SE524871C2 - Antenna device for portable radio communication device - Google Patents

Abstract

The disclosure relates to an antenna device for a portable radiocommunications apparatus, for example a so-called cell or mobile telephone, which has at least one but preferably several operating frequencies within one frequency range. The frequency range has a width of several times the lower limit frequency of the frequency range, for example 800-2200 MHz. The antenna device has a radiating structure in the form of a continuous conductor. At least a first and a second section of the conductor are connectable to and disconnectable from each other. The interconnection takes place by the intermediary of connecting devices that are controlled by a control unit.

Description

l5 20 25 30 35 40 524 871 2 Possibly this technology could be scaled down to the sequence ranges used in mobile telephony. However, the length setting of the rod antenna poses major problems because such a setting would require some kind of servomotor, which due to the current consumption is not acceptable in a mobile phone with battery operation.

Mechanical, adjustable components are not relevant in this current technical area due to their size and a requirement for some kind of electrically driven control device. Varactors and FET switches cause problems in that they give rise to intermodulation and Switches, which are based on Pindiode technology, are unusable at least in battery-powered applications due to their power consumption.

Finally, there are previously known antenna devices, which are composed of a number of radiating components which can be connected or can be connected and disconnected in different combinations.

PROBLEM STATEMENT The present invention has for its object to design the initially specified antenna device so that it can operate at a number of different operating frequencies within a wide frequency band. The purpose of the invention is also to provide an antenna device that is simple and inexpensive to manufacture and safe to operate, and has an extremely low or preferably no own power consumption. Finally, the purpose of the invention is to provide an antenna device with compact outer dimensions.

TROUBLESHOOTING The objective underlying the invention is achieved if the antenna device initially indicated is characterized in that within at least one of the radiating conductors there are switching bridges provided with coupling means, by means of which different portions of one and the same conductor are interconnected and separable from each other.

COMPILATION OF DRAWING FIGURES The invention will now be described in more detail with reference to the accompanying drawing figures. These show: fi g 1 an embodiment of a radiating device according to the prior art; 10 15 20 25 30 35 40 524 871 3; g 2 a first embodiment of a radiating device according to the invention; Fig. 3 shows a second embodiment of a radiating device according to the invention; and 4 g 4 a third embodiment of a radiating device according to the invention.

PREFERRED EMBODIMENT There has been a group of components on the market for some time, which are manufactured with MEMS technology (Micro Electro Mechanical Systems) and which include switches, capacitances, both fixed and variable, as well as inductances, also here fixed and variable. The components are physically small, in the order of 0.5 to some or a few mm but in some cases still smaller, and can easily be integrated into larger units.

The mass of the moving parts is extremely small, which is why these components require extremely little energy for their maneuvering and can be made extremely fast. They do not give rise to intermodulation problems.

The operation of MEMS components can be electrostatic or electromagnetic. The electrostatic operation requires a relatively high voltage of IOV or more but in return consumes no current. The electromagnetic operation consumes a certain current but on the other hand does not need a high voltage.

The goal of the invention can be achieved through changes in the radiator or radiant structure that emits and receives RF energy.

Two fundamentally different variants are possible, namely firstly a radiating structure which has a number of radiating components which by means of coupling means, which are controlled by a control unit, can be connected and disconnected to or from a radiating component, which in turn is directly or indirectly connected to a supply line and secondly a radiating structure in the form of a continuous conductor where at least a first and a second portion of the conductor by means of coupling means, which are controlled by a control unit, are interconnectable and disconnectable with respective each other. 10 15 20 25 30 35 40 524 871 4 Combinations of these two fundamentally different variants are also possible, as are combinations with the switchable or variable matching networks described above.

The coupling means are preferably of the MEMS type and may be designed for galvanic coupling, capacitive coupling or inductive coupling. Variants where there is a varying degree of coupling can also be relevant in all embodiments.

Fig. 1 shows a known antenna device, which in electrical terms can be compared with a rod antenna of variable length.

It can be seen from the drawing that a coaxial cable 41 has a junction point 43 on an elongate radiating component 42 in front of an electrical conductor. The connection between the coaxial cable 41 and the conductor 42 is permanent.

The antenna device according to fi g l comprises further, radiating components in the form of conductors 44, 45 and 46. These conductors 44-46 are also elongate in shape and in a practical embodiment are arranged much closer to each other in the longitudinal direction of the antenna device than indicated in the drawing. .

Arranged between adjacent conductors are coupling means 47, 48 and 49 which are shown in the drawing as switches.

In ñg 1, all switches 47-49 are open, but if switch 47 is closed, this will result in the effective length of the antenna device being doubled compared to if switch 27 is open. As a result, the resonant frequency of the antenna device is halved.

By closing also the switch 48, a further extension of the antenna device is achieved, so that the resonant frequency decreases further. Correspondingly, the resonant frequency becomes even lower if the conductor 46 is also connected to the antenna device by closing the switch 49.

