DE60100492T2 - TONE ANTENNA - Google Patents

Description

TECHNICAL TERRITORY

The present invention relates to a multi-frequency antenna in a first frequency band and a second frequency band works and for application to a multi-frequency antenna for a vehicle is suitable and capable of a first mobile radio band, a second Cellular band, AM / FM broadcasting and the GPS band can be received.

STATE OF THE ART

There are different types of antennas that to be attached to a vehicle, but roof antennas that are on the vehicle roof are preferred because they allow the reception sensitivity by installing the antenna the roof, which is the highest point on the vehicle is to improve. There is also usually an AM / FM radio built into the vehicle, it is convenient to use an antenna capable of receiving both the AM and FM radio bands and have roof antennas that can receive two radio bands together therefore great Spread found.

The more valuable are in the last Years of vehicle navigation systems using GPS (Global Positioning System) use, and cell phones have become increasingly popular, and GPS antennas for vehicle navigation systems and Cellular antennas for Mobile phones have been installed on vehicles.

If the vehicle is a keyless one Has access system in which the locking and unlocking the Wireless doors is controlled remotely an antenna for the keyless Access attached to the vehicle.

Independent installation of different types of antennas for these purposes on a vehicle, however, not only bring with it design problems itself, but also complicates maintenance and installation tasks and the like, and therefore a multi-frequency antenna is a Cellphone band, FM / AM radio bands, the GPS band and the band for the keyless Access and the like in a single antenna has been proposed.

One in Japanese Patent Laid-Open No. H6-132714 multi-frequency antenna is an example of this Type of multi-frequency antenna known. This multi-frequency antenna consists of a retractable rod antenna that combines Three-wave antenna for receiving a cell phone band, FM radio band and AM radio band, an area radiation element that forms a GPS antenna for receiving GPS signals, and a loop radiation element that an antenna for the keyless Access to receive keyless entry signals.

These respective antennas are on the top of a main body attached, and a metal plate is present in the upper part of the main body, the area radiating body and the Loop body radiation be formed by an inductive layer on this plate. Since the plate forms a counterweight, the surface radiation element works and the loop radiation element as microstrip antennas. Of Werteren is over the area radiation element and a protective cover is formed for the loop radiation element.

Because a multi-frequency antenna this Type includes a retractable rod antenna, it is necessary to provide a space for housing the rod antenna if it is installed. While it possible is, the multi-frequency antenna on the trunk lid or fender where such a space can be formed, they can install therefore not on the roof, which is the optimal place to attach an antenna, because this does not have the required Accommodation space. When the multi-frequency antenna is installed on the trunk lid or fender is, because the inclination angle of the GPS satellite in many make a low angle of inclination is, in this case, a risk that the electromagnetic waves from the satellite, depending on the position of the GPS satellite, shielded by the vehicle body can be. Japanese Patent Laid-Open No. H10-93327 (CP 0862 234) a multi-frequency antenna is therefore disclosed which is constructed to solve this problem.

This multi-frequency antenna exists from an antenna element that vibrates at multiple frequencies is determined by being provided with a fold coil and one Cover section with a built-in control circuit board or the like on which this antenna element is installed. by doing this cover section is attached to the roof, the multi-frequency antenna can installed on the roof.

Generally, a plurality of frequency bands are allocated for use by cellular phones. For example, in the PDC (Personal Digital Cellular Telecommunication System) used in Japan, the 800 MHz band (810 MHz-956 MHz) and the 1.4 GHz band (1429 MHz-1501 MHz) are allocated. In Europe, the 800 MHz (870 MHz – 960 MHz) GSM (Global System for Mobile Communication) and the 1.7 GHz (1710 MHz – 1880 MHz) DCS (Digital Cellular System) are used. In order to operate an antenna in a plurality of operating frequencies of this type, antennas operating in the relevant frequency bands are provided, but usually two antennas are provided connected to a choke coil so that they mutually influence the operation of the other, see e.g. B. EP 0657 093 ,

In a choke coil, such as. B. a pleated coil or the like, however, it is difficult to send signals through a separate wide frequency range. In other words, even if a choke coil between antennas that work in respective frequency bands, is provided, it is when the frequency bandwidths as in Mobile phone straps are great not possible, the relevant antennas above this frequency bands independently to be worked on, and therefore there is a problem in that the Antennas influence each other and are not made to do so can, to work satisfactorily.

EPIPHANY THE INVENTION

It is a task of the present Invention, a multi-frequency antenna of a novel composition provide that over works in two different broad frequency bands, as in the pending claims explained. To the aforementioned Task to accomplish the antenna comprises a first element which is in a first frequency band works, and a second element with a rectangular expanded Radiation surface, the operates in a second frequency band that is higher than the first frequency band and connected to an intermediate region of the first element is. The working principles of the multi-frequency antenna of the present Invention according to this Composition are not clear, but the antennas are able to independently to work without mutual adverse effects, even if that the first frequency band and the second frequency band are broad frequency bands, z. B. Mobile phone bands. Since the second element has an extended radiation surface, Is it possible, essentially omnidirectional properties in the horizontal plane to achieve.

Furthermore, in the multi-frequency antenna according to the invention the first frequency band is taken as a first mobile radio band, and the second frequency band is taken as a second mobile band, which is a frequency band that is about twice as high as the first Cellular band is.

In addition, if the first Element is divided into two and the bottom element of the divided the first element is accommodated within a cover section, while the second element is also housed within the cover section will be obtained, a compact multi-frequency antenna. It is possible, a circuit board having a frequency divider and the like contains manufacture that housed in the space within the cover section can be.

