SE512363C2 - Double band antenna - Google Patents

Abstract

A dual band antenna for a so-called mobile telephone comprises a supply conductor (5) which is connected to the circuits of the mobile telephone. The supply conductor (5) is galvanically connected to a first antenna section (8) which is approximately planar and has a number of loop-shaped conductor members (10). The conductor members (10) are galvanically connected in series and are disposed in sequence after one another in the longitudinal direction (14) of the antenna. The conductor member (10) which is located most distally from the supply conductor (5) is galvanically connected to a second antenna section (9). The second antenna section (9) is substantially straight and essentially parallel with the longitudinal direction (14) of the antenna.

Description

15 20 25 30 35 i: 512 see 2 which are galvanically connected to each other in series and which are arranged in succession in a longitudinal direction for the antenna and that the loop-shaped conductor portion located furthest from the supply conductor is galvanically connected to or merges into a second antenna section.

Additional advantages are obtained if the object of the invention is also given one or more of the features according to claims 2-12.

COMPILATION OF DRAWING FIGURES The invention will now be described in more detail with reference to the accompanying drawings. In these: Fig. 1 schematically shows an upper part of a mobile telephone and its antenna arrangement, fi g 2 a vertical plan view of an antenna included in the antenna arrangement according to fi g 1, fi g 3 the antenna according to Fig. 2 seen from the left in this fi gur, and fi g 4 an electrical diagram of the antenna according to fi g 2 and 3.

PREFERRED EMBODIMENT As initially stated, the invention aims to provide a double-band antenna which has minimal physical dimensions. It is particularly advantageous if the antenna can be given a flat design so that it can be placed at the back of the mobile telephone and thereby come as far away as possible from the user's head. Below, the term "flat" or "approximately planar" or equivalent terms will be used for the antenna and components included therein. These terms should not be taken literally, but should be considered to include constructions that have a length, a width and a thickness and where the thickness is significantly less than the length, often as much as a factor of 10 or more, while the width can amount to more than half the length .

In Fig. 1, the reference numeral 1 denotes a part of a cover of a portable radio communication apparatus, in everyday speech a mobile telephone, which comprises electrical circuits for transmitting and receiving radio waves within two different Ål 10 15 20 25 30 35 4; 512 363 3 frequency band. The dashed lines at the reference numeral 2 show the outer contour of an enclosure which at least partially encloses the antenna unit according to the invention. The antenna unit comprises a first antenna element 3, which is completely enclosed inside the outer contour 2 and which is intended to function in stand-by mode, paging mode. The antenna unit further comprises a second antenna element 4, which is intended to operate in the talc position and which is designed to be excited or fed by the first antenna element 3. In the embodiment shown, the second antenna element 4 is designed as a rod antenna, which is slidable in its longitudinal direction between an extended, active position and a position, mostly inserted in the housing, inactive. The rod antenna 4 is long and can be tuned to M2 or k.

Figures 2 and 3 together show the detailed construction of an embodiment of the first antenna element 3. The antenna element has a supply conductor 5, which is galvanically connected to the coaxial cable 6, which directly, without interconnection of an adaptation network, connects the antenna to the mobile telephone electrical circuits. The coaxial cable 6 earths the antenna in the cover 1 of the mobile telephone or an electrically conductive chassis lying therein, which is illustrated by the reference numeral 7.

The antenna comprises a first antenna section 8, which is intended to act in the higher of the two frequency bands in which the antenna is to operate, and a second antenna section 9, which together with the first antenna section 8 operates in the lower of the two frequency bands for which the antenna is designed.

The figures show that the two antenna sections 8 and 9 together form a substantially flat or flat unit, which in the thickness direction (perpendicular to the plane of the paper in fi g 2 and left-right in fi g 3) has a considerably smaller extent than in the longitudinal direction 14 of the antenna and also in its width direction. Preferably, the thickness is some ten power less than the length.

In the embodiment shown, the first antenna section 8 comprises three successively arranged, loop-shaped conductor portions 10, which as can be seen from fi g 2, can be substantially circular and which can be described as helical formations, which comprise one turn and which have only a very insignificant increase. Although the loop-shaped conductor portions 10 are shown as circular, it is not necessary to give them the perfect circle shape, but they may be elliptical, polygonal or anything in between these shapes. 10 15 20 25 30 35 4; In the embodiment shown, the loop-shaped conductor portions 10 have the same diameter and are arranged in line one after the other in the longitudinal direction of the antenna and have their center points located on a straight line which is substantially parallel to the longitudinal direction of the antenna.