In the figure, the conductors 42 and 44-46 are shown with different lengths, which means that the frequency change steps become different in size when the switches are closed. Of course, the leaders can also have the same length and of course they can also be both more and fewer in number.

Figure 2 shows a fundamentally different embodiment of the antenna device according to the invention compared to Figure 1. In this embodiment there is a single continuous conductor 71 which has the shape of an approximately C-shaped frame with approximately rectangular angles. höm. The frame has an opening 72 which can be bridged or interconnected via a coupling member 73 shown as a switch. With the coupling means 73 closed, the conductor 71 will take the form of a closed, square ring, while with the coupling means 73 open it will have the previously described open, square C-shape.

The conductor 71 has a supply point 74 and a ground point 75 via which it is connected to a coaxial cable 76.

Fig. 3 shows another embodiment of the antenna device according to the invention. In this embodiment, a conductor 77 is used in the form of a meander, which at one end has a supply point 78 via which it is connected to a coaxial cable 79. A winding in the meander-shaped conductor 77 can be short-circuited by means of a coupling member 80 in the form of a switch.

The location shown for the coupling means is made for exemplary purposes only, so the placement may be between any two adjacent portions of the meander 77. Of course, your coupling means may also be used, which are intended for interconnection of other, adjacent portions of the meander.

Fig. 4 shows another embodiment of the antenna device according to the invention. In this embodiment, a conductor 81 is used in the form of a square, flat spiral, which at its outer end has a feed point 82, via which it is connected to the center conductor in a coaxial cable 83. Also in this embodiment, adjacent portions of the conductor 81 are similar. connectable to each other via coupling means 84 and 85, which are designed as switches.

The location of the coupling means 84 and 85 shown in the drawing is made for exemplary purposes only, for which reason completely different locations may be relevant as well as only one coupling member but also more than two.

For control of the antenna devices according to fi g 1-4, a control unit is used, which can be integrated in the radiating structure or be designed as a separate unit. The control unit receives control signals, which can be of two fundamentally different types, namely control signals which reflect the operating state in the transmitter / receiver circuit of the mobile telephone and control signals which reflect the influence of the environment on the mobile telephone. Examples of the first type of control signals are frequency (transmitted and received) and operating state (eg GSM, PCS, DCS, AMPS or UMTS). Examples of the second type of control signals include RSSI (receiver signal strength indicator), transmitter VSWR (voltage standing wave ratio), BER (bit error rate) and signal-to-noise ratio (C / N, Carrier / noice).

The software in the control unit controls so that one of the parameters or a combination of them is optimized. In this way, the combination of the coupling means is switched on which provides the resonant frequency which in turn provides optimal function with regard to operating conditions and current ambient conditions.

For different operating conditions as above, preset values are programmed.

If the telephone is used for GSM, the state S1-S10 is thus set in pre-programmed modes that provide optimal function over the GSM control area when the telephone is used in normal voice mode. If any of the control signals, eg RSSI, shows a low value, the control unit goes in and tests the combination state that gives the best resonant frequency for the current fi-sequence used.

Conventional radiant structures are made if possible for adaptation to 50 ohms. However, the actual impedance displayed by the phone may vary and deviate from 50 ohms but is usually transformed to this value. With the control unit according to the invention, the impedance can be adapted to the current impedance which the telephone circuits have before the impedance transformation to 50..

Claims (7)

10 15 20 25 30 35 524 871 7 PATENT REQUIREMENTS 1. l. Antenna device for a portable radio communication device, eg a so-called mobile phone, with at least one but preferably fl your operating frequencies within a frequency range with a width of fl times the lower range of the frequency range, eg 800-2200 MHz, comprising a radiating structure with a number separate radiating conductors (42, 44-46), wherein a first radiating conductor (42) has a connection (43) to a supply line (41) and that a number of additional radiating conductors (44-46) by means of coupling means (47-49) controlled by a control unit can be directly or indirectly connected and disconnected to the first radiating conductor, characterized in that within at least one of the radiating conductors there are switching bridges provided with coupling means (73, 84, 85, 88), by means of which different portions of one and the same conductor are interconnectable with and separable from each other. Antenna device according to claim 1, characterized in that the coupling means (73, 84, 85, 88) are arranged for galvanic coupling. Antenna device according to claim 1, characterized in that the coupling means (73, 84, 85, 88) are arranged for inductive coupling. Antenna device according to claim 1, characterized in that the coupling means (73, 84, 85, 88) are arranged for capacitive coupling. Antenna device according to any one of claims 1-4, characterized in that the coupling means (73, 84, 85, 88) are of the MEMS type. Antenna device according to one of Claims 1 to 5, characterized in that the control unit has at least input signals which reflect the operating state of the transmitter / receiver circuits of the mobile telephone. Antenna device according to one of Claims 1 to 6, characterized in that the control unit has at least input signals which reflect the influence of the environment on the mobile telephone.