WO2009012957A2

WO2009012957A2 - Rod antenna with different antenna conductor structures in places

Info

Publication number: WO2009012957A2
Application number: PCT/EP2008/005952
Authority: WO
Inventors: Peter Riedhofer
Original assignee: Hirschmann Car Communication Gmbh
Priority date: 2007-07-21
Filing date: 2008-07-21
Publication date: 2009-01-29
Also published as: DE102008033881A1; WO2009012957A3

Abstract

Rod antenna (1), which is designed for transmission and/or reception of radio-frequency signals, having an antenna pole (2), which has a mount on which an antenna conductor structure is arranged, wherein the mount together with the antenna structure is surrounded by a sheath and, at the end, the rod antenna (1) has an attachment element (2), characterized in that the rod antenna (1) is designed for transmission and/or reception of different frequency bands and, for this purpose, the antenna conductor structure is formed continuously on one piece and differently in places, wherein the design is dependent on the respective frequency band.

Description

Rod antenna with partially different antenna conductor structures

description

The invention relates to a rod antenna for mobile applications, which is designed for transmitting and / or receiving high-frequency signals.

Rod antennas for mobile applications, in particular for attachment to motor vehicles, are known in principle. These have at the end a fastener with which the rod antenna is attached to the motor vehicle. Based on this, there is an antenna rod which has an antenna conductor structure in its interior. For optimum transmission and / or reception of high-frequency signals in certain frequency bands, it is necessary to tune the length of the antenna rod to the frequency band to be received. For reception in the VHF frequency range, the length of the antenna rod at a lambda-quarter tuning (lambda = wavelength) is too large, as a result of the length of the antenna rod is too large. Therefore, the antenna conductor structure has been helically arranged to shorten the length of the antenna rod. Thus, the mechanical length of the antenna rod, for example, for the VHF frequency range of about 700 to 800 mm in length to 170 to 400 mm shortened. Another way of shortening the length of the antenna rod can be achieved by incorporating an inductance, in particular a concentrated inductance in the form of a coil in the vicinity of the foot (ie the fastening element). If the installation location of the same inductance is shifted in the direction of the end of the antenna rod, only a smaller shortening results. By adding further inductances, areas of the antenna rod for higher frequencies can be separated, which enable further resonances of the antenna rod as half-wave dipoles. For the first so-called lambda quarter resonance of the rod antenna applies: The Side effect of additional inductance in the antenna structure is that the bandwidth of the rod antenna disadvantageously decreases. Differently high installation positions of the additional inductance in the course of the antenna conductor structure of the antenna rod thus require a bandwidth of different widths. If the concentrated coil is mounted at a height such that the part of the antenna radiator located below the coil is a monopole for a higher frequency (or another frequency band), a rod antenna can be obtained with suitable dimensioning of the coil, with which one can split into two frequency bands can send and receive, but due to their construction in the lower frequency band narrowband fails (see also DE 44 33 724 C2).

The inductors used in the lower part of the radiator are already in self-resonance at the crossover frequency, ie the operating frequency of the lower part of the radiator. The parasitic capacitance of the coil together with the inductance forms a parallel resonant circuit.

In place of the inductors and blocking circuits are used, consisting of the inductance and a parallel-connected capacitance, which electrically separate the lower part of a rod antenna from the upper part.

Another way to provide an antenna with a second frequency band, which is approximately 1.5 to 2.5 times the fundamental frequency, is to give the upper part of the antenna a little more inductance. This shifts the natural, the fundamental frequency subsequent higher-frequency next resonance, which corresponds to a 3/4 lambda current assignment, down. The fundamental frequency is not shifted as much in proportion as the effective inductance in the upper part of the radiator is less effective for the low frequency. An effective option is the insertion of two inductors. An inductance close to the base of the radiator ensures effective shortening. In combination with this, a much larger inductance at the upper end of the radiator ensures a defined current distribution at a second useful frequency.

Despite a reduced geometric length, a current dip is formed for the first usable frequency at the base. For the next highest arbitrary, usable frequency corresponds, with conventional configuration (only one coil near the base) no current dip in the base would form, but a Strornrninirπum exist, which corresponds to a very high impedance, not adaptable to a cable impedance or amplifier impedance impedance.

