SE528069C2 - Mobile phone antenna, has antenna component powered by resonator with metallized surface and specific resonance frequency - Google Patents

Abstract

The antenna component (405) is powered in a non-galvanic manner via a resonator (409) having a resonance frequency which is greater than the top frequency in the top frequency band for the antenna. The resonator has a metallized surface facing the antenna component. At least one frequency arm (413, 415) cooperates with an earth plane (401).

Description

528 528 069 2 thin metal plate is applied to a non-conductive holder of, for example, plastic, which for reasons of inadequacy is not shown in the figure. The holder can then be mounted against a circuit board containing a ground plane 109. The antenna element 105 has a galvanic connection to the ground plane at point 107 and also a galvanic connection to RF at point 101 or 103. If the RF connection takes place at point 101, an optimal adaptation to it is obtained. high frequency band utilizing frequency arm lll and if the connection is made in point 103, the adjustment will be optimal in the low frequency range utilizing frequency arm 113.

A variant of this solution is shown in GB 2403069, in which an integrated antenna unit is described consisting of a first, dielectric antenna and a second, electrically conductive antenna, where the first and second antennas are not electrically connected to each other but are arranged so that the second antenna is driven by the first antenna when the first antenna is fed with a predetermined signal, where the second antenna is connected to ground, and where the first and second antennas are configured to radiate in different, non-overlapping frequency ranges.

GB 2403069 requires that a portion of the ground plane below the dielectric antenna be removed or, in another embodiment, with an entire ground plane below the dielectric antenna, that the dielectric antenna be shaped in a particular manner to obtain resonance at a desired frequency.

Disclosure of the Invention The present invention has for its object to provide an antenna which can be built into a mobile terminal unit, hereinafter exemplified by mobile telephone, which eliminates disadvantages of prior art and to provide a solution with very compact outer dimensions that is simple and cheap to manufacture.

Furthermore, the invention has for its object to provide an antenna which enables resonance in up to four or more frequency bands.

These objects are achieved in that an antenna is provided which comprises at least one antenna element with at least one frequency arm which is arranged to co-operate with a ground plane and a resonator for feeding the antenna element. The antenna element is arranged to be fed non-galvanically via a resonator whose resonant frequency is above the uppermost frequency in the uppermost frequency band for which the antenna is intended and has a metallized surface of the resonator facing the antenna element.

The resonator's task is only to transfer RF energy between the antenna element and the mobile telephone's reception and transmission circuits and to function as an impedance adaptation to the radiator's different frequency arms. The resonant frequency of the resonator is thus not used in any of the frequency bands within which the antenna is intended to operate.

With this solution, hereinafter referred to as DFA (Dielectric Feed Antenna) antenna, a very production-friendly, inexpensive and compact antenna solution is achieved with optimal impedance matching in all frequency bands and thus good antenna function. Because the resonator can be placed very close to the antenna element, a thin antenna construction can be obtained with a short distance between the antenna element and the ground plane. 10 15 20 25 528 069 4 The DFA antenna cooperates with a ground plane and in one embodiment can advantageously be placed over the circuit board of the mobile telephone and utilize the ordinary ground plane of the circuit board without modifications. This is advantageous compared to the solutions according to older technology where a part of the ground plane under the ceramic element needs to be removed in order to obtain optimal function. In other embodiments of the invention, interaction with the ground plane can take place by integrating the antenna element in the ground plane of the mobile telephone circuit board. This means fewer components, a compact design and simple and cost-effective manufacturing.

Additional advantages are obtained if the object of the invention is also given one or more features according to the dependent claims.

Brief description of the figures The invention will now be described in more detail with reference to the accompanying drawings. On these shows: Figure 1 shows a PIFA in accordance with prior art.

Figure 2 schematically shows a mobile telephone comprising an antenna in accordance with the present invention.

Figure 3 shows schematically the transmission of RF energy.

Figure 4a is a schematic top view of a DFA in accordance with the present invention.

Figure 4b is a schematic side view of the DFA in Figure 4a.

Figures 5a and 5b schematically show two examples of quartz wave resonators. Figure 15 schematically shows a resonant curve of a pentaband antenna.

Figures 7a and 7b are schematic top and side views of meander antenna elements in accordance with the present invention.

Figure 8 shows a schematic antenna element in the form of an E-way meander slot in the ground plane in accordance with the present invention.

Figure 9 schematically shows a combination of two antenna elements, slot and structure according to Figure 4, in accordance with the present invention. Figure 10 shows a schematic antenna element in the form of a PILA structure in accordance with the present invention.

Figure 11 shows a schematic antenna element in the form of a one-way slot in the ground plane in accordance with the present invention.

