10) offset by 900 in the middle of the shielding plates are used. 7. Omnidirectional antenna system according to claim 3, characterized in that that the district directors (14,15,16) are designed as endlessly wound circular coils are. 8. Omnidirectional antenna system according to claim 7, characterized in that that the levels of the individual turns of this circle coils in a spiral progression run tangentially to the circular path of the circle director. 9. Omnidirectional antenna system according to claim 7 and 8, characterized in that that the number of turns of a circular coil is selected as large as possible. 10. Omnidirectional antenna system according to claim 1 to 9, characterized in that that the district directors (14,15,16) for the different frequency ranges are centric around the broadband dipole (10) are arranged0 11. Omnidirectional antenna system according to Claim 10, characterized in that the district directors (14,15,16) are staggered according to the size of their diameter in different planes around the broadband dipole (10) are arranged. 12. Omnidirectional antenna system according to claim 11, characterized in that that the levels of the turns of the circular coils are aligned to the broadband dipole (10) are. 13. Omnidirectional antenna system according to claim 10 to 12, characterized in that that the circle directors (14,15,16) in a hemispherical plastic cover (18) and hermetically sealed by a round plastic cover plate (17) Are completed. 14. Omnidirectional antenna system according to claim 13, characterized in that that the circle directors (14,15,16) on the inside of the cover (18) and the broadband dipole (10) and the broadband antenna amplifier (12) on the inside the cover plate (17) are attached. 15. Omnidirectional antenna system according to claim 1 to 14, characterized in that that the antenna lead (13) as a coaxial or flat band broadband cable directly turned on at the output of the Antelmen broadband amplifier (12) and up to the Receiving device upstream crossovers is performed. 16. Omnidirectional antenna system according to claim 1 to 15, characterized in that that the antenna cover (17, 18) is preferably in the middle of the round cover plate (17) carries a receptacle for the antenna mast, which also carries out the antenna derivation (13) is used. 17. Omnidirectional antenna system according to claim 1 to 16, characterized in that that the antenna broadband amplifier (12) receives the feed voltage via the antenna discharge line (13) is supplied. 18. Omnidirectional antenna system according to claim 3, characterized in that that the circle directors (14, 15, 16) are often angled in a zigzag shape Single turn is formed along the circumference. 19. Omnidirectional antenna system according to claim 13 and 14, characterized in that that the entire antenna arrangement with the cover plate (17) directly with the roof structure of the building can be connected and that the antenna discharge line (13) at the side of the transition led out between the cover plate (17) and the hemispherical cover (18) is. 20. Omnidirectional antenna system according to claim 1 to 19, characterized in that that for two adjacent individual frequency ranges in the entire frequency range a single circle director is used, whose center frequency is extended from the Frequency range is calculated.