By providing an item, that in a much lower frequency band, e.g. B. an AM / FM band works over a choke coil at the top of the first element, it is also possible to use one Multi-frequency antenna that works at three or more frequencies, to obtain. Furthermore, if a GPS antenna unit in the Accommodation space is provided within the cover, the GPS signal can also be received without the other antennas to adversely affect.

SUMMARY THE DRAWINGS

1 Fig. 12 is a drawing showing a partial sectional view of the structure of a first embodiment of a multi-frequency antenna according to the invention.

2 Fig. 12 is a drawing showing an enlarged partial view of a multi-frequency antenna according to a first embodiment of the present invention.

3 Fig. 12 is a drawing illustrating the structure of a lower element of a divided D-network element and an E-network element in a multi-frequency antenna according to a first embodiment of the present invention.

4 Fig. 12 is a drawing illustrating the detailed structure of a lower member of a divided D-network member of a multi-frequency antenna according to a first embodiment of the present invention.

5 Fig. 12 is a drawing showing the detailed structure of the E-network element in a multi-frequency antenna according to a first embodiment of the present invention.

6 Fig. 12 is a drawing showing the general structure of an E-network element connected to a D-network element in a multi-frequency antenna according to a first embodiment of the present invention.

7 10 is a diagram showing impedance characteristics in a D-network frequency band when certain constants are used for the dimensions of a D-network element and an E-network element in a multi-frequency antenna according to a first embodiment of the present invention.

8th 10 is a diagram showing VSWR characteristics in a D-network frequency band when certain constants are used for the dimensions of a D-network element and an E-network element in a multi-frequency antenna according to a first embodiment of the present invention.

9 Fig. 10 is a diagram showing impedance characteristics in an E-mesh frequency band when certain constants are used for the dimensions of a D-mesh element and an E-mesh element in a multi-frequency antenna according to a first embodiment of the present invention.

10 is a diagram showing VSWR properties in an E-network frequency band when certain constants for the dimensions of a D-network element and an E-network element can be used in a multi-frequency antenna according to a first embodiment of the present invention.

11 Fig. 10 is a diagram showing directional characteristics and a measurement state at a lowest D-network frequency when certain constants are used for the dimensions of a D-network element and an E-network element in a multi-frequency antenna according to a first embodiment of the present invention ,

12 FIG. 12 is a diagram showing directional characteristics in a horizontal plane at a medium and a highest D-network frequency when certain constants for the dimensions of a D-network element and an E-network element in a multi-frequency antenna according to a first embodiment of the present invention can be used.

13 FIG. 10 is a diagram showing directional characteristics in a horizontal plane at a lowest and a medium E-network frequency when certain constants for the dimensions of a D-network element and an E-network element in a multi-frequency antenna according to a first embodiment of the present invention can be used.

14 Fig. 10 is a diagram showing directivity in a horizontal plane at a highest E-network frequency when using certain constants for the dimensions of a D-network element and an E-network element in a multi-frequency antenna according to a first embodiment of the present invention become.

15 Fig. 12 is a diagram illustrating the measurement state of directional characteristics in a vertical plane when a multi-frequency antenna is erected according to a first embodiment of the present invention.

16 FIG. 12 is a diagram showing directional characteristics in a vertical plane at a lowest and a medium D-network frequency when certain constants for the dimensions of a D-network element and an E-network element in a multi-frequency antenna according to a first embodiment of the present invention can be used.

17 Fig. 10 is a diagram showing directivity in a vertical plane at a lowest E-network frequency when using certain constants for the dimensions of a D-network element and an E-network element in a multi-frequency antenna according to a first embodiment of the present invention become.

18 FIG. 12 is a diagram showing directivity in a vertical plane at a middle and a highest E-network frequency when certain constants for the dimensions of a D-network element and an E-network element in a multi-frequency antenna according to a first embodiment of the present invention can be used.

19 FIG. 12 is a diagram illustrating the measurement state of directional characteristics in a vertical plane when a multi-frequency antenna is tilted according to a first embodiment of the present invention.

20 Fig. 12 is a diagram showing directivity in a vertical plane at a lowest D-network frequency when using certain constants for the dimensions of a D-network element and an E-network element in a multi-frequency antenna according to a first embodiment of the present invention become.

21 FIG. 12 is a diagram showing directivity in a vertical plane at a middle and a highest D-network frequency when certain constants for the dimensions of a D-network element and an E-network element in a multi-frequency antenna according to a first embodiment of the present invention can be used.

22 FIG. 12 is a diagram showing directional characteristics in a vertical plane at a lowest and a medium E-network frequency when certain constants for the dimensions of a D-network element and an E-network element in a multi-frequency antenna according to a first embodiment of the present invention can be used.

23 Fig. 12 is a diagram showing directivity in a vertical plane at a highest E-network frequency when using certain constants for the dimensions of a D-network element and an E-network element in a multi-frequency antenna according to a first embodiment of the present invention become.

24 Fig. 12 is a drawing showing a partial sectional view of a structure of a second embodiment of a multi-frequency antenna according to the invention.

25 Fig. 12 is a drawing showing a partial enlargement of a multi-frequency antenna according to a second embodiment of the present invention.

26 Fig. 12 is a drawing showing the structure of a lower element of a divided D-network element and an E-network element in a multi-frequency antenna according to a second embodiment of the present invention.

27 Fig. 12 is a drawing showing the detailed structure of a lower member of a divided D-network element in a multi-frequency antenna according to a second embodiment of the present invention.

28 Fig. 12 is a drawing showing the detailed structure of an E-network element in a multi-frequency antenna according to a second embodiment of the present invention.

29 Fig. 12 is a drawing showing the general structure of an E-network element connected to a D-network element in a multi-frequency antenna according to a second embodiment of the present invention.