The invention is based on the object to provide a rod antenna for mobile applications, which is designed for transmitting and / or receiving high-frequency signals, provide over known rod antennas, a precise control of the resonance frequencies and, to a limited extent, the bandwidths in the various frequency bands allowed and compared to known antennas is much easier to manufacture, since the known rod antennas require a complex assembly, as between the antenna conductor structure inductors and capacitors, which are to be handled as separate components (coils), arranged and switched (usually soldered) must be.

This object is solved by the features of claim 1.

By inserting the inductance at the upper end of the radiator, a second current dip is obtained in this region, so that a current dip is also formed at the base. First and second use frequency are not by a numerical factor, eg 3 as in conventional monopolies, with each other connected. Due to the position and value of the inductors, an arbitrary frequency ratio can be set.

According to the invention, the maximum and minimum achievable inductance values are first determined under the framework of antenna length, diameter of the antenna structure and conductor width or conductor diameter, maximum and minimum conductor spacing and surrounding dielectric. Physically meaningful is therefore an indication of the value in H / m (Henry per meter) for antennas extended in length. According to the invention, the positions and lengths of the different inductance ranges are then determined with a numerical field calculation such that a higher inductance value per meter is used in the upper range, so that the desired frequencies and bandwidths are established. During optimization, the power distributions described above are used as the reference curve for the optimization goal. The calculated distributed inductance values are then converted back into conductor distances and thus the geometry of the antenna is determined.

According to the invention, it is provided that the rod antenna is designed to transmit and / or receive a plurality of different frequency bands and for this purpose the antenna conductor structure is configured differently in sections, the design being dependent on the respective frequency band. According to the invention, the antenna conductor structure as a single component realizes both antenna radiators (sections of the antenna conductor structure for transmitting and / or receiving the high-frequency signals) and inductors and / or resonant circuits which separate the individual sections of the antenna conductor structure so as to be able to receive a plurality of different frequency bands. The essential advantage of the rod antenna according to the invention over the previously known rod antennas is that the antenna conductor structure realizes both antenna radiators and inductors and / or resonant circuits in a single component. As a result, with the antenna conductor structure, the vote on the respective Frequency bands as well as the production of the rod antenna are substantially simplified, so that the finished rod antenna receives more accurate and more flexible adjustable bandwidths for the different bands than previous different antenna conductor structures, which were interconnected by means of additional inductances high frequency.

To realize a rod antenna according to the invention, e.g. two possibilities conceivable, but the invention is not limited thereto. On the one hand, it is conceivable that the antenna conductor structure is formed as a meander-shaped conductor track which is arranged on a corresponding rigid carrier (printed circuit board) or flexible carrier (carrier foil), wherein the correspondingly formed carrier has a shape corresponding to the rod antenna.

Nowadays, elongated rod antennas having a circular or elliptical cross-section are standard, so the carrier foil may be tapered or cylindrically rolled to form the antenna rod and surrounded by the shell.

The further solution consists in that the antenna conductor structure consists of an antenna winding, which is wound onto the carrier with sections of different pitches and / or multiple windings for generating a radiator or an inductance and / or resonance circuits. Care must be taken to ensure that the wound areas are not galvanically connected so that no high frequency short circuit occurs. This is the case in particular in the areas in which an inductance or a resonance circuit is to be generated, for which purpose, for example, a lacquered copper wire is used.

A resonant circuit consists of an inductance and a parallel capacitance. As already described, the inductance is realized by a conductor structure which may be meandering or wound. A capacity consists of two ladders, between which a potential difference can occur. The smaller the distance between the conductors, the greater the capacity.

According to the invention, the capacitance mechanically also consists of a conductor structure which, however, is not contained separately but in the overall structure or winding, i. There are no additional mechanical or electrical components needed. It is possible to precisely define the capacitance value by selecting the arrangement or winding parameters and to select the resonance frequency accurately together with the inductance value.

Embodiments of the invention, to which, however, is not limited, are given in the subclaims and in the figures and described below.

