FI122484B - miniature Antenna - Google Patents

Description

Miniatyyriantenni

The invention relates to a very small antenna component, in particular for implementing a receiving antenna for small radio devices.

In portable radios, there has been an ongoing effort to reduce the size of the antenna to a pie-5. For this purpose, for example, a coil reducing the physical length of the whip of a monopoly tennis bowler has been used for a long time, or the entire whip has been replaced by a helical coil. Another way to reduce the length of the monopoly element measured directly from end to end is to arrange it in bends. the meander pattern. Such an antenna element is a conductor on a geometric plane, usually on the surface of a dielectric support layer of a strip conductor. In compact devices such as mobile phones, for convenience, the antenna is preferably placed inside the covers of the device. Internal antennas are usually planar in structure, and include a radiating plane and a parallel ground plane at a given distance. The planar antenna can be reduced in size by using relatively high dielectric material between the radiating plane and the ground plane instead of air. The disadvantage here is an increase in antenna losses and hence a decrease in efficiency, and it is not possible to achieve high reduction rates. A planar antenna can also be reduced by bringing these planes closer together, but the harmful effect is to degrade almost all electrical properties of the antenna. This is due in large part to the fact that the phase of the reflected wave from the conducting ground plane moves 180 degrees relative to the phase of the incoming wave, whereby the reflected wave weakens the outgoing wave from the radiating plane.

The antennas may employ the technique known as EBG (Electromagnetic Band Gap). In one embodiment of this, on the surface of a thin dielectric substrate, there is a regular formation of small conductor regions relative to the wavelength, each of which is connected through the substrate to a conductor plane on its lower surface. The structure can be dimensioned so that at a given frequency the level of the field applied to it does not change much in the reflection, in the case of so-called. AMC-Pinta (Artifical Mag- | netic Conductor). When using such an AMC board as the ground plane of the antenna, the radiator can be placed almost there without deteriorating the antenna characteristics, and the construction has the disadvantage of relatively high manufacturing costs.

The above-mentioned meander antenna element can, in principle, be made without changing the electrical length very small by densifying only the meander pattern. In practice, the minimum line width allowed in gravity circuit technology sets a limit to the meander-35 pattern reduction. In addition, the reproducibility of the element structure in production decreases as line width is reduced. Similar limitations apply to the use of IMD (In Mold Decoration) technology known in the art of dielectric surface metallization.

Figure 1 is an exemplary top view of a known antenna plate. "Antennile-5 band", as used herein, means a body formed by a conductive antenna element and its substrate. The antenna plate 100 includes a substrate 120 and an antenna element 110. The antenna element is formed by applying a metal layer to the surface of the substrate and removing most of it, leaving a narrow metal conductor. Such a small cross-section conductor can also be formed by increasing the metal layer by a sputtering technique. At the end of the antenna element, this metallization provides an extension 131 for connecting the antenna element coupling conductor 101 to the element. A similar extension may be for connecting the adapter conductor 102 to the element.

Figure 2 is an example of a sectional view of an antenna component 15 comprising the antenna plate of Figure 1. In addition to the antenna plate 100, the antenna component includes a plastic shield portion 240, within which the antenna plate is completely contained. The cover part also supports the antenna plate. The edges of the component have the required number of contacts, such as contact 242, to which the antenna element switching conductor 101 is connected inside the component.

Figure 3 is another example of a top view of a known antenna plate. The substrate 320 of the antenna plate 300 has a similar antenna element 310 as shown in Figure 1. Furthermore, the same substrate now has an antenna filter 360 and a low noise amplifier 370 (LNA) of the radio receiver. For example, filter 360 is of the FBAR (Film Bulk Acoustic Resonator) type. The filter and amplifier 25370, as well as the inductive and capacitive parts c3 required for amplifier fitting, are made on the substrate surface in the same process as the antenna element. Picture 3 £! in the example, the antenna element, filter and amplifier are first processed separately and then interconnected by wiring. The connecting yarn could also be replaced by wires processed on the substrate surface.