BEST WAY FOR EXECUTION THE INVENTION

1 shows a partial sectional view of the structure of a first embodiment of a multi-frequency antenna according to the invention, and 2 shows an enlarged view thereof.

As shown in these drawings, the multi-frequency antenna 100 according to the first embodiment of the present invention by a linear antenna element 1 and a cover section 2 made of synthetic resin on which the antenna element 1 is installed detachably, formed. The antenna element 1 includes a spirally shaped spiral element section 31 and one at the top of the spiral element section 31 attached antenna tip 32 , There is also a shaped antenna base section 30 on the lower end of the spiral element section 31 available. A flexible, elastic element section 16 that with the lower end of the spiral element section 31 is connected, and a choke coil 14 , one end of which is connected to the lower end of the elastic element section 16 are connected inside the antenna base section 30 available. Furthermore, the other end of the choke coil 14 with a D-network element 13 connected, which corresponds to an upper D-network element, and a fastening screw 12 is on the lower end of the D-mesh element 13 available.

"D network" here denotes a first one Mobile phone band based on the aforementioned GSM system and "E-Network" mentioned below denotes a second mobile phone band operating on the aforementioned DCS system based.

Incidentally, a wind noise preventing device wound in a coil shape is also placed on the spiral element portion 31 provided. The elastic element section also serves 16 the antenna element 1 prevent bending and breaking when a side load is placed on it. This elastic element section 16 can be formed by a flexible cable or a coil spring.

A metal base plate 25 is in the cover portion formed by resin molding 2 fitted, and a cylindrical installation section 24 for installation on the roof or the like of a vehicle is from this base plate 25 protruding formed. A screw thread is in the outer periphery of the base plate 25 cut, and signal cables and power cables coming from inside the cover section 2 can be inserted through a chip hole formed on the inside thereof.

The cover section 2 houses a lower element 10 for D-Netz use and one element 11 for e-network use, which is shaped so that it has a rectangular radiation surface that is adjacent to the vicinity of the upper end of the lower element 10 followed. The composition of the lower D-Netz element 10 and the E-Netz element 11 is in 3 illustrated. Furthermore, a screw receiving section 2a for receiving one at the lower end of the antenna base section 30 existing fastening screw section 12 on the top of the cover section 2 provided. A screw thread is in the inner periphery of this metal screw receiving section 2a cut that as an insert in the cover section 2 is formed. At the bottom of the screw receiving section 2a is a connection section 10a present on the front end of the lower element 10 is formed and in one on the front end of the mounting screw portion 12 formed terminal insertion section 12a is screwed. In other words, by screwing it onto the antenna base section 30 provided fastening screw section 12 in the screw receiving section 2a become the connection section 10a and the D-network element 13 in the antenna base section 30 by means of the fastening screw section 12 electrically connected. This will make the D network element 13 , which forms an element of the shared D-network antenna, and the lower element 10 , which forms the other element of the same.

A circuit board 21 is at the bottom of the bottom element 10 soldered, and a filter for sharing waves between a D-network and E-network mobile phone band and an AM / FM band is in this circuit board 21 available. The AM / FM band signal thus shared is amplified by an amplification circuit which is in an amplification circuit board 22 is included in the cover section 2 is housed. There is also a GPS unit 23 , which consists of a GPS antenna and a converter section for converting received GPS signals into intermediate frequency signals, within the cover section 2 accommodated. Because the E-network element 11 is constructed so that it is on the back of the lower element 10 in this case, it does not affect the directional properties at a lower angle of inclination of the GPS antenna in the GPS unit 23 , Furthermore, D-Netz and E-Netz mobile phone band signals from one with the circuit board 21 connected signal cable is extracted while AM / FM ribbon signals from the gain shaft board 22 are extracted, and GPS signals converted into intermediate frequency signals are converted from one with the GPS unit 23 connected signal cable extracted. These cables are made from the cover section 2 led through the inside of the installation section 24 run, and are then connected to appropriate facilities located within the vehicle.

The structure of the lower D-network element 10 and the E-Netz element 11 is in 3 veran shows. The structure of the lower element 10 will be described later, but is plate-shaped with a front end portion bent into an approximate L-shape in cross section by machining a metal plate, and a screw thread portion 10d in which the terminal insertion section 12 is screwed is approximately in the middle of the connection section 10a formed at the curved front end portion thereof. There is also a solder piece 10b for soldering to the circuit board 21 at the bottom of the bottom element 10 educated.

Furthermore, the E network element 11 by machining a metal plate so as to have an approximately rectangular radiation surface, with a fitting extending from about the center of an edge thereof bent in a square U-shape, and a holding piece 11a is formed on the front end thereof. This holding piece 11a is inserted into a cut window that is in the upper part of the main element of the lower element 10 is formed, and it holds the lower member on both sides thereof. By soldering the part held in this way, the E-Netz element 11 on the lower element 10 attached and also electrically connected to it. As described below, this E-net element has 11 an enlarged radiation surface with an approximately rectangular rm, so that it essentially has omnidirectional properties in the horizontal plane. Furthermore, each end section is the e-network element 11 bent slightly forward, and both corners of its top edge are cut away by editing. This is so the E network element 11 can be accommodated in a narrow housing space through the back of the lower element 10 and the side wall of the cover section 2 is formed. Bending the E-Netz element 11 and removing the two corner areas thereof does not affect the leveling properties thereof in the horizontal plane.

In the multi-frequency antenna 100 According to the first embodiment of the present invention, by means of the above-mentioned composition, the divided D-network element 13 and the lower D-mesh element 10 connected when the antenna element 1 in the cover section 2 is screwed. In other words, in the multi-frequency antenna 100 according to the first embodiment of the present invention, as in 1 illustrates, the D-network antenna is an antenna that is in an area between the circuit board 21 and the lower end of the choke coil 14 is working. In addition, the E-network antenna is an antenna that is in an area between the circuit board 21 and the top of the bottom element 10 is working. Furthermore, the AM / FM band antenna is an antenna that is in the area between the circuit board 21 and the antenna tip 32 is working. However, it does not vibrate in the AM band.