Figure 12 shows schematically antenna elements and parasitic antenna elements in accordance with the present invention.

Figure 13 schematically shows two galvanically coupled antenna elements in accordance with the present invention.

Figure 14 shows schematically curved antenna elements in accordance with the present invention.

Preferred Embodiments As initially stated, the invention aims to provide an antenna with possibilities for resonance in one or more bands, here called DFA antenna, intended for use in a mobile terminal unit such as for example a mobile telephone according to figure 2.

Figure 2 shows a mobile telephone 201 comprising a control unit 207 which is arranged to control communication with a mobile communication system 203. To the control unit 207 a keyboard 213, a monitor 215 and radio frequency circuits 209 are connected which together with an antenna 211 are arranged to maintain a radio interface 205 for communication with the mobile communication system 203.

In one embodiment, the antenna can cover a low and a high frequency range. The low range can, for example, consist of the range 824-960 MHz, which covers the GSM 800 and GSM 900 bands (GSM = Global System for Mobile communication). The high range can, for example, consist of 1710-2170 MHz, which covers the GSM 1800, GSM 1900 and UMTS (Universal Mobile Telecomunication System) bands. This means that several bands can be covered with a compact, single-feed antenna. GSM 800 and 1900 are mainly used in the USA and GSM 900 and 1800 in Europe. The UMTS frequencies are used in the so-called 3G telephones (third generation telephones).

An antenna can thus cover the frequency bands for both GSM and UMTS, which is desirable for the telephones that are to operate in both systems.

The resonator can consist of a standard M-path coaxial resonator of ceramic that has a resonant frequency of about 2.1 GHz. The resonant frequency must be well outside the frequency bands that the antenna is to cover. This resonator can therefore be used to cover frequency bands up to about 2 GHz and can thus be used for a four-band antenna covering GSM 800, 900, 1800 and 1900. If the UMTS band is also to be covered, the resonator frequency should be 10 15 20 25 30 528 069 7 at about 2.3 GHz which is well above UMTS upper limit frequency of 2.17 GHz. “By using the resonator, a broadband transmission of RF energy is obtained with low losses from the generator to the resonator, from the resonator to the antenna element and from the antenna element to free space. Figure 3 shows the different transitions.

Between a generator 305 and a resonator 307, a galvanic coupling is normally used between the generator's RF conductor 302 and a plated metal surface on the resonator 307. Since low losses are important, matching components should be avoided. A resonator 307 with close to 50 ohms impedance should therefore be selected. An antenna element 303 and RF wire 302 are connected to a ground plane 301.

From the resonator 307 to the antenna element 303 a non-galvanic, "hard" coupling is used. This is controlled by selecting a resonator 307 of suitable size and dielectric constant and by locating the resonator 307 against the antenna element 303.

For transmission to the free space 309 impedance of 377 ohms, normal antenna rules apply. It is above all a matter of getting as large a loss-free conductive surface as possible on the antenna structure.

Figure 4a shows a preferred embodiment of a DFA (Dielectric Feed Antenna) 400 antenna. The antenna 400 comprises an antenna element 405 with a ground connection 403 to a ground plane 401. The antenna element 405 may be a thin metal plate, circuit board, flex film or other material. with good conductive properties in the current frequency range, eg conductive polymeric materials or metamaterials mounted on a non-conductive holder. The holder is not shown in the figure. The RF supply 407 of the DFA4 antenna is made by galvanic connection to a resonator 409 at a point 411. The resonator 409 connects (see Figure 4b) to the antenna element 405 consisting of a high frequency arm 413 then non-galvanically via a gap 417 and a low frequency arm 415. The advantage of this coupling principle is that the RF coupling to the antenna element 405 is not made via a galvanic point connection as with conventional technology but by making the connection over a surface, indicated at 410, between the two frequency arms 413, 415 of the antenna element 405 corresponding to the resonator 409 field image projection towards the antenna element 405. With conventional technology and galvanic connection, the connection point must be laid either at a point that is optimal for the high or low band. With a connection according to the invention, a geographically distributed connection is obtained over a surface which means that optimal impedance matching can be obtained for both frequency bands. The impedance matching can then be fine-tuned by the orientation of the resonator 409 relative to the antenna element 405 and by selecting a dielectric constant for the resonator 409 s s 30-100. Normally a value around 90 is preferable but also higher or lower values may be conceivable. Characteristic of the invention is also that the resonant frequency of the resonator 409 must be selected so that it is well above the uppermost frequency in the uppermost frequency band, as discussed further with reference to Figure 6. A resonator 409 with a high dielectric constant has a very narrow bandwidth around its travel. nance frequency, normally only one or a few MHz, which means that the frequency band of the resonator can be seen as a “nail” compared to the wide frequency band of the antenna element 405 at 100-500 MHz. If the "nail" of the resonator 409 is placed in one of the frequency bands of the antenna element 405, will the antenna function surprisingly deteriorate precisely at the "nail frequency"? due to the fact that circulating currents occur in the resonator 409 at this frequency.