Show it:

FIGS. 1 to 6: a rod antenna with a rod-shaped carrier, on which, in sections, an antenna winding with sections of different pitches is wound,

FIG. 7 shows a rod antenna with a carrier foil on which meander-shaped antenna structures are arranged,

FIG. 8 shows an antenna with conventional blocking circuit,

FIG. 9 shows a conventional blocking circuit and its elements in the case of a continuously wound blocking circuit,

FIG. 10: transition to a continuously wound blocking circuit, Figure 11: View of the winding layers in a continuously wound

Trap,

FIGS. 12 to 14 are views of the practical embodiment of the continuously wound blocking circuit;

FIG. 15: antenna structures on the carrier film,

Figures 16 to 18: further embodiments.

The figures 1 to 6 show, as far as shown in detail, a rod antenna with the reference numeral 1, which has an approximately circular cross-section antenna rod 2, at the end of a fastener 3, for example, for screwing into a corresponding holder on a vehicle. This outer shape of the rod antenna 1 is basically known and can vary depending on the transmission and / or reception properties that the rod antenna is to have. The inventive construction of the rod antenna 1 can be seen in Figure 2, wherein in the interior of the rod antenna 1, more precisely, the antenna rod 2, a support rod 4, is located. This may be, for example, a glass fiber rod or a rod of a corresponding other material, which is relatively rigid, but can be elastically deformed within certain small limits. An antenna winding 5 with different winding sections 51-56 (see FIGS. 3 and 4) is wound on this support bar 4. The different winding sections 51-56 form, depending on their pitch, emitters for transmitting and / or receiving high-frequency signals in certain frequency bands (eg 53, 54, 56) or inductors and / or resonant circuits (for example 52 or 55). The end of the antenna winding 5 is connected either directly to the fastening element 3, which produces the high-frequency connection between the rod antenna 1 and a corresponding transmitting and / or receiving device. In the rod antenna 1 According to Figure 2, the support rod 4 at the end a connection piece 6, with which the support rod 4 is connected, for example, with the fastening element 3. Here, however, the connection piece 6 is smaller in diameter than the support rod 4 itself, wherein an intermediate piece 7, designed here as a spring element, the connection between the support rod 4 and the fastener 3 produces. Preferably, with the same diameter of the connecting piece 6 of the support rod 4, the fastening element 3 also has a connecting piece 8, wherein the ends of the formed as a spring intermediate piece 7 are pressed onto the connecting pieces 6 and 8. Alternative connection possibilities between the support rod 4 and the intermediate piece 7 can be seen in FIGS. 5 and 6, in which case a further connecting piece 13 is present between the support rod 4 and the intermediate piece 7, if the support rod 4 has a diameter at the end that is greater than that Inner diameter of the connecting piece 7. For this purpose, according to Figure 5, the connecting piece 13 is approximately funnel-shaped, while the connecting piece 13 is formed as shown in FIG 6 as a sleeve. Alternatively, it is conceivable to make the intermediate piece 7 not as a spring, but from solid material, in which the connecting pieces 6, 8 are inserted and pressed or otherwise secured. Depending on the requirement placed on the rod antenna 1, it is important that the area of the antenna rod 2 (that is to say in the region of the support rod 4) is relatively rigid, whereas in the area of the intermediate piece 7 a larger elastic area can be achieved compared to the area of the support rod 4 Deformability can be permitted with appropriate restoring moment. If these basic conditions are not met, it is also conceivable to guide the carrier rod 4 into the fastening element 3, and fix it there.

It can also be seen in FIG. 2 that the antenna winding 5 wound on the support rod 4, for example comprising copper enameled wire, is surrounded by an insulation 9. This insulation 9 causes the sections differently shaped antenna winding 5 is fixed in Umsphtzen the rod antenna 1 with a sheath 10 in position and not the individual windings are movable on the support rod 4 during the injection process. This insulation 9 may be, for example, an adhesive layer between the support rod 4 and the antenna winding 5, but also an adhesive tape or a heat-shrinkable tube which is mounted on the support rod 4 after winding up the antenna winding 5.

An exemplary, but not limiting manufacturing method of the rod antenna 1 according to Figure 2 will be explained below.