Next is the individual composition of the bottom element 10 and the E-Netz element 11 in the multi-frequency antenna 100 in the first embodiment of the present invention 4 and 5 described.

4 shows the detailed structure of the lower element 10 : 4 (a) is a front view of the lower member 10 ; 4 (b) is a side view of the same; 4 (c) is a back view of the same, and 4 (d) is a bottom view of the same.

As shown in these drawings, the bottom element has 10 a plate shape, the front end portion of which is bent into an approximately L-shape in cross section by machining a metal plate. The curved front end portion thereof is called a connection portion 10a taken, and a screw thread section 10d in which the terminal insertion section 12a is screwed, is approximately in the middle of this connection section 10a educated. There is also a taper on the main piece 10c attached, extending from the end of the connecting section 10a extends downward so that it has a narrower width at its lower end, and the upper part thereof is slightly curved towards the rear. A solder piece 10b for soldering to the circuit board 21 is at the bottom of the main piece 10c educated. It is also part of the upper part of the main piece 10c cut out to a cut window 10e to build.

5 shows the detailed structure of the E-Netz element 11 : 5 (a) is a front view of the E-Netz element 11 ; 5 (b) is a side view of the same, and 5 (c) is a bottom view of the same.

As shown in these drawings, the E network element 11 with an enlarged radiation surface with an approximately rectangular shape is formed by machining a metal plate, and end pieces 11d . 11e on each side are slightly bent forward on the approximately rectangular radiation surface, and both corner portions of the top edge thereof are cut away by machining. It also becomes a connector 11f and a curved piece 11b by extending a portion from about the center of the top edge of the element 11 and bending it into a square U-shape. A stop 11a is done by cutting off part of the leading edge of the bent piece 11b educated.

This stop 11a is used to on each side of the cut window 10e to sit around an upper part of the main piece 10c of the bottom element 10 to build. If so, the E-Netz element can 11 on the lower element 10 can be attached, and a mutual electrical connection can be made by the holding piece 11a around the edge of the out cut window 10e is soldered around. If the bend angle of the center piece 11c in relation to the connector 11f is set to greater than 90 ° when the E-Netz element 11 on the lower element 10 is attached, the lower element 10 and the centerpiece 11c of the E-Netz element 11 are approximately parallel.

The multi-frequency antenna 100 According to the first embodiment of the present invention, it works simultaneously as a four-frequency antenna for D-network and E-network mobile phone bands and an AM / FM band, and also GPS signals can be obtained by means of a separately provided GPS unit 23 be received. In this case, if there are no AM / FM band facilities and therefore the AM / FM antenna is superfluous, it is possible to use only the D-network element 13 , which is one of the divided elements, within the antenna base portion 30 accommodate. In this way, the multi-frequency antenna 100 according to the first embodiment of the present invention, be a multi-frequency antenna using the antenna element 1 only works in the D network and the E network. In this case, the length of the antenna element can of course 1 be shortened accordingly.

Next, the construction of the D-network and E-network antenna in the composition of 1 described by the following explanation of the theoretical structure of an antenna that is used as a multi-frequency antenna that works in this way only in the D network and E network.

6 (a) shows the theoretical structure of an antenna, which works only in the D network and E network, with respect to the multi-frequency antenna 100 according to the first embodiment of the present invention.

As in 6 (a) shown, the split D-network antenna is a linear antenna of length L1 that have an upper section that is a D mesh element 13 forms, and includes a lower portion that a lower element 10 the length L2 forms. The D network antenna thus constructed protrudes at an angle in a slightly inclined manner θ1 with respect to the horizontal plane. An electric network element 11 with a length L3 is connected to an area where the D-network element is 13 with the bottom element 10 united. The E-Netz element 11 is roughly parallel to the bottom element 10 arranged by length L4 of the connector described above 11f separated from it. The front end of this connector 11f is connected to an intermediate part of the D-network antenna by the D-network element 13 and the lower element 10 is formed. The structure of the e-network element 11 is like in 5 is illustrated, and its approximate shape is shown in 6 (b) and 6 (c) illustrated, the width of the rectangular shape forming the enlarged radiation surface as W1 is taken. The bottom end of the bottom element 10 forms an electricity feed point for the D-network antenna and the E-network element 11 as illustrated in the drawings.

In the 6 shown dimensions, namely the length L1 the D-network antenna by the D-network element 13 and the lower element 10 is formed, the length L2 of the bottom element 10 , the length L3 and the width W1 of the E-Netz element and the distance L4 between the D-network antenna and the E-network element 11 are according to the frequency values of the first frequency band for the D network and the second frequency band for the E network and the angle used θ1 certainly. If the z. B. the angle θ1 can be about 76 °, if the wavelength at the center frequency of the D network is 915 MHz θ1 (327.87 mm) and the wavelength at the center frequency of the E-Netz 1795 MHz as θ2 (167.23 mm) is assumed to be the length L1 the D network antenna as about 0.202 λ1 , the length L2 of the bottom element 10 than about 0.136 λ2 , the length L3 of the E-Netz element 11 than about 0.102 λ2 , the width W1 the same as about 0.162 λ2 and decency L4 between the D-network antenna and the E-network element 11 than about 0.021 λ2 be taken.

7 and 9 show impedance properties for a multi-frequency antenna 100 according to the first embodiment of the present invention, as in 1 illustrates when the aforementioned constants for the dimensions of the length, width and distance of the divided D-mesh element 13 and lower element 10 and the E-Netz element 11 used while 8th and 10 Show VSWR properties of the same.

