DE69824262T2 - antenna - Google Patents

Description

Of the The invention relates to an antenna structure, which in the preamble of claim 1, and an antenna structure disclosed in Mobile stations operating in two frequency ranges, applicable is as set forth in the preamble of claim 9.

The Development of mobile station technologies has brought and brings new versatile Models on the market, where new requirements for the antennas be placed: the antenna must z. B. in two frequency ranges such as the 900 MHz range and the 1.8 GHz range; the Bandwidths need be relatively large; The radiation and reception properties must be different in both Positions of the device and the antenna as well as in different Layers be good with respect to external objects and the antenna still needs to be relatively small and compact.

1 shows previously known antenna structures that operate in two frequency ranges.

1) Structures on the Basis of a spiral:

• - A double spiral: two spiral elements 101 and 102 with different resonance frequencies are placed in an overlapping manner in each other or one above the other. The elements have either a common or a separate feed.
• - A spiral and a monopoly: in a spiral element 103 is a rod element 104 , which has a different resonant frequency, placed. The elements have either a common or a separate feed.

disadvantage the spiral-based structures are the relative ones high production costs and the significantly deteriorating Properties when the antenna is near the frame of the device is arranged or in its proximity is pivoted.

In one mentioned as a reference publication WO 96/38881 discloses a monopole antenna as stated therein is implemented by a printed monopoly structure. The Antenna therein has a first printed circuit board. This should have a first and a second page. A first monopole radiating element in the form of a conductive trace intended to be printed on one side of the first PCB be formed while a second monopole radiating element in the form of a conductive track near of the first monopole radiating element is positioned. The first Monopole radiating element should be resonant in a first frequency band and the second monopole radiating element is intended to be in a second frequency band be resonant. So that the first and the second radiating element in different frequency bands are resonant, it is further described that the conductive traces for each different lengths have. Furthermore is described as having no direct electrical connection between the monopole radiating elements is present, but the second Emitter element dominated on one frequency, at which the second Radiator element measures about half a wavelength, so that a coupling takes place with the first radiating element. The first monopole radiating element and the second monopole radiating element are on the same side of FIG first printed circuit board, on separate sides of the first printed circuit board or on separate printed circuit boards educated.

2) microstrip structures

• - A double stripe: a spotlight stripe 105 is on the surface of a dielectric plate, with another strip in it 106 is located, which has a different resonance frequency. The power is applied z. B. to the strip 105 , where the strip 106 is parasitic. The ground plane 107 is on the other surface 108 the plate.
• - A strip and a transmission line: On the surface of a dielectric plate 111 there is a strip 109 as well as a strip 110 acting as part of a shorted transmission line. The transmission line is dimensioned to emit at one of the two desired frequencies.

One Disadvantage of the illustrated and other microstrip structures is their relatively narrow bandwidth. An improvement can be achieved be parasitic by Elements are added to the structure, but then the relatively large one Size of the structure a disadvantage is.

3) chip structures

In a dielectric monolithic body 114 There are two conductors 112 and 113 with a meander shape that emit at different frequencies. The disadvantage of these structures is the relatively narrow bandwidth.

In addition to The structures shown above are dual band antennas on the Basis of a half-wave dipole. Their disadvantage is a relatively large size.

The object of the invention is to reduce the above-mentioned drawbacks related to the prior art. An antenna according to the invention is characterized by what is shown in claims 1 and 9. Some before Preferred embodiments of the invention are shown in the dependent claims.

The The basic idea of the invention is as follows: On one side of a small dielectric plate such as a printed circuit board is a regularly or almost regularly repeating Ladder pattern at one end with a ladder for reception and the antenna feed is connected. On the opposite Side of the plate or in it is a parasitic coupled Conduction area, which is formed so that the structure is two relative has widely spaced resonance frequencies.