The support rod 4 is cut to length and provided with a paragraph (connector 6). Subsequently, by means of a winding machine, the application of the antenna winding 5 with the different sections (eg 51 to 56) and the fixing of the applied antenna winding 5 on the support rod 4 by means of the insulation 9. The end of the antenna winding 5 is guided into the region of the connecting piece 6 and electrically contacted with the there to be applied spacer 7 (eg soldered). For this purpose, the antenna winding 5 must be exposed, for example, if it is a copper enameled wire. Subsequently, the attachment of the electrically conductive fastening element 3 takes place at the other end of the intermediate piece 7, after which this finished structure ("inner life" of the rod antenna 1) is inserted into an injection mold and completely encapsulated with the casing 10 (except for the lowermost threaded pin of the fastening element 3 The very essential advantage of a rod antenna 1 produced in this way is that the automatic winding machine can be adjusted and operated in such a way that the different winding sections 51 to 56 can be produced to achieve antenna radiators or inductors and / or resonant circuits Simplification in the production of the rod antenna 1 given that the individual sections of the antenna rod 2 no longer separately (winding sections and additional inductances) must be prepared and electrically connected to each other.Thus, the invention also offers the advantage that malfunction n the rod antenna 1 are excluded, since poor or no connections (especially solder joints) between the antenna winding and inductors and / or resonant circuits or parts thereof may arise or they are avoided with the invention.

The two rod antennas 1 shown in the figures and described above have the advantage that a single rod antenna 1 for different frequency ranges is produced by the differently-shaped antenna windings 51 to 56 or the meander-shaped conductor track 12. These frequency ranges are, for example, long wave, medium wave, short wave, UKVV or telephone or corresponding combinations of the aforementioned frequency ranges. Thus, for example, with the rod antenna 1 according to the invention a novel rod antenna can be realized, which is compact (in particular short) built, easy to manufacture and has a large bandwidth. Due to the different antenna windings or sections of different conductor tracks, it is possible to use e.g. a single rod antenna for the frequency ranges long wave (153-279 kHz), medium wave (522-1710 kHz), short wave (5900-6250 kHz), VHF (87.5-108 MHz), telephone (eg 810-960 MHz) and DAB (Digital Audio Broadcast) (170-230 MHz and 1452-1492 MHz). The frequency bands with amplitude-modulated signal long wave, medium wave and short wave are coupled high impedance, while in all other bands the rod antenna has adaptation.

FIG. 7 shows the rod antenna 1, in which the carrier is designed as a rigid carrier or, as shown in FIG. 7, as a carrier foil 11. On the rectangular or trapezoidal plastic carrier foil 11, for example, a conductive structure is applied in a meandering manner (for example, printed as a printed conductor 12) so that resonances in the finished bar antenna 11 are set in a plurality of frequency bands. These resonances are directly attributable to the individual, different sections of the conductor track 12. The eg cylindrical or conically rolled carrier film 11 is mechanically or electrically connected directly or with the interposition of an intermediate piece (see Figures 2 to 6) with the fastener 3, so that an electrical contact between the metallic fastener 3 (threaded foot) and the electrically conductive printed structures of the plastic Carrier film 11 is formed. Subsequently, the sheath 10 is attached, again, for example, in a plastic injection molding process or in another conceivable method to make the "inner workings" of the rod antenna 1 weatherproof and to protect against external mechanical influences.

FIGS. S to 14 show the essential and important method according to the invention for the realization of blocking circuits within the antenna as well as their structural design options.

The blocking circuit is formed by the inductor 101 and the capacitor 102. It can also be represented in a stretched form with a capacitor plate 103, the inductor 104 and a capacitor plate 105. In a wound form, the antenna winding region 106 goes into the lower capacitor "winding" 107 The conductor 108 forms the connection between the lower capacitor "plate" 107 and the inductance 109 and the conductor 110 forms the connection between the inductance 109 and the upper capacitor "plate" 111. 112 denotes the extension of the antenna winding after the In the winding process, first the regions 106, 107, 108 and 109 are wound onto the carrier in this order, then the negative feed region 110 is wound over the inductance 109. At the beginning of the winding 107 the region 111 is arrived at with positive feed , which represents the upper capacitor "plate", so that it is wound between the Wick lungen the lower capacitor "plate" 107 comes to rest. In this case, the area 110 is automatically fixed. At the end of the winding 111, the area of the blocking circuit is left with a large feed 112. Analogously, a blocking circuit can also be realized within the printed antenna structure. The areas 107 and 111 do not lie on top of each other, but are arranged in a finger-like manner.