7 shows impedance properties for the D-network 800 MHz band (870 MHz-960 MHz) and an impedance value in the size of 50 ohms is obtained for this frequency band. 50 ohms is the impedance value to be met. The worthy shows 9 Impedance properties in the 1.7 GHz band (1710 MHz-1880 MHz), and from the lower frequency range beyond the center frequency range of this 1710 MHz-1880 MHz band, an impedance of 50 ohms is obtained.

Furthermore shows 8th VSWR properties for the D-network 800 MHz band (870 MHz - 960 MHz), and a good VSWR value of about 1.8 or less is achieved in this frequency band. 10 shows VSWR characteristics for the E-network 1.7 GHz band (1710 MHz-1880 MHz), and a VSWR value of about 2.0 or less is achieved in this frequency band, and in particular a good VSWR value of about 1.5 or lower is achieved by the lower frequency range beyond the center frequency range of this band. In this case, even if the E network element 11 is removed the properties of the D-network antenna that the D-network element 13 and the lower element 10 includes, not significantly changed, and the D-network antenna and the E-network antenna are therefore able to work independently. Ge the working principles are currently unclear.

Show next 11 to 14 Directional characteristics within a horizontal plane for a multi-frequency antenna 100 according to the first embodiment of the present invention, as in 1 shown in a case where the aforementioned constants for the dimensions of the length, width and distance of the D-mesh element 13 , the lower element 10 and the E-Netz element 11 be used.

11 (a) is a drawing showing a measurement state of the multi-frequency antenna 100 on a counterweight 50 is located with sufficient surface, illustrated and shows reference angles in the horizontal direction, which correspond to the angles of the directional properties described below in the horizontal plane.

11 (b) illustrates directional characteristics in the horizontal plane of a multi-frequency antenna 100 at the lowest frequency f = 870 MHz of the D-network frequency band. As shown in this diagram, essentially omnidirectional properties are obtained. In this case, the gain of the multi-frequency antenna is 100 compared to a λ / 4 whip antenna about +0.94 dB.

12 (a) shows directional properties in a horizontal plane of a multi-frequency antenna 100 at the center frequency f = 915 MHz of the D-network frequency band. As shown in this diagram, essentially omnidirectional properties are obtained. In this case, the gain of the multi-frequency antenna is 100 compared to a λ / 4 whip antenna about +0.5 dB.

12 (b) shows directional properties in a horizontal plane of a multi-frequency antenna 100 at the highest frequency f = 960 MHz of the D-network frequency band. As shown in this slide, although the level decreases somewhat in the -30 ° direction, essentially omnidirectional characteristics are obtained. In this case, the gain of the multi-frequency antenna is 100 compared to a λ / 4 whip antenna about +0.35 dB.

13 (a) shows directional properties in a horizontal plane for a multi-frequency antenna 100 at the lowest frequency f = 1710 MHz of the E-network frequency band. As this diagram shows, although the level is lower than in the D network, omnidirectional properties are essentially obtained. In this case, the gain of the multi-frequency antenna is 100 compared to a λ / 4 whip antenna about –0.8 dB.

13 (b) shows directional properties in a horizontal plane for a multi-frequency antenna 100 at the center frequency f = 1795 MHz of the E-network frequency band. As shown in this diagram, essentially omnidirectional properties are obtained. In this case, the gain of the multi-frequency antenna is 100 compared to a λ / 4 whip antenna about –0.6 dB.

14 shows directional properties in a horizontal plane for a multi-frequency antenna 100 at the highest frequency f = 1880 MHz of the E-network frequency band. As this diagram shows, almost the same level is achieved as for the D network, and essentially omnidirectional properties are obtained. In this case, the gain of the multi-frequency antenna is 100 compared to a λ / 4 whip antenna about +0.3 dB.

Show next 16 to 18 Directional characteristics in a vertical plane of a vertical multi-frequency antenna 100 in a case where the aforementioned constants for the dimensions of the length, width and distance of the D-mesh element 13 , the lower element 10 and the E-network element 11 in a multi-frequency antenna 104 after the in 1 shown first embodiment of the present invention can be used. Furthermore is 15 a drawing showing a measurement state of the multi-frequency antenna 100 that are related to a counterweight 50 is positioned vertically of sufficient surface, illustrated and shows reference angles in the vertical direction, which correspond to the angles of the directional properties described below in the vertical plane.

16 (a) shows directional properties in a vertical plane for a multi-frequency antenna 100 at the lowest frequency f = 870 MHz of the D network frequency band. As shown in this diagram, good straightening properties are obtained which have a maximum level at an elevation angle of approximately +/- 60 °. In this case, the gain of the multi-frequency antenna is 100 compared to a dipole antenna about +1.65 dB.

16 (b) shows directional properties in a horizontal plane for a multi-frequency antenna 100 at the center frequency f = 915 MHz of the D-network frequency band. As shown in this diagram, good straightening properties are obtained which have a maximum level at an elevation angle of approximately +/- 60 °. In this case, the gain of the multi-frequency antenna is 100 compared to a dipole antenna about +0.55 dB.

17 (a) shows directional properties in a horizontal plane for a multi-frequency antenna 100 at the highest frequency f = 960 MHz of the D-network frequency band. As shown in this diagram, good straightening properties are obtained which have a maximum level at an elevation angle of approximately +/- 60 °. In this case, the gain of the multi-frequency antenna is 100 compared to a dipole antenna about +1.1 dB.