This means that the resonator 409 does not significantly participate in the radiation at the "nail frequency". By selecting the resonant frequency of the resonator 409 well outside the frequency ranges of the antenna element 405 described above, this negative effect is avoided while the effect is achieved that an RF transmission can take place efficiently via the resonator 409 to both the low and high frequency arms 413, 415. frequency range.

In addition, an optimal impedance matching is obtained for both the high and low frequency band with the help of the “geographically distributed connection” described in Ovâfl.

Figure 4b shows a side view of the DFA antenna shown in Figure 4a, with the antenna element 405, the ground plane 401, the resonator 409 with a longitudinal axis 410 indicated, the RF supply 407 and the galvanic connection to the resonator via the point 411. The ground connection 403 is not shown thereon. figure. The transition between the resonator 409 and the antenna element 405 takes place with a "hard" non-galvanic coupling, i.e. the gap 417 between the resonator 409 and the antenna element 405 is small, typically 0.2-0.3 mm. This further facilitates to provide a thin antenna construction where a distance 419 between ground plane 401 and antenna element 405 can be kept short. The column 417 can normally consist of air, but other non-conductive materials with a low loss factor can also be used. The DFA antenna in the embodiment according to Figures 4a and 4b is a so-called ground plane dependent antenna, i.e. the ground plane 401 must be accessible under the entire antenna element 405 and also a bit outside. The larger the ground plane 401, the better the antenna function. The ground plane 401 is, as shown in Figure 4b, substantially parallel to the antenna element 405.

A mobile phone normally contains a so-called multi-layer circuit board where one of the layers forms a ground plane. In this embodiment, a DFA antenna can therefore advantageously be placed over the circuit board and use the circuit board's ordinary ground plane without modifications. This is advantageous compared with the solutions according to older technology where a part of the ground plane under the ceramic element needs to be removed in order to obtain optimal function.

Figures 5a and Sb show two examples of two embodiments of typical standard resonators 500, 500 'of coaxial type which can be used to advantage in an antenna according to the invention. The materials of the resonators 500, 500 'preferably consist of an insulating ceramic material with a high dielectric constant, but other materials with a high dielectric constant can also be used. All sides except the underside 501, 501 'of the resonators 500, 500' are metallized. The RF signal is connected to a center conductor 503, 503 '. The resonators 500, 500 'also have a continuous channel 505, 505' which is internally metallized to obtain a so-called coaxial resonator. Figure 5a shows a parallelepipedic quartz wave resonator 500. Typical dimensions of this resonator at a resonant frequency of 2.5 GHz and s ~ 90 are approximately 7x3x3 mm. Even lower s-values down to about 30 and significantly higher values can be used. Figure 5b shows a corresponding resonator 500 'in cylindrical design. So-called half-wave resonators can also be used. These resonators are twice as long for the same s-value and more expensive, which is why quartz wave resonators are normally preferred.

Figure 6 shows a schematic frequency diagram for a Pentaband antenna which thus covers five different frequency bands. The horizontal axis shows the frequency (f) and the vertical axis reflected energy (RL = Return Loss). With good antenna function, supplied energy is transferred to free space and only a small part of the energy is reflected back to the transmitter. (The antenna function is reciprocal so the corresponding ratio applies to received energy) Between the frequencies f1-f2 and f3-f4 the reflected energy is low and here energy is thus transferred to free space. By designing the antenna element according to Figure 4 with a low frequency arm 415 and a high 413, fl-f2 'can be laid at 824-960 MHz and thus cover the low GSM bands 800 and 900 and f3-f4 at 1710-2170 MHz to cover the high GSM bands 1800 and 1900 as well as the UMTS band. The resonance between f1 and f2 consists of a% wave resonance from the low frequency arm 415. To achieve the wide resonant band between f3 and f4, 460 MHz, a double resonance is used in that the first part between f3 and f5 consists of a The% -wave resonance from the high frequency arm 413 and the other part between f5 and f4 consists of an M-path resonance from the low-frequency arm 415. The resonant frequency of the ceramic resonator 409 is seen as a “nail” at f6.