As described above and explained with reference to FIGS. 12 to 14, the antenna conductor structure in the form of a wire has been wound onto the support rod 4 in various ways (see reference numerals 106 to 112). In this case, it is essential and important for the formation of the desired blocking circuits and, as a result, the reception of different frequency bands, that the antenna winding in the form shown is arranged on the carrier bar 4, wound back and forth. Only by this forward and backward winding, but also by placing wire sections on already wound wire sections (for example, placing the wire section 110 on the already wound wire section 109), it becomes possible, the rod antenna 1 with the desired function, namely the transmission and / or Receive multiple frequency bands to realize.

Alternatively, it is shown in FIG. 15 that with the same function (realization of a rod antenna for transmitting and / or receiving high-frequency signals of a plurality of frequency bands not only the wire winding technique shown in FIGS. 12 to 14 must be used, but that the function also works Therefore, in Fig. 15, the conductor portions are shown similarly to the wire portion and Figs. 12 to 14, wherein the same reference numerals designate the same functions (blocking circles).

FIGS. 16 to 18 show further embodiments of the rod antenna according to the invention. In Figure 16 it can be seen that parts of the integrally formed antenna conductor pattern are arranged to form one or more blocking circuits of a predetermined frequency. For this it is intended the carrier film or printed circuit board has incisions extending substantially perpendicularly to the longitudinal axis in order to increase the bending flexibility.

In FIG. 17, it is shown that the carrier foil or printed circuit board is helically or helically wound along its length and is then surrounded by the sheathing (not shown here). By the helical or spiral winding of the carrier film or printed circuit board with appropriate dimensions (length or width and height of the individual turns) turn the different blocking circuits can be realized, resulting in turn, the different reception of multiple frequency bands.

Finally, FIG. 18 shows that the carrier foil or printed circuit board spirally wound in a spiral cylindrical shape to form the antenna route 2 and is subsequently surrounded by the sheathing 10 (not shown here). As a result, the rod antenna 1 can be realized in a particularly simple and compact form.

In summary, it is stated once again that one of the essential aspects of the invention is an antenna rod wound continuously from an electrically conductive material (eg wire) on a support (eg rod of electrically non-conductive material), which is in the single continuous (and fixed and thus neither tunable in the mechanical nor in the electrical length) winding both radiator elements (for transmitting and / or receiving high-frequency signals in several frequency ranges or on multiple frequencies) as well as a blocking circuit or more blocking circuits for defined frequencies or defined frequency ranges realized by defined winding of the antenna winding in the one longitudinal direction of the carrier and in partial regions in the other longitudinal direction and back again in the one longitudinal direction, wherein identical or different gradients are realized, as well as stacking of winding sections (without electrical short circuit) , whereby the measures mentioned result in increased stray capacities, in particular by approaching the beginning of the winding and its end or by approaching the coil start and the coil end.

Alternatively, this object can be achieved by not winding a wire on a rod, but by forming the antenna conductor structure by applying electrically conductive regions (e.g., copper traces) to a planar support (e.g., circuit board). Here too, for example, a capacitor can be formed by feeding back and forth a superimposed conductor track (the superimposed regions being electrically isolated from one another), as well as an inductance.

Claims

Rod antenna with sections of different antenna windings Patent claims

1.

Rod antenna (1), which is designed for transmitting and / or receiving high-frequency signals, having a carrier, on which an antenna conductor structure is arranged having antenna rod (2), wherein the carrier with the antenna structure at least partially surrounded by a sheath (10) is and the rod antenna (1) has a fastening element (2) at the end, characterized in that the rod antenna (1) is designed for transmitting and / or receiving different frequency bands and for this purpose the antenna conductor structure is configured in one piece continuously and in sections differently, wherein the Design is dependent on the respective frequency band.

Second

Rod antenna (1) according to claim 1, characterized in that parts of the integrally formed antenna conductor structure are arranged so that they form one or more blocking circuits with a predetermined frequency.