17 (b) shows directional properties in a horizontal plane for a multi-frequency antenna 100 at the lowest frequency f = 1710 MHz of the E-network frequency band. As shown in this diagram, although the main beam width is narrower than for the D network, good straightening properties are obtained which have a maximum level at an elevation angle of approximately +/- 60 °. In this case, the gain of the extra frequencies is zantenne 100 compared to a dipole antenna about +3.98 dB.

18 (a) shows directional properties in a horizontal plane for a multi-frequency antenna 100 at the center frequency f = 1795 MHz of the E-network frequency band. As shown in this diagram, good straightening properties are obtained which have a maximum level at an elevation angle of approximately +/- 60 °. In this case, the gain of the multi-frequency antenna is 100 compared to a dipole antenna about +0.04 dB.

18 (b) shows directional properties in a horizontal plane for a multi-frequency antenna 100 at the highest frequency f = 1880 MHz of the E-network frequency band. As shown in this diagram, good straightening properties are obtained which have a maximum level at an elevation angle of approximately + 70 ° and -65 °. In this case, the gain of the multi-frequency antenna is 100 compared to a dipole antenna about +2.65 dB.

Show next 20 to 23 Directional characteristics in a vertical plane of an inclined multi-frequency antenna 100 in a case where the aforementioned constants for dimensions of the length, width and distance of the D-mesh element 13 , the lower element 10 and the E-Netz element 11 in a multi-frequency antenna 100 after the in 1 illustrated first embodiment of the present invention. Furthermore is 19 a drawing showing a measurement state of the multi-frequency antenna 100 that are in an inclined position with respect to a counterweight 50 is arranged with sufficient surface, illustrated and shows reference angles in the vertical direction, which correspond to the angles of the directional properties described below in the vertical plane.

20 shows directional properties in a vertical plane for a multi-frequency antenna 100 at the lowest frequency f = 870 MHz of the D network frequency band. As shown in this diagram, although there is a slight inequality between the positive angular direction and the negative angular direction, good straightening properties are obtained which have a maximum level at an elevation angle of approximately +/- 60 °. In this case, the gain of the multi-frequency antenna is 100 compared to a dipole antenna about +1.67 dB.

21 (a) shows directional properties in a horizontal plane for a multi-frequency antenna 100 at the center frequency f = 915 MHz of the D-network frequency band. As shown in this diagram, although there is a slight inequality between the positive angle direction and the negative angle direction, good straightening properties are obtained which have a maximum level at an elevation angle of approximately +/- 60 °. In this case, the gain of the multi-frequency antenna is 100 compared to a dipole antenna about +0.47 dB.

21 (b) shows directional properties in a horizontal plane for a multi-frequency antenna 100 at the highest frequency f = 960 MHz of the D-network frequency band. As shown in this diagram, good straightening properties are obtained which have a maximum level at an elevation angle of approximately +/- 60 °. In this case, the gain of the multi-frequency antenna is 100 compared to a dipole antenna about +1.64 dB.

22 (a) shows directional properties in a horizontal plane for a multi-frequency antenna 100 at the lowest frequency f = 1710 MHz of the E-network frequency band. As shown in this diagram, although there is a slight inequality between the positive angular direction and the negative angular direction, good straightening properties are obtained which have a maximum level at an elevation angle of approximately +/- 60 °. In this case, the gain of the multi-frequency antenna is 100 compared to a dipole antenna about +4.07 dB.

22 (b) shows directional properties in a horizontal plane for a multi-frequency antenna 100 at the center frequency f = 1795 MHz of the E-network frequency band. As shown in this diagram, although there is a slight inequality between the positive angular direction and the negative angular direction, good straightening properties are obtained which have a maximum level at an elevation angle of approximately +/- 60 °. In this case, the gain of the multi-frequency antenna is 100 compared to a dipole antenna about 2.44 dB.

23 shows directional properties in a horizontal plane for a multi-frequency antenna 100 at the highest frequency f = 1880 MHz of the E-network frequency band. As shown in this diagram, good straightening properties are obtained which have a maximum level at an elevation angle of approximately + 75 ° and -65 °. In this case, the gain of the multi-frequency antenna is 100 compared to a dipole antenna about 4.46 dB As from the in 16 - 23 illustrated directivity in the vertical plane can be seen, even if it is assumed that the antenna element 1 is inclined by approximately 76 °, the directional properties of the antenna in the vertical plane such that it radiates in all directions with a good elevation angle of approximately +/- 60 °. In addition, the directional properties in the horizontal plane are essentially omnidirectional properties, as in 11 to 14 illustrated. This allows the multi-frequency antenna 100 according to the first embodiment of the present invention can be suitably used as an antenna operating in cellular phone bands.

Next illustrate 24 and 25 a second embodiment of a multi-frequency antenna according to the invention.

With this multi-frequency antenna 200 to The second embodiment of the present invention, as illustrated in these drawings, is the antenna element 201 more inclined than the antenna element 1 the first execution. The angle of this inclination is z. B. 50 °. The structure of the multi-frequency antenna 200 according to the second embodiment of the present invention is the same as the multi-frequency antenna 100 according to the first embodiment, except for its inclination, and the inclined construction thereof, is therefore described below.

As in 24 shown, the antenna element 201 at an angle of inclination of z. B. 50 ° with respect to a horizontal plane. This inclination is achieved by using it as an insert of the cover section 202 molded metal screw receiving section 202a is inclined when it is in the cover portion 202 is attached. In other words, the structure of the antenna element 201 resembles that of the antenna element 1 , The length of the D mesh element 213 differs from that of the D-Netz element 13 , The structure of the cover section differs in this way 202 from that of the cover section 2 , and the structure of the bottom element 210 and the E-Netz element 211 that are inside the cover section 202 are housed; are also different.