The invention can also be applied in other frequency ranges than those described here. Within the scope of the principle of the invention, one, two or more frequency bands may be covered. In a preferred embodiment according to Figures 4 and 6, five frequency bands can be obtained. m 15 20 25 30 528 069 12 The resonator can also consist of materials other than ceramics.

The important thing is that the material has a high dielectric constant (high s-value) and a low loss factor for the current frequencies.

The design of antenna elements can take place mainly according to what is shown in figure 4. A requirement for the antenna elements is that they constitute effective radiators. They can thus be of varying types such as monopolies, patches, slot antennas (also called slot antennas), meanders. The antenna element can also have one or more frequency arms. Various combinations can also occur, such as a non-galvanic or so-called parasitic connection to a second antenna element, which can be a patch with one or more arms or a slot. Some examples of these alternative embodiments are shown in Figures 7-14. The RF supply can take place with the help of coaxial cable or so-called stripline supply on a circuit board.

Figure 7a shows a top view of an antenna element in the form of a so-called meander 701 which is fed non-galvanically via a resonator 703. RF supply takes place galvanically to the resonator's RF connection 705. A ground plane 707 can in this case lie in the same plane as the meander or in a plane approximately perpendicular to the meander plane. In the case where the meander 701 is in the same plane as the ground plane 707 of the mobile phone circuit board. The meander 701 can be designed, the antenna element can easily be integrated in a principles known to the person skilled in the art for resonance in one or more frequency bands, whereby one or more frequency arms can be provided. By varying the relative position between the resonator 703 and the antenna element 701, here exemplified by an angle α, the antenna can be tuned in to obtain an optimal combination of coupling degree and impedance matching. With a = 0 °, the connection becomes maximum, ie maximum with RF energy is transmitted to the antenna element and with d = 180 °, the transmission becomes minimal. By selecting an angle α approximately as shown in the figure, i.e. in this embodiment about ten degrees, an adjustment can be made to an impedance close to 50 S2 at the same time as the coupling becomes close to the maximum, which gives an optimal transmission of RF energy. .

Figure 7b is a side view of the antenna element 701 and the resonator 703 shown in Figure 7a. The dashed resonator 709 shows an alternative placement of the resonator to illustrate that the resonator can be placed above or below the antenna element. The resonator can also be placed next to the antenna element, which will be discussed with reference to Figures 10 and 12 below. The only criterion is that the resonator is placed close enough to the antenna element to obtain the optimal combination of coupling degree and impedance matching described above. Furthermore, the resonator is advantageously placed in the vicinity of the connection point of the antenna element or the first antenna element (in the case of more antenna elements according to Figures 12 and 13) to ground.

Figure 8, which is also a view from above, shows an antenna element in the form of a radiating so-called meander slot 801 in a ground plane 803. RF supply takes place via a resonator 805 and its RF connection 807. The meander slot 801 is shown here as a so-called half-wave slot, which means that the length of the slot 801 must correspond to half the wavelength of the desired resonant frequency. A half-wave slot is also characterized in that both ends of the slot 801 are completely enclosed by the ground plane 803. The slot 801 can also be designed for resonance in one or more frequency bands whereby the slot 801 can be said to consist of one or more frequency arms. In this case, the antenna element can thus be integrated in the ground plane to the circuit board of the mobile telephone.

Figure 9 shows a combination of a slot 901 and PIFA structure with two frequency arms 903 and 905 over a ground plane 907 having a connection point 909 with the antenna element. The slot 901 can here be said to constitute a third frequency arm. RF supply of both the slot and the PIFA structure does not take place galvanically via a resonator 911 and its RF connection 913. In addition, a normal interconnection between the PIFA structure and the slot takes place.

Figure 10 shows a perspective view of an antenna element designed as a PILA structure (Planar Inverted L Antenna) with a frequency arm 1001 over a ground plane 1003. The antenna element can also be made wire or band format and then becomes a variant of the antenna element 701 in Figure 7a (a meander with only a 90 ° bend) where the ground plane can lie in the plane of the antenna element or in a plane perpendicular thereto. Here too, an integration of the antenna element in a mobile telephone circuit board is possible in the case when the plane of the antenna element and the ground plane coincide. RF supply does not occur galvanically via a resonator 1005 and its RF connection 1007.

Figure 11 shows a top view of a ground plane 1101 in a circuit board of a mobile telephone. The ground plane 1101 has a slot 1103, constituting a frequency arm, which is open at one end, i.e. not enclosed by the ground plane 1101. The slot 1103 thus becomes an M-way slot which can be used in an upper frequency band. A frequency arm 1105 can be used as a wave resonant in the lower frequency band. The length of the frequency arm 1105 is the distance 1107 which can be reduced because the material of the circuit board normally has a dielectric constant s ~ 3-4. For air used in the slot, e = 1.