Of the Advantage of the invention is that the bandwidths in each Operating range are wider than in the previously known structures. This is important, especially if the device is in different Positions is used and when the passbands u. a. move slightly because of a shifted position. Another Advantage of the invention is that when the antenna is short and flat, it is possible on the one hand is she in a protected Position near to swing the frame of the device, and that on the other hand their electrical properties will then remain adequate because of the distance is kept relatively large to the device frame. Another Advantage of the invention is that they because of the flat Shape of the antenna on the back wall can be placed in mobile phones, with the head of the User's absorbed power (SAR) is as low as possible. Another advantage of the invention is that the cost the antenna are relatively low because of the simple structure.

The Invention is detailed below described. In the description, refer to the attached drawing Reference is made in the

1 Two band antennas according to the prior art shows;

2 shows a typical antenna according to the invention;

3 shows the band characteristics of the antenna according to the invention;

4 shows a mobile station mounted antenna in different situations;

5 shows some modifications of the antenna according to the invention; and

6 shows a mobile communication means according to the invention.

The structures of 1 have been described above in connection with the description of the prior art. In 2 There is a structure according to the invention, which is a dielectric plate 21 , one with the feedline 25 the antenna connected radiator element 22 and a parasitic radiating element 23 includes. The dielectric plate in this example is the dielectric layer on the printed circuit board. The element 22 is a right-angled meander-type conductor pattern on the other side of the plate 21 z. B. is formed by etching. Meander in this context refers to a line without branches, wherein a certain basic shape or its variations or different basic shapes are repeated in sequence in the same direction. Examples of the meander pattern are in the 5 shown. The element 22 is referred to below as a meander element. A parasitic element is a conductor which is galvanically isolated from the other conductors of the system but which has an electromagnetic coupling with them. In this example is a parasitic element 23 a conductor region formed by etching on the surface opposite to the meandering element and electromagnetically coupled to the meandering element. The reference numerals concerning the characteristics of the antenna are also in FIG 2 characterized: the thickness d of the dielectric layer, the height h of the meandering element 22 , the width w of the meander element, the height s of the repeating pattern in the meander element, the width w _{1 of} the conductor of the meander element, the height h _{p of} the parasitic element 23 , the width w _{p of} the parasitic element, the height difference e ₁ + e _{2 of} the meander element and the parasitic element, of which e _{1 is} at the upper end of the structure and e ₂ at the lower end. The height direction is here and in particular in the claims, the direction of the largest dimension h of the meandering element.

The structure of 2 has two resonant frequencies, the lower of which is mainly due to the meandering element 22 and the upper one mainly through the parasitic element 23 is determined. The elements naturally influence each other and thus have an effect on both resonance frequencies. The structure is characterized in that the resonance frequencies are relatively far apart, with a z. B. may be located in the frequency range used by the GSM network and the other in the frequency range used by a PCN network or satellite telephones. The structure is characterized in particular by the fact that the bandwidths in both the upper and the lower operating region are relatively large. Namely, the planar parasitic element causes a broad upper band, and it is also effective in the lower band in a way that widens it. If z. B. is desired that the upper Band as wide as possible, the parasitic element must be dimensioned as a broad element, where it must be placed down so that the dimension e _{1 is} relatively large. Wider bandwidths can also be obtained without changing the resonant frequencies by making the meander patterns with wider spaces or by increasing the dimension s and by simultaneously increasing the heights h and _{hp of} the radiator elements. Consequently, a compromise must be made between the bandwidths and the antenna size. The properties of the antenna are affected by the antenna dimensions as well as the material between the meander element and the parasitic element: as the dielectric constant of the dielectric plate is increased, the upper resonance frequency decreases.

The band characteristics of an antenna are often examined by measuring its return loss A _r as a function of frequency. Return loss refers to the ratio between the energy supplied to the antenna and the energy returning from it. It is the absolute value of the inverse of the square of the reflection factor or the parameter s ₁₁ . The higher the return loss, the larger the part of the energy supplied to the antenna that is radiated into the environment, or the better the antenna works. In an ideal case, the return loss is therefore infinitely large. If the return loss is 1 or 0 dB, the antenna does not radiate at all; whereby all the energy supplied to her flows back to the source of supply. The reception characteristics of the antenna follow the transmission characteristics: the more effectively the antenna transmits at a certain frequency and direction, the more effectively it receives on the frequency from the direction. The bandwidth of the antenna can be defined in several ways: it can denote the difference between the frequencies at which the return loss has dropped 3 dB from its best value or its maximum value. Often the bandwidth is considered to be the difference between those frequencies where the value of the return loss is 10 dB or 10. This corresponds to the value 2 of the standing wave ratio SWR.