26 shows the structure of a lower element 210 and E-Netz-Elements 211 in a multi-frequency antenna 200 according to the second embodiment of the present invention. The detailed structure of the lower element 210 will be described below, but it is plate-shaped with a front end portion bent in cross section by machining a metal plate into an approximate L shape, and a screw thread portion 210d in which a connection insertion section 212a is screwed is approximately in the middle of a connecting section 210a formed which is formed on the curved front end portion thereof. There is also a solder piece 210b for soldering to a circuit board 221 at the bottom of the bottom element 210 educated.

Furthermore, although the detailed description thereof is given below, the e-network element is 211 shaped by machining a metal plate so as to have an approximately rectangular radiation surface, a connector extending from about a center of an edge thereof being bent in a square U-shape and a holding piece 211 is formed at the front end thereof. This holding piece 211 appears in a cut window that is in the upper part of the main element of the lower element 210 is formed, inserted, and it holds the lower element 210 on each side of it. By soldering the part held in this way, the E-Netz element 211 on the lower element 210 attached and also electrically connected to it. As described below, this E-Netz element has 211 an enlarged radiation surface with an approximately rectangular shape so that it has essentially omnidirectional properties in the horizontal plane. In addition, each end section of the E-network element 221 bent slightly forward, and both corner portions of the upper edge thereof are cut away by machining. This is so the E network element 211 in one through the back of the bottom element 210 and the side wall of the cover section 202 formed accommodation space can be accommodated. Bending the E-Netz element 211 and removing the two corner areas therefrom does not affect the directional properties of them in the horizontal plane.

With the multi-frequency antenna 200 According to the second embodiment of the present invention, by means of the above-mentioned composition, the separate D-network element 213 and the lower D-mesh element 210 connected when the antenna element 201 in the cover section 202 is screwed. In other words, with the multi-frequency antenna 200 According to the second embodiment of the present invention, the D-network antenna is an antenna located in an area between the circuit board 221 and the lower end of the choke coil 214 is working. In addition, the E-network antenna is an antenna that is in an area between the circuit board 221 and the top of the bottom element 210 is working. Furthermore, the AM / FM antenna is an antenna that is in the area between the circuit board 221 and the antenna tip 322 is working. However, it does not vibrate in the AM band.

Next is the individual composition of the bottom element 210 and the E-Netz element 211 in the multi-frequency antenna 200 the second embodiment of the present invention with reference to 27 and 28 described.

27 shows the detailed structure of the lower element 210 : 27 (a) is a front view of the lower member 210 ; 27 (b) is a side view of the same; 27 (c) is a rear view of the same, and 27 (d) is a bottom view of the same.

As shown in these drawings, the bottom element has 210 a plate shape; the front end portion thereof being bent into an approximately L-shape in cross section by machining a metal plate. The curved front end portion thereof is called a connection portion 210a taken, and a screw thread section 210d in which the terminal insertion section 212a is screwed is approximately in the middle of this connecting section 210a educated. There is a taper on the main piece 210c attached, extending from the end of the connecting section 210a extends downward so that it has a narrower width at its lower end, and the upper part thereof is slightly towards bent to the back. A solder piece 210b for soldering to the circuit board 221 is at the bottom of the main piece 210c educated. It is also part of the upper part of the main piece 210c cut out to a cut window 210e to build. The length of the bottom element 210 is shaped slightly longer than the lower element 10.

28 shows the detailed structure of the E-Netz element 211 : 28 (a) is a front view of the E-Netz element 211 ; 28 (b) is a side view of the same, and 28 (c) is a bottom view of the same.

As shown in these drawings, the E network element 211 formed with an enlarged radiation surface with an approximately rectangular shape by machining a metal plate, and end pieces 211d . 211e on each side are slightly bent forward on the approximately rectangular radiation surface, and both corner portions of the top edge thereof are cut away by machining. It also becomes a connector 211f and a curved piece 211b by extending a portion from about the center of the top edge of the element 211 and bending it into a square U-shape. A stop 211 is done by cutting off part of the leading edge of the bent piece 211b educated.

This stop 211 is used to on each side of the cut window 210e to sit around an upper part of the main piece 210c of the bottom element 210 to build. If so, the E-Netz element can 211 on the lower element 210 can be attached, and a mutual electrical connection can be made by the holding piece 211 around the edge of the cut window 210e is soldered around. If the bend angle of the center piece 211c in relation to the connector 211f is set to greater than 90 ° when the E-Netz element 211 on the lower element 210 is attached, the lower element 210 and the centerpiece 211c of the E-Netz element 211 are roughly parallel, as in 26 shown.

The multi-frequency antenna 200 according to the second embodiment of the present invention works simultaneously as a four-frequency antenna for D-network and E-network mobile phone bands and an AM / FM band, and also GPS signals can be obtained by means of a separately provided GPS unit 223 be received. In this case, if there are no AM / FM band facilities and therefore the AM / FM antenna is superfluous, it is possible to use only the D-network element 213 , which is one of the divided elements, within the antenna base section 230 accommodate. In this way, the multi-frequency antenna 200 according to the second embodiment of the present invention, be a multi-frequency antenna, which by means of the antenna element 201 only works in the D network and the E network. In this case, the length of the antenna element can of course 201 be shortened accordingly.

Next, the construction of the D-network and E-network antenna in the composition of 24 described by the following explanation of the basic construction principles of an antenna that is used as a multi-frequency antenna that works in this way only in the D network and E network.

29 (a) shows the basic structure of an antenna, which works in the D network and E network, with respect to the multi-frequency antenna 200 according to the second embodiment of the present invention.