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The object of the invention is to reduce the antenna element beyond known solutions and thus to implement a very small antenna in a new way, g. The antenna component according to the invention is characterized in what is disclosed in it-0X1.

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The basic idea of the invention is as follows: The central part of the antenna component is an antenna plate consisting of a conductive antenna element and a substrate thereof. The antenna element is a meander pattern, very thin conductor. Gold wire or a metal strip grown on a substrate is used as a conductor to ensure conductivity. 5 The wire is fastened at its bending points to the so-called guide points on the substrate. bonding-joints. In addition to the antenna element, the substrate may have other components. The antenna plate is supported by dielectric material.

An advantage of the invention is that the wire pattern of the antenna element can be made very dense and thus the entire antenna in a very small space. This is due to the fact that the cross-sectional area of the conductor forming the element 10 is better than that of the corresponding known antennas. A further advantage of the invention is that the antennas according to the invention are manufactured by existing production processes originally designed for other purposes. A further advantage of the invention is that the reproducibility of the antenna elements is good due to the nature of the production process. A further advantage of the invention is that when using its antenna as a separate receiving antenna in a bidirectional radio device, a duplex filter or antenna switch is not required to separate transmission and reception.

The invention will now be described in detail. In the description, reference is made to the accompanying drawings, in which Fig. 1 shows an example of a known antenna plate viewed from above, Fig. 2 shows an example of an antenna component containing an antenna plate, g Fig. 3 shows another example of a known antenna plate,

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Fig. 4 shows an example of an aerial plate according to the invention, seen from above, | Fig. 5 shows an example of an antenna qq component containing the antenna plate according to Fig. 4, Fig. 6 shows another example of a top view of an antenna plate according to the invention.

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Referring to Figure 30, Figure 7 shows an example of the band characteristics of antennas using the element of the invention, and Figure 4 shows an example of the efficiency of antennas using the element of the invention.

Figure 4 is an example of an antenna element according to the invention with its substrates. The antenna plate 400 is shown in the figure at a magnification approximately 50 times from above, i.e., from the side of the an-5 transducer element 410. The antenna element consists of gold wire sections connected in series. For serial connection, each long side of the rectangular top surface of the substrate 420 has a row of conductive patches, such as a first spot 431 on the first end of the substrate on the first side, a second spot 432 on the opposite side of the substrate at the same end and a third spot 433. The first strand 411 of gold wire is connected by two bonding joints between the first and second spots, the second strand 412 by two bonding links between the second and third spots, the third strand 413 by two bonding joints between the third and fourth spots, etc. The last strand 4In is at the opposite end. In this way, the antenna-15 projection element 410, when viewed from above, forms a zigzag-shaped meander pattern. The element is connected to the radio device from the first spot 431 by a connecting wire 401, which is also in practice a gold wire. Functionally, the connecting wire is part of the antenna element. To accommodate the antenna, the element can be coupled to the signal ground at some other spot. In Figure 4, the dotted line 402 20 from the second spot 432 indicates such a possible matching thread.

The bonding joint is realized, for example, by welding. The substrate 420 is, for example, alumina or a collector such as LTCC (Low Temperature Co-fired Ceramic). Said conductive spots are formed during the manufacture of the substrate by pressing a metal paste on the surface of the substrate for these small areas and then sintering the paste. Alternatively, the conductive spots may be formed by etching the metal from the metallized surface of the substrate away from the rest of the region.

dj V For example, the spacing between adjacent spots on the substrate is 100 µm. This will allow the antenna element operating in the 900 MHz O 2 cv band to accommodate approximately 3 x 1.5 mm co. antenna elements operating in the northeast region and in the upper bands respectively for an additional 30 smaller regions. For example, the wire thickness in the antenna element is 17 µm.

o Wire strengths of this class mean that the antenna is only suitable for o very low power transmitter antennas. On the other hand, such a structure is well suited, for example, to mobile stations as a receiving antenna.