The 3 shows an example of the change in the return loss A _{r of} an antenna according to the invention as a function of the frequency in different operating situations. The measurement results were obtained with the following dimensions of the antenna: h = 29.3 mm; w = 5.4 mm; _hp = 24.4 mm; w _p = 5.4 mm; e ₁ = 4.2 mm; e ₂ = 0 mm; s = 1.6 mm; w ₁ = 0.5 mm and d = 0.76 mm. The dielectric constant of the printed circuit board is _-r = 2.5. The measuring range in 3 runs from 800 MHz to 2.2 GHz. The thin solid curve 31 corresponds to the situation of 4a : The antenna is on the outside and faces up and there are no other objects nearby. The thick solid curve 32 corresponds to the situation of 4b : There is now a human head near the mobile station. The dotted line 33 corresponds to the situation of 4c : The antenna is on the outside but in a tilted position such as during normal operation in a multi-function mobile station. The dashed line 34 corresponds to the situation of 4d The antenna is pivoted to a protected position, such as near the frame of the mobile station. In the following, the band limits are defined as frequencies where the return loss is 8 dB = 6.3 (SWR ≈ 2.3) except in the case of the tilted antenna 34 where the bandwidth is defined based on the -3 dB points. The curve 31 shows that when the mobile station is in a free space, the lower area comprises about 900 to 975 MHz and the upper area about 1,670 to 1,940 MHz. The curve 32 shows that in the situation of a normal call, the lower range comprises about 880 to 975 MHz and the upper range about 1,630 to 1,920 MHz. The 33 shows that in the operating position of a multi-function mobile station, the lower range comprises about 885 to 975 MHz and the upper range about 1690 to 2100 MHz. The 34 shows that when the antenna is panned, the lower range is about 845 to 975 MHz and the upper range is about 1,625 to 1,890 MHz. It is noted that the position of the regions and their widths are dependent on the position of the antenna and on the environment, but in all cases the regions cover the regions used by the GSM network and the PCN network. When the antenna is in the tilted position, the average return loss in the pass band is on the order of 10 dB less than in the normal position. Of course, the transmission power is lower, but in most cases still sufficient.

Above, an antenna structure according to the invention and its features has been described by the inventors. The invention is not limited to the solutions presented above. For example, the number and shape of the radiator elements may vary. 5 shows examples of some possible modifications. In 5a the meander element comprises straight sections as in 2 However, the angles between the conductor sections deviate from an extended angle. Further, the width of the pattern increases in the downward direction. In 5b The meandering element comprises straight sections which, however, form a triangular wave pattern. In this example, the parasitic element is elliptical rather than rectangular. In 5c The meandering element comprises circular arcs and straight lines. A gap 51 has been formed in the parasitic element, the gap radiating in a third frequency range. An antenna similar to this one can now be dimensioned to operate in frequency ranges used by three systems. With the same intention 5d a second parasitic element 52 on the same side of the printed circuit board as that of the feeder or the meandering element. The material of the dielectric plate may also vary: in addition to the materials typically used in printed circuit boards, it may be e.g. As polytetrafluoroethylene (PTFE) or another plastic. The radiating elements can also be formed in the surface of the dielectric plate in some other way than by etching, e.g. B. by steaming or by editing the conductor surfaces of the printed circuit board: z. For example, a conductive material may be deposited by vapor deposition or screen printing on the surface of the plate.