As in 29 (a) shown, the split D-network antenna is a linear antenna of length L11 that have an upper section that is a D mesh element 213 forms, and includes a lower portion that a lower element 210 the length L12 forms. The D network antenna thus constructed protrudes at an angle in a slightly inclined manner θ2 with respect to the horizontal plane. An electric network element 211 with a length L13 is connected to an area where the D-network element is 213 with the bottom element 210 united. The E-Netz element 211 is roughly parallel to the bottom element 210 arranged by length L14 of the connector described above 211f separated from it. The front end of this connector 211f is connected to an intermediate part of the D-network antenna by the D-network element 213 and the lower element 210 is formed. The structure of the e-network element 211 is like in 28 is illustrated, and its approximate shape is shown in 29 (b) and (C) illustrated, the width of the rectangular shape forming the enlarged radiation surface as W2 is taken. The lower end of the lower element 210 forms an electricity feed point for the D-network antenna and the E-network element 211 as illustrated in the drawings.

In the 29 shown dimensions, namely the length L11 the D-network antenna by the D-network element 213 and the lower element 210 is formed, the length L12 of the bottom element 210 , the length L13 and the width W2 of the E-Netz element 211 and the distance L14 between the D-network antenna and the E-network element 211 are according to the frequency values of the first frequency band for the D network and the second frequency band for the E network and the angle used θ2 certainly. If the z. B. the angle θ2 is about 50 °, if the wavelength at the center frequency of the D network is 915 MHz λ1 (327.87 mm) and the wavelength at the center frequency of the E-Netz 1795 MHz as λ2 (167.23 mm) is assumed to be the length L11 the D-network antenna as about 0.221 λ1 , the length L12 of the bottom element 210 than about 0.174 λ2 , the length L13 of the E-Netz element 211 than about 0.102 λ2 , the width W2 the same as about 0.149 λ2 and decency L14 between the D-network antenna and the E-network element 211 than about 0.015 λ2 be taken.

The distance L14 is small, as described above, because the accommodation space within the cover portion 202 is narrow, and since this accommodation space is narrow, the width is W2 of the E-Netz element 211 also small, and the bend angle of the end pieces 211d . 211e is getting tighter. The length of the D-network antenna and the E-network element 211 but is getting bigger.

The multi-frequency antenna 200 the second embodiment of the invention, as in 24 has essentially the same properties as the multi-frequency antenna 100 with regard to the first embodiment in the form of the impedance properties and VSWR properties of the multi-frequency antenna 200 in the D-Netz and E-Netz frequency bands, if the aforementioned constants for the dimensions of the length, width and distance of the D-Netz element 213 , the lower element 210 and the E-Netz element 211 be taken. The directional properties in the horizontal plane and the directional properties in the vertical plane of the multi-frequency antenna are of further importance 200 in the D-network and E-network frequency bands in this case essentially the same as the directional properties of the multi-frequency antenna 100 after the first run.

In the first and second embodiment of the multi-frequency antenna according to the invention described above, the E-network elements are 11 . 211 shaped so that they have an enlarged radiation surface with an approximately rectangular shape. This is so that the straightening properties are essentially non-directional in the horizontal plane, but if no non-directional properties are required in the horizontal plane, the E-net elements can 11 . 211 be formed with a narrower width. In addition, if the widths of the E-network elements 11 . 211 than about 0.12 λ2 or above, essentially omnidirectional properties are obtained in the horizontal plane.

In the multi-frequency antenna according to the invention becomes a second antenna, the z. B. forms an E-network antenna, with the intermediate part of a first antenna, the z. B. forms a D-network antenna. It is believed that the fact that the two antennas when composed in this way, work without mutual, disadvantageous Cause effects related to the fact that the second antenna operates in a frequency band that is about twice is as high as the frequency band in which the first antenna operates.

INDUSTRIAL APPLICABILITY

Since the present invention in the is constructed above, a second element with an extended, rectangular radiation surface that is in a second frequency band, the higher as a first frequency band, operates with an intermediate range of a first element connected in the first frequency band is working. By adopting this composition, though the principles of operation are not obvious, the antennas able, without mutual, adverse effects even over one first frequency band and a second frequency band, which is a broad Cover the frequency band like the cellphone bands, independently work. Because the radiation surface of the second element expands is it is possible To achieve omnidirectional properties in the horizontal plane.

In this case it will be for a deep one Frequency band used first element divided into two, the divided one lower element is housed within a cover section, while a second element is also housed within the cover section is achieved, whereby a compact multi-frequency antenna can be. It is also possible, a circuit board having a frequency divider and the like includes in to accommodate the space within the cover section.

By providing an item, that in a very low frequency band, e.g. B. an AM / FM band, works over a choke coil at the top of the first element, it is also possible to use one Multi-frequency antenna to bring about that at three or more Frequencies works. If in the accommodation space within the Cover a GPS antenna unit is provided, it is possible that GPS signals without interference to receive the other antennas.

Claims (4)

(Modified) multi-frequency antenna comprising a first element operating in a first frequency band and a second element connected to an intermediate region of the first element having a rectangularly enlarged radiation surface and in a second frequency band higher than the first frequency band, works, characterized; that it includes: an upper member of the first member, the first member divided into two members, and a cover section that has a connection section on which the upper member can be detachably installed, and an installation section for installing the same on an installation receiving object is provided, the other lower member of the divided first member provided between the connection portion and a power supply section and the second member connected to the upper member being housed within the cover portion, and the upper member and the lower member by installing the obe Ren element on the connecting section are mutually connected. Multi-frequency antenna according to claim 1, characterized in that a third element that is in a much lower frequency band as the first frequency band works, at the top of the top Elements about a choke coil is provided. Multi-frequency antenna according to claim 1, characterized in that a GPS antenna unit also within the cover section provided. Multi-frequency antenna according to claim 2, characterized in that a GPS antenna unit also within the cover section provided.