The present invention relates to a broadband antenna means according to the preamble of Claim 1.

Portable equipment, and then particularly hand-carried telephones, are often provided with helical antennas. Such antennas are convenient because they can be made more robust and take up less space than straight wire antennas for instance. However, they do not always give a satisfactory antenna performance.

One problem is that a helical antenna is short and can therefore easily be screened or obstructed by a user or by objects in its vicinity. The helical antenna is therefore often combined with an extendable straight wire antenna, which is not screened as easily and which also gives better antenna performance. For instance, the Patent Specifications US-A 4,121,218, US-A 5,204,687 and US-A 4,868,576 describe differ- ent antenna means for portable equipment in which a helical antenna has been combined with an extendable straight wire antenna.

Another problem encountered with the use of helical antennas resides in their limited bandwidth. This renders conventional helical antennas unusable in those cases when an antenna function having a very broad band is required, for instance in the JDC mobile telephone system. In cases such as these, it would be desirable to provide an antenna means which has the positive properties of helical antennas coupled with a bandwidth which is much greater than the bandwidth of a conventional helical antenna.

It is, of course, conceivable to provide portable equipment with two separate helical antennas which have mutually different resonance frequencies. Such an antenna arrangement would be unnecessarily space consuming, however.

The problems concerning bandwidth and space requirements are solved by a broadband antenna means according to the preamble of Claim 1 that has the characteristic features of the invention set forth in the characterizing clause of Claim 1. There is thus obtained a helical structure that is resonant at two frequencies which result from the different lengths of respective coils and whose difference is due to the difference in the lengths of the coils.

The problems relating to screening of the short helical antennas is solved by combining the helical antennas with a straight wire antenna.

Further advantageous embodiments of the invention are defined in the depending Claims. For instance, a helical structure which is resonant at more than two frequencies can also be obtained in a similar manner, by combining three or more coils.

It may also be problematic and require very high precision in manufacture to achieve a well-defined mutual capacitance/in¬ ductance between the coils when they are mounted close to one another. This can be alleviated by twisting the coils together prior to being wound to their final helical shape, for instance.

Two preferred embodiments of the invention will now be described in more detail with reference to the accompanying drawings, in which

Fig. 1 is a view of a first embodiment of the invention which includes, among other things, a first helical antenna incorpo¬ rated in a sleeve provided with an attachment means, a second helical antenna, an antenna rod or pin which encloses a straight wire antenna and the second helical antenna;

^• Fig. 2a illustrates a second embodiment of the invention which

includes, among other things, a first helical antenna and a second helical antenna embodied in a sleeve provided with an attachment means, and an antenna rod or pin which embraces a straight wire antenna;

Fig. 2b shows elements of the second embodiment illustrated in Fig. 2a;

Fig. 3 is a circuit diagram which illustrates an electric function of the helical antennas of the first embodiment illustrated in Fig. 1;

Fig. 4 is a circuit diagram which illustrates an electric function of the helical antennas of the second embodiment shown in Figs. 2a and 2b; and

Fig. 5 shows three curves in a bandwidth diagram of a conven¬ tional helical antenna of a helical structure according to the invention, and of a straight wire antenna.

The antenna means illustrated in Fig. 1 is comprised of three main components. Firstly, a first helical antenna which comprises a first coil 107 is embodied coaxially in a hollow, generally cylindrical insulating sleeve 106 made of plastic material or some equivalent material. One end of the coil 107 is connected to a conductive sleeve 108, which is fastened in one end of the insulating sleeve 106. The conductive sleeve 108 is effective in connecting the coil 107 electrically to portable equipment, for instance a hand-carried telephone (not shown) , and forms the means for attaching the antenna means externally to the portable equipment.

Secondly, a second helical antenna which is comprised of a second coil 103 whose length is different to, and preferably shorter than the length of the first coil 107, and thirdly a straight wire antenna 105. The second coil 103 is arranged coaxially in an insulated upper part 104 of an antenna rod or

pin 102 which is provided with a knob 101 on top of the pin. The lower part of the antenna pin includes the straight wire antenna 105, and the whole of the antenna pin 102 can be inserted and extended axially through the insulating sleeve 106, the first coil 107 and the conductive sleeve 108.

Attached to the other end of the insulating sleeve 106 is an insulating tube 109 which when fitted in place is located within the portable equipment and in which the antenna pin 102 is located in when in its inserted or retracted position. Axial movement of the antenna pin is preferably limited by the knob 101 and also by a shoulder or abutment (not shown) on the lower end of the antenna pin 102.

When the antenna pin 102 is telescoped to its inwardly inserted position, the straight wire antenna will lie general¬ ly beneath the conductive sleeve 108 and is essentially inactive. The two coils 107, 103 are located coaxially with one another in generally the same axial position. The coils are therewith mutually coupled capacitively/inductively, as shown in the circuit diagram of Fig. 3. The result is an antenna function which has a much broader band than the antenna function of each coil 107, 103 when taken individual¬ ly.

In the outwardly extended position of the antenna pin 102, the straight wire antenna 105 will be positioned substantially above the conductive sleeve 108, wherein the straight wire antenna 105 is connected to the portable equipment either directly or via the first coil 107 and forms the main antenna function.