The shortening factor L = 1 / Va. With s = 4, the shortening factor thus becomes 0.5. RF supply does not take place galvanically via a resonator 1109 and its RF connection 1111. In this case, the antenna element can thus be integrated in the ground plane 1101 to the circuit board of the mobile telephone.

Figure 12 shows a side view of an antenna which is a variant of the antenna in Figure 10, but with an antenna element with two frequency arms 1201 and 1203, both with H-wave resonances and galvanic connection to a ground plane 1207. The antenna element arms 1201, 1203 feed non-galvanically a second antenna element 1205. An antenna element fed in this way is also usually called a parasitic antenna element. In a preferred embodiment, the length of the parasitic antenna element can be adapted for the half-wave resonance to suit, for example, the GPS frequency (Global Positioning System). RF supply does not occur galvanically via the resonator 1209 and its RF connection 1211.

Figure 13 shows a solution similar to that of Figure 12 but with galvanic connection between a first 1301 and a second antenna element 1302.

The embodiments according to Figures 12 and 13 can also be made in a two-dimensional embodiment in analogy to what is described for the embodiment according to Figure 10. In these embodiments, an integration in the mobile phone circuit board is also possible in accordance with what is described above.

Figure 14 shows an example of an embodiment with an antenna element 1401 made of electrically conductive so-called flex film well known to the person skilled in the art which is applied to a non-conductive holder 1403 of eg plastic with a curved surface 1404. The flex film has a galvanic connection 1405 to a ground plane 1407. A resonator 1409 is placed inside the holder so that optimal coupling and impedance matching is obtained. RF supply takes place via the resonator 1409 and its RF connection 1411. The ground plane can also be curved.

It is of course also possible that embodiments according to Figure 4 and Figures 7-11 and 13-14 can excite a parasitic element in a similar manner as shown in Figure 12.

The invention is also well suited for the use of so-called metamaterial as an antenna element in that the transformation of the energy into the antenna element takes place via a resonator whose frequency is outside the frequency ranges for which the antenna is intended to be used.

The reaction of a material to an electromagnetic field is determined by two parameters: the dielectric constant e which determines how the material reacts to an electric field, and magnetic permeability p which determines how the material reacts to a magnetic field.

These two parameters can be fine-tuned in metamaterials and in some cases assume negative values. As a result, the material can obtain new properties which enable a minimization of the size and weight of the antenna element at the same time as it can lead to a further increase in bandwidth.

Claims (15)

10 15 20 25 528 069 17 Patent claims An antenna for mobile terminal unit comprising at least a first antenna element (405) comprising at least one frequency arm (413,415), arranged to cooperate with a ground plane (401) and comprising a resonator (409) for feeding the at least first antenna element (405) characterized in that the antenna element (405) is arranged to be fed non-galvanically via the resonator (409) whose resonant frequency is above the uppermost frequency in the uppermost frequency band for which the antenna is intended and has a metallized surface of the resonator facing the antenna element. The antenna of claim 1, wherein the antenna element (405) is galvanically connected to the ground plane (403). An antenna according to any one of claims 1 or 2, wherein the antenna element (405) extends in a two-dimensional plane and that an axis (410) of the resonator (409) is substantially parallel to the antenna element (405). An antenna according to any one of claims 1 or 2, wherein the antenna element (405, 1401) is curved in a third dimension. An antenna according to any one of claims 1-4, wherein the resonator is a k-path resonator. An antenna according to any one of claims 1-4, wherein the resonator is a k-path resonator. An antenna according to any one of claims 1-6, wherein the resonator is of ceramic material. 10 15 20 25 528 069 18 An antenna according to any one of claims 1-7, wherein the antenna element (405) has at least one frequency arm for high frequencies and at least one frequency arm for low frequencies. An antenna according to any one of claims 1-8, further comprising a parasitic antenna element (1205) and wherein the antenna element (1203) is arranged to excite the parasitic antenna element (1205). 10. a second antenna element (1302) and that the antenna element (1301) is galvanically connected to the second antenna element (1302). An antenna according to any one of claims 1-8, further comprising An antenna according to any one of claims 1-10, wherein at least one antenna element and a ground plane are extended in a two-dimensional plane. An antenna according to any one of claims 1-10, wherein at least one antenna element is extended in a two-dimensional plane which is curved in a third dimension. An antenna according to any one of claims 1-12, wherein the antenna element is made of metamaterial. A mobile terminal unit comprising an antenna according to any one of claims 1-13. A mobile terminal unit according to claim 14, wherein at least one antenna element is integrated in a circuit board present in the terminal unit.