Third

Rod antenna (1) according to claim 1 or 2, characterized in that the carrier is a rigid or flexible carrier foil (11) or printed circuit board with printed or otherwise arranged thereon and forming the antenna conductor pattern conductor track (12).

4th Rod antenna (1) according to claim 1, 2 or 3, characterized in that the flexible carrier foil (11) or printed circuit board is conically or cylindrically rolled to form the antenna rod (2) and subsequently surrounded by the casing (10).

5th

Rod antenna according to claim 1, 2, 3 or 4, characterized in that the carrier film or printed circuit board to increase the bending flexibility has substantially perpendicular to the longitudinal axis incisions.

6th

Rod antenna according to one of the preceding claims, characterized in that the carrier foil or printed circuit board helically or spirally wound over its length and is then surrounded by the sheath (10).

7th

Rod antenna according to one of the preceding claims, characterized in that the carrier foil or printed circuit board spirally cylindrical wound to form the antenna rod (2) and then surrounded by the sheath (10).

8th.

Rod antenna (1) according to any one of the preceding claims, characterized in that the antenna rod (2) as carrier has a support rod (4), to which a single continuous antenna winding (5) with at least two differently wound winding sections (51-56) applied is.

9th Rod antenna (1) according to one of the preceding claims, characterized in that the antenna winding (5) with the fastening element (3) is directly connected and electrically contacted.

10th

Rod antenna (1) according to one of the preceding claims, characterized in that arranged between the fastening element (3) and the end of the support rod (4) facing it is an intermediate piece (7) designed in particular as a spring.

11th

Rod antenna (1) according to one of the preceding claims, characterized in that the antenna winding (5) with the fastening element (3) via a particular designed as a spiral spring intermediate piece (7) is connected and electrically contacted.

12th

Rod antenna (1) according to any one of the preceding claims, characterized in that the fastening element (3) and / or the support rod (4) has at its end a connection piece (6, 8) for the intermediate piece (7).

13th

Rod antenna (1) according to one of the preceding claims, characterized in that the connecting piece (6) of the carrier rod (4) has a smaller diameter than the carrier rod (4) itself.

14th

Rod antenna (1) according to one of the preceding claims, characterized in that between the carrier rod (4) and intermediate piece (7) a connecting piece (13) is arranged., Which has a sleeve portion, the End of the support rod (4) and a pin portion which projects into the intermediate piece (7).

15th

Rod antenna (1) according to one of the preceding claims, characterized in that between the support rod (4) and intermediate piece (7) a connecting piece (13) is arranged., Which is designed as a sleeve body, the end of the support rod (4) and the end of the intermediate piece (7).

16th

Rod antenna (1) according to one of the preceding claims, characterized in that the antenna winding (5) consists of wire, in particular enameled copper wire.

17th

Method for producing a rod antenna (1) according to one of the preceding claims, characterized in that the antenna winding (5) by means of a controllable winding machine sections with different slopes and / or defined superimposed or adjacent turns in the respective section on the support rod (4) is wound up.

18th

Method for producing a rod antenna (1) according to one of the preceding claims, characterized in that a blocking circuit is formed by an inductor (101) and a capacitor (102), wherein in wound form an antenna winding region (106) is transformed into a lower capacitor " In addition, a conductor (108) forms the connection between a lower capacitor "winding" (107) and an inductance (109), and a conductor (110) forms the connection between the inductance (109) and a upper capacitor "winding" (111) forms.

19th

A method for producing a rod antenna (1) according to claim 18, characterized in that during the winding process first the regions (106, 107, 108 and 109) are wound in this order on the carrier (4), then the region (110) with negative Feed over the inductance (109), having arrived at the beginning of the winding (107), with positive feed, the area (111), which represents the upper capacitor "winding", is wound between the windings of the lower capacitor "winding" 107 comes to rest, while the area (110) is automatically fixed.

on

Method for producing a rod antenna according to one of the preceding claims, characterized in that the antenna winding (5) is produced on the carrier rod, the carrier foil or the printed circuit board by means of an application method, in particular a printing method or by means of a removal method, in particular a chemical etching method.