The helical antennas and the straight wire antenna 105 can be connected electrically to circuits in the portable equipment galvanically and/or capacitively/inductively in a combined form, wherein switching between different combinations is effected by extending or inserting the antenna pin 102. Switch

means intended for this purpose may conceivably be provided in the proximity of the conductive sleeve 108, wherein the switch means preferably coactable with parts of the antennas 103, 105 that are located within the antenna pin 102.

The antenna means illustrated in Fig. 2a is comprised of two main components. Firstly, a first helical antenna and a second helical antenna which are comprised respectively of a first coil 207 and a second coil 203 which are embodied coaxially in a hollow, generally cylindrical insulating sleeve 206 made of plastic material or some equivalent material. One end of respective coils 207, 203 is connected to a conductive sleeve 208 which is attached to one end of the insulating sleeve 206. The conductive sleeve 208 is operative in connecting the coils 207, 203 electrically to portable equipment, for instance a hand-carried telephone (not shown), and forms the means for attachment of the antenna means externally to the portable equipment. The first coil 207 and the second coil 203 are combined to form commonly a unitary helical form, which will be described in more detail below with reference to Fig. 2b.

Secondly, a straight wire antenna 205 is arranged in a lower part of an antenna pin or rod 202. The antenna pin 202 has an insulated upper part 204 and carries a knob 201 at the top thereof. The whole of the antenna pin 202 can be inserted and extended, i.e. telescoped, axially through the insulating sleeve 206, the first coil 207, the second coil 203 and the conductive casing 208.

Attached to the other end of the insulating sleeve 206 is an insulating tube 209 which when fitted in place is located within the portable equipment and in which the antenna pin 202 is located when in its inserted position. Axial movement of the antenna pin is preferably limited by the knob 201 and also by a shoulder or abutment (not shown) at the bottom end of the antenna pin 202.

When the antenna pin 202 is inserted, or retracted, the straight wire antenna will be located generally beneath the conductive sleeve 208 and is essentially inactive. The two coils 207, 203, in whose centres the upper insulating part 204 is located, are herewith active and connected to the portable equipment in accordance with the circuit diagram shown in Fig. 4. The result is an antenna function which has a much broader bandwidth than the antenna function of each coil 207, 203 per se.

When the antenna pin 202 is in its outwardly extended posi¬ tion, the straight wire antenna 205 will be located generally above the conductive sleeve 208 and is connected to the portable equipment, either directly or via the coils 207, 203, and forms the main antenna function.

The helical antennas and the straight wire antenna 205 can be connected to circuits in the portable equipment galvanically and/or capacitively/inductively in a combined form, wherein switching between different combinations is effected by extending and inserting the antenna pin 202 telescopically. In this regard, a switch means may conceivably be provided in the proximity of the conductive sleeve 208, this switch means being capable of coacting with preferably the straight wire antenna 205 located in the antenna pin 202.

Fig. 2b shows in detail the insulating sleeve 206, the conductive sleeve 208 and the coils 207, 203 of the two helical antennas. The Figure illustrates a suitable manner of arranging the first coil 207 and the second coil 203 in a common helical form whose diameter is slightly smaller than the diameter of the insulating sleeve 206. In this case, the two coils 207, 203 consist of two insulated wires of mutually different lengths, for instance of the kind normally used in transformers.

The wire forming the first coil 207 and the wire forming the

second coil 203 are first twisted together along the full length of the shorter wire. The wires are then wound to the common helical form. Twisting of the wires together results in a well-defined capacitive/inductive connection between the wires. This obviates the need of producing the winding with the same degree of precision as that required when the wires are wound parallel to one another in the common helical form. This greatly facilitates manufacture.

The circuit illustrated diagrammatically in Fig. 3 is an electrical model of the antenna function of the first embodi¬ ment when the antenna pin is in its inserted or retracted position, wherein the first and the second coil are described respectively by a first group 307 and a second group 303, each having three series-connected inductances. The capacitance between the first and the second coil is shown with two capacitances 310 connected in parallel at the interconnection points of respective inductances. One end of the first group 307 is parallel connected directly to the circuit 312 in the portable equipment while one end of the second group 303 is parallel connected to the circuit 312 via a capacitance 311.

The circuit illustrated diagrammatically in Fig. 4 is an electrical model of the antenna function of the second embodi- ment when the antenna pin is in its inserted or retracted position, or alternatively without the antenna pin, wherein the first and the second coil are described respectively by a first group 407 and a second group 403, each having three series-connected inductances. The capacitance between the first and the second coil is shown by two capacitances 410 connected in parallel at the interconnection points of respective inductances. One end of each group 407, 403 is directly parallel-connected to the circuits 412 of the portable equipment.

The diagram shown in Fig. 5 illustrates the principle configu¬ ration of the standing wave ratio as a function of the

frequency of different antenna means. A curve 517 which describes a conventional helical antenna has a narrow local minimum, which corresponds to a small bandwidth. A curve 519 which describes a straight wire antenna has a broad local minimum, which corresponds to a large bandwidth. A curve 518 which describes a helical structure according to the invention has two separate local minima located adjacent one another, which corresponds to a large total bandwidth. The marked frequency regions 515, 516 denote transmission and reception bands for a broadband telephone system, for instance JDC. Both of these frequency ranges 515, 516 are included by the bandwidth of the inventive helical structure.