6 shows a block diagram of a digital mobile communication means according to an advantageous embodiment of the invention. The mobile communication means comprises a microphone 301 , a keyboard 307 , an ad 306 , a listener 314 , an antenna duplexer or an antenna switch 308 and a control unit 305 , which are all typical components of conventional mobile communication media. Further, the mobile communication means includes typical transmission and reception blocks 304 . 311 , The transmission block 304 includes the functionality required for voice and channel coding, encryption and modulation, as well as the necessary RF circuitry to amplify the signal for transmission. The reception block 311 includes the necessary amplifier circuits and the variety of functions necessary for demodulating and decrypting the signal as well as removing the channel and speech coding. That from the microphone 301 signal generated is in the amplifier stage 302 amplified and in the A / D converter 303 converted into a digital form, whereupon the signal to the transmission block 304 is brought. The transmit block encodes the digital signal and generates the modulated and amplified RF signal, whereupon the RF signal is transmitted through the duplexer or switcher 308 to the antenna 309 is brought. The reception block 311 demodulates the received signal and removes the encryption and channel coding. The resulting speech signal is in the D / A converter 312 converted into an analog form, wherein the output signal in the amplifier stage 313 is amplified, whereupon the amplified signal to the listener 314 is brought. The control unit 305 Controls the functions of the mobile communication device, reads the user's keyboard 307 given commands and displays the messages to the user about the ad 307 at. The mobile communication device further comprises an antenna structure 309 , The antenna structure 309 preferably has a structure corresponding to the above-described antenna structure according to the invention or any of the equivalent antenna structures.

Claims (9)

Antenna having a first operating band and a second operating band and a first element ( 22 ), which is connected to its feed line, and at least one parasitic element ( 23 ), wherein - the support structure for the first element ( 22 ) and for the parasitic element ( 23 ) a dielectric plate ( 21 ) and the first element ( 22 ) and the parasitic element ( 23 ) on opposite sides of the dielectric plate ( 21 ) are arranged, - wherein the first element ( 22 ) is a meandering element that determines a first operating band whose width is determined essentially by the dimensions of the meandering element, characterized in that - the parasitic element ( 23 ) is a planar conductor region which determines a second operating band whose width is determined essentially by the dimensions of the parasitic element, and - the meandering element ( 22 ) with the parasitic element ( 23 ) is electromagnetically coupled to widen at least one of the operating bands. Structure according to Claim 1, characterized that the width (w) of the meandering element to a first point in the height direction is different from its width at a second point in height direction. Structure according to claim 1, characterized in that the height (h _p ) of the parasitic element ( 23 ) lower than the height (h) of the meander element ( 22 ). Structure according to claim 1, characterized in that the width (w _p ) of the parasitic element ( 23 ) at a first point in the height direction is different from the width at a second point in the height direction. Structure according to claim 1, characterized in that the dielectric plate ( 21 ) is the dielectric part of a printed circuit board. Structure according to claim 5, characterized in that the meander element ( 22 ) is a conductor region on the first surface of the printed circuit board and that the parasitic element ( 23 ) is a conductor area on the second, opposite surface of the printed circuit board. Structure according to claim 1, characterized in that the parasitic element ( 23 ) a radiator gap ( 51 ) owns. Structure according to claim 1, comprising a first parasitic element and a second parasitic element ( 52 ), characterized in that the second parasitic element ( 52 ) is a conductor region located on the same side of the dielectric plate as the meandering element. Mobile station comprising an antenna having a first operating band and a second operating band and a first element ( 22 ), which is connected to its feed line, and at least one parasitic element ( 23 ), wherein - the support structure of the first element ( 22 ) and the parasitic element ( 23 ) a dielectric plate ( 21 ), the first element ( 22 ) and the parasitic element ( 23 ) on opposite sides of the dielectric plate ( 21 ), - the first element ( 22 ) is a meandering element that determines a first operating band whose width is determined essentially by the dimensions of the meandering element, characterized in that - the parasitic element ( 23 ) is a planar conductor region which determines a second operating band whose width is determined essentially by the dimensions of the parasitic element, and - the meandering element ( 22 ) with the parasitic element ( 23 ) is electromagnetically coupled to widen at least one of the operating bands.