Within each loop-shaped conductor portion 10 there is an overlapping area 11, where the conductor 12, which has been counted from the supply conductor 5, enters the loop-shaped conductor portion 10 and the conductor 13, which leaves it, overlaps or possibly intersects. These input and output conductors are galvanically separated from each other in that, as can be seen from Fig. 3, spaces 18 are arranged between the adjacent conductors.

In terms of manufacturing, the absence of galvanic contact between the joints within the overlapping areas 11 can be achieved by the antenna element 3 being made of a metal wire with an insulating layer. Alternatively, the antenna element 3 may be made with an inherent bias, which will cause nearby conductors within the overlap area 11 fi to spring away from each other. By casting in an insulating plastic material, the conductors are fixed in the correct position.

In the lower overlapping area 11 shown in Fig. 2, as shown above, the input conductor has been given the reference numeral 12 while the outgoing conductor has been given the reference numeral 13.

Counted in the longitudinal direction of the antenna, as illustrated by the arrow 14, the loop-shaped conductor portions 10 are spaced 15 apart. This distance may amount to half the diameter of a loop-shaped conductor portion but is preferably smaller and may possibly approach 0. However, it may not be negative, which would mean that two loop-shaped conductor portions 10 overlap each other in the longitudinal direction of the antenna 14. The distances 15 are equal along the whole the length of the antenna.

The loop-connected conductor portion 10, which is furthest from the supply conductor 5, has its output conductor 13 at some distance from the loop-shaped conductor portion bent across the longitudinal direction 14 of the antenna, so that a transverse conductor portion 16 is thereby formed. a bend so that the straight conductor portion 17 located after the bend has a longitudinal direction which is substantially parallel to the longitudinal direction 14 of the antenna. Furthermore, the orientation of the transverse conductor portion 16 and the conductor portion 17 is such that these <11 | 515 563 5 both conductor portions lie substantially in the same plane as the three loop-shaped conductor portions 10. The second antenna section 9 consists of at least the longitudinal, straight conductor portion 17, but may also be included therein. at least some parts of the transversal leadership 16.

Fig. 1 shows a first antenna element 3 with two loop-shaped conductor portions 10, while Figs. 2 and 3 show an embodiment with three loop-shaped conductor portions. According to the invention, it is possible in the antenna section 8 to also use four or possibly five loop-shaped conductor sections as long as the wire length used for the production of the loop-shaped conductor sections is approximately the same at the same frequency. This means that in the embodiment according to fi g 1, which has two loop-shaped conductor portions, these have a larger diameter than is the case in fi g 2, where three loop-shaped conductor portions occur.

The wire length is thus approximately the same if the tuning frequencies are the same. Correspondingly, an antenna section with four or five loop-shaped conductor portions would have a smaller diameter on these and at the same time have a larger length of the antenna section calculated in the longitudinal groove 14.

The number of loop-shaped conductor portions selected in the individual case (at approximately the same blank length of the wire used and at the same frequency) depends on the characteristics of the antenna. With a physically short antenna, the bandwidth of the antenna becomes relatively small, while it increases with the length of the antenna (with the number of loop-shaped conductor portions within approximately the same blank length). Furthermore, the efficiency increases with the length of the antenna, so that an antenna with three or four loop-shaped conductor portions can dispense with the second, rod-shaped antenna element 4.

As mentioned above, the first antenna element 3 is connected directly to the circuits of the mobile telephone without the use of an interconnected adaptation network.

This is possible in that the antenna element 3 itself forms a matching network with both capacitive and inductive components. In Fig. 4 this is illustrated by the fact that capacitances are formed in the overlapping areas ll between adjacent wire portions. These are shown in the arrows at the arrows C. Correspondingly, the loop-shaped conductor portions 10 form inductances, which are illustrated by the arrows L. , which are connected in parallel with each other. These groups, which represent a loop-shaped conductor portion 10 and which comprise a capacitance and an inductance, are connected in series one after the other and are in the end of the coaxial cable 6 and the supply conductor 5 connected to the other from the coaxial cable 6 and the supply conductor 5. antenna section 9.

As indicated above, the antenna element 3 can be cast into a body of an electrically insulating material, for example plastic material, so that the antenna element 3 thereby forms a discrete unit. In this way, the various conductor portions are also relativtxerated relative to each other, so that any change in the electrical properties of the antenna, for example due to a change in the distance 18 (fi g 3), does not have to be feared if the antenna is exposed to mechanical impact. Because the plastic material used has a dielectric constant which is greater than the dielectric constant for air, a reduction in the physical dimensions of the antenna element is also obtained.