Figure 5 is a side view of the antenna component comprising the antenna plate of Figure 4, approximately 25 times magnified. The sloping wire portions 5 of the antenna element appear as small arcs above the substrate. In order to make the structure sufficiently robust, the antenna plate 400 is mounted on a small support plate 540, for example of circuit board material. For example, the fixing is done by gluing. The support plate has a lead-through 541 on whose upper surface the feed wire 401 of the antenna element is bonded.

5 At the lower end of the lead-through is a contact 542 through which the antenna component formed by the antenna plate and support plate is connected to other parts of the receiver. For example, the total height of the antenna component is 1.1 mm. It is installed on the circuit board of the device where the other RF components are.

Fig. 6 is a second example of a top view 10 of an antenna plate according to the invention. The antenna plate 600 has a dielectric substrate 620 and an antenna element 610 attached by bonding connections to the conductive dots on its upper surface, as in the plate shown in Fig. 4. The difference with Fig. 1 is that the gold wire constituting the antenna element is now initially uniform and secured in its bending positions by a single bonding. In addition, the portions of the elbows of the wire now run parallel to the long side of the rectangular-angled substrate, and the conductive spots are respectively located at each end of the upper surface of the substrate. The antenna element coupling wire 601 is connected to a first spot 631 near one corner of the substrate. In this example, a possible matching wire 602 is connected to the fourth spot 634 following the first spot element wire.

Figure 7 shows an example of the band characteristics of an antenna according to the invention. It has a graph of the reflection coefficient SI 1 as a function of frequency. The graph is measured from an antenna using an element similar to that shown in Figure 4 tuned to 2.3 GHz. If the cut-off frequency is used as a criterion of a reflection coefficient of -6 dB, the bandwidth becomes about 120 MHz, which is a relative value of just over 5%. 25 In the center of the band, the reflection coefficient is -25 dB indicating good fit. When using an element such as that shown in Fig. 1 ^, an equal relative bandwidth is achieved, but the fit is somewhat worse.

Figure 8 shows an example of the efficiency of an antenna according to the invention. This too the example relates to an antenna using an element similar to that shown in Fig. 4. In the center of the antenna's operating band, the efficiency is a little over 0.2 and drops from it to about 0.1 as it moves 100 MHz aside from the center of the band. The efficiency is understandably lower than that of larger, aerial insulated larger antennas, but still useful.

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The antenna elements and components of the invention have been described above. Naturally, the shape and implementation of the antenna element may differ from those shown. Thus, the term "meander" in the specification and claims generally refers to the shape of a line containing relatively dense bends. The bends may be curved or angular, and there may be irregularities in the bend pattern. The opposite ends of the antenna element may be connected to the receiver, which is a loop antenna. The loop is now just a circular or rectangular outline. There is a dense wire pattern around the outline. The inventive idea can be applied in various ways within the confines of the independent claim 1.

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Claims (5)

An antenna component having a meander pattern conductor as an antenna element and a dielectric substrate thereof, characterized in that, in order to maintain a constant cross-sectional area of the conductor and thereby reduce the size of the meander pattern, said 5 conductors (410; 610) at the bends secured to guide dots on the substrate (420; 620) by bonding joints. An antenna component according to claim 1, characterized in that at each of said bends the ends of two separate sections (412, 413) of gold wire are bonded to a guide plate (433), wherein the antenna element (410) consists of separate sections of gold wire. An antenna component according to claim 1, characterized in that at each of said bends a continuous gold wire (610) is bonded to a conductive patch (632; 634). Antenna component according to Claim 1, characterized in that said substrate (420; 620) is alumina or collected. An antenna component according to claim 1, characterized in that it further comprises a dielectric support plate (540) on which the antenna element (400) formed by the antenna element and the substrate is fixed and wherein the antenna element connection cable (401) is connected to the contact (542). 20 o δ CM CM o C \ l X cc CL 00 00 o o o CM