In a practical embodiment of the antenna according to fi g 2 and 3, it is intended for the GSM and DCS bands. The antenna is molded in a plastic material with the dielectric constant in the range 2-2.5. The wire used for adjusting the antenna has a diameter of 1 mm. The inner diameter of the loop-shaped conductor portions is about 4 mm and the distance between them is about 0.5 mm and the distance between the transverse conductor 16 and the uppermost loop-shaped conductor portion is about 1 mm. The length of the supply conductor 5 is approx. 2 mm calculated up to the underside of the lower loop-shaped conductor portion. Furthermore, the distance between the longitudinal conductor portion 17 and the adjacent loop-shaped conductor portions is about 1 mm. Finally, the distance 18 is about 0.2 mm, while coated wires 12 and 13 can lie against each other.

ALTERNATIVE EMBODIMENTS Above, the antenna element 3 has been described as being made of a single piece of metal wire. However, the antenna element 3 can just as easily be manufactured by means of a double-sided circuit board, which thus has an electrically conductive coating on its opposite sides. This would in 2 g 2 mean that, for example, the supply conductor 5 and the upper half of the lower loop-shaped portion 10 are produced on the side of the circuit board facing the viewer, while the lower half of the lower loop-shaped conductor portion is produced on the back of the circuit board together with the upper half of the middle loop-shaped conductor portion and the conductor connecting the two lower conductor portions to each other. Wire connections straight through the circuit board connect on opposite sides of this located conductive portions. -x 4! Above, the loop-shaped conductor portions 10 have been described as being equally large. In, for example, such situations where the external shape of the antenna is limited or predetermined, deviations from this rule can be made. Thus, the diameter of the different loop-shaped conductor portions 10 can vary, for example decrease from the bottom of the antenna towards its top. Furthermore, the center points for them can be located along a crooked line. Finally, the input conductor 12 to the lower loop-shaped conductor 10 in Fig. 2 can extend a further approximately 1 A revolution in the counterclockwise direction so that the supply conductor 5 is located approximately in the middle below the antenna.

Regarding the longitudinal conductor 17, it is possible to let it form an angle with the longitudinal direction 14. Furthermore, it can be placed in front of (or behind) the loop-shaped conductor portions 10 in Fig. 2, as well as being placed to the left of these. In the latter case, one can expect greater bandwidth in the lower frequency band.

The invention can be further modified within the scope of the appended claims.

Claims (12)

10 15 20 25 30 35 4; 512 565 8 PATENT REQUIREMENTS A double-band antenna for a portable radio communication device, a so-called mobile telephone, comprising a supply conductor (5), which is connected to the circuits of the mobile telephone telephone, characterized in that the supply conductor (5) is galvanically connected to or merges into a first antenna section (8). , which is approximately flat and which comprises a number of loop-shaped guide portions (10), which are mutually galvanically connected in series and which are arranged in succession in a longitudinal direction (14) of the antenna and that the loop-shaped guide portion furthest from the supply conductor is galvanically connected to or merges into a second antenna section (9). Antenna according to claim 1, characterized in that the second antenna section (9) comprises a substantially straight section (17), which is substantially parallel to the longitudinal direction (14) and which extends in the direction of the supply conductor (5). . An antenna according to any one of claims 1 or 2, characterized in that the second antenna section (9) is located in approximately the same plane as the first antenna section (8). An antenna according to any one of claims 1-3, characterized in that the loop-shaped conductor portions (10) are arranged at some distance (15) from each other in the longitudinal direction (14). Antenna according to any one of claims 1-4, characterized in that the loop-shaped conductor portions (10) have approximately the same shape with their centers arranged along an approximately straight line, which is substantially parallel to the longitudinal direction (14 ). An antenna according to any one of claims 1-5, characterized in that the loop-shaped conductor portions (10) have overlapping areas (1 1), where the conductor (12) entering the loop-shaped portion overlaps, possibly crosses, the conductor emanating therefrom (13), and that the input and output conductors are galvanically separated within the area of overlap. Antenna according to any one of claims 1-6, characterized in that the first antenna section (8) and the second antenna section (9) are made in one piece of a wire of metal or metal alloy. 'lll 10 15 20 4; 512 565 Antenna according to any one of claims 1-6, characterized in that the first antenna section (8) and the second antenna section (9) are arranged on a double-sided circuit board, the first antenna section (8) having conductor portions on both sides of the circuit board. An antenna according to any one of claims 1-8, characterized in that the first antenna section (8) is tuned to the higher of the two frequency bands for which the antenna is intended to operate. An antenna according to any one of claims 1-9, characterized in that the second antenna section (9) is tuned to cause the antenna as a whole to operate at the lower of the two frequency bands for which the antenna is intended to operate. . Antenna according to one of Claims 1 to 10, characterized in that the supply conductor (5) is connected without an adaptation network directly to the circuits of the mobile telephone. Antenna according to any one of claims 1-11, characterized in that it is arranged in the physical vicinity of a rod antenna (4) for inductive / capacitive feeding thereof.