WO2000052784A1

WO2000052784A1 - Integrable multiband antenna

Info

Publication number: WO2000052784A1
Application number: PCT/DE2000/000599
Authority: WO
Inventors: Stefan Huber; Martin Weinberger
Original assignee: Siemens Aktiengesellschaft
Priority date: 1999-03-01
Filing date: 2000-03-01
Publication date: 2000-09-08
Also published as: AU3802000A; DE10080501D2

Abstract

The invention relates to an integrable multiband antenna. The aim of the invention is to guarantee a good integrability of such a multiband antenna. To this end, the antenna is produced in the form of a meander with two or more indentations, the length of the meander approximately corresponding to the size range of the received and transmitted frequencies.

Description

description

Integrable multiband antenna

The present invention relates to an integrable multiband antenna.

With regard to the development in mobile radio technology (network utilization, roammg m in Germany and abroad) or with radio-operated communication terminals, antennas are required that are able to cover several frequency bands at the same time. The market is also demanding ever smaller and cheaper devices. This is why antennas are required that have a small footprint, can be easily designed for a function in several frequency bands or one or more broadband frequency ranges, can be produced cheaply and reproducibly. A new trend is that the antenna should sit inside the device house and not as a stub or extendable antenna on the device as before.

These requirements are met by a multiband antenna, which is characterized in that the antenna has essentially the shape of a meander with at least three bays, the length of the meander being approximately equal to half the wavelength of a first higher frequency, that at one end a meandering point is provided for the meander and a mass point is provided in the area of the center of the meander, and the dimensions of the meander's bays on the food side are selected such that a wave of a second lower frequency couples over the first two bays so that forms a wave of a quarter of the wavelength of the lower frequency from the feed point across to this diagonally opposite corner of the meander and from there to the other end of the meander. For the higher frequency, the antenna structure (electrical length) represents a λ / 2 radiator. The ground contact (ground ^¬ point) should ideally be placed along the route A3 (Fig. 1). So roughly according to the electrical length λ / 4 for this higher frequency. At this point the

Ground contact, the operation of the antenna for this frequency is only insignificant. This resonance is almost unchanged with and without ground contact. A short distance to the earth negatively influences the behavior of the antenna for this frequency.

The ground contact is necessary for the lower frequency. The structure almost forms a patch antenna for this frequency. It therefore needs to be close to ground, which is more damaging to the higher frequency (this results in an optimal distance for the antenna, which results from a compromise for both frequencies). According to FIG. 1, the width of the line (B1), the coupling distances (A4 and A2) and the distance of the line above the mass m must be in a certain ratio to one another so that the shaft can travel from the distance C1 to C7 or C8 to couple. The wider the line and the greater the distance from ground, the greater the distances A2 and A4 can be. Seen from the feed point, the radiator structure (meander) behind the height of the ground point P2 also changes its behavior for this frequency (microstrip line characteristic) and no longer couples over between the meander elements. This frequency also sees the last branch of the meander as part of a patch antenna. There is no overcoupling between C8 and C2. For the lower frequency, the structure (electrical length) represents a λ / 4 radiator.

The integrable multiband antenna fulfills all of the above requirements.

Further essential developments of the antenna according to the invention result from the subclaims and the subsequent The description of exemplary embodiments of the antenna according to the invention

The invention will be described in more detail below with the aid of several exemplary embodiments.

Figures 1 to 17 show different configurations of an integrable multiband maander antenna according to the invention.

Fig. 1 shows the basic structure of such an integrable antenna. All the dimensions shown can vary in their values to adapt to the requirements or device properties. It is also not essential that Bl is constant over the entire length of the structure. The width of the meander can therefore vary within its structure. The length C1 or C3 need not be the same as the length C2 or C4. The same applies to C5 or Cβ and C7 or C8. The previous concepts (F, mverted F, patch, microstrip and double-sided PCB antennas) all have the disadvantage that they either take up too much space (no compact integrated multiband antenna is known to date), or they can be tuned a multiband function is not easily possible.

Fig. 2 shows options for tuning the antenna. The two basic resonances are determined by the dimensions of the meander. By suitable shaping of the radiator structure, more than two frequency ranges are also possible. The frequency ranges can now be tuned by selecting the long AI-A6. However, these options depend heavily on the space available for the antenna. By inserting the bridge or the bridge (D) with the distance H1 and by changing the location for the contact point P2, a lower or upper frequency can be shifted partially independently of one another. A similar shift in the resonance frequencies results with a change in the width H2 m Fig. 3.

4 shows a basic arrangement of the antenna according to the invention on the main assembly of a mobile radio device. The position of the antenna on or in the device is irrelevant, so it can be adapted to the device properties and type of application. However, the distance between the radiator element and the ground plane is important. The antenna has preference, two contact elements: a contact-RF contact and a ground ^¬. However, several ground contacts are also possible in order to set a desired antenna behavior. The HF contact is ideally located at the beginning of the meander, but it can also be positioned at another location. A ground contact is optimally contacted somewhere on the Lange A3, but can also be positioned at one or, in the case of several ground contacts, at several other arbitrary locations.

Further possible variations can be seen in the other figures.

The maander structure can e.g. can be composed of any curved elements. An exemplary embodiment of this is shown in FIG. 5.

In FIG. 6, several webs and bridges, also of different widths, are added at different distances Hi to match the different resonance frequencies and bandwidths. These bridges can also be inclined or curved as desired.

In Fig. 7, the feed point and the ground contact are designed such that the contact takes place over the entire width of an edge or surface (intermediate solutions also possible). The position for the supply and the ground connection can also be on other sides or edges of the radiator structure. tur lie. The antenna may use their own assigned Mas ^¬ seplatte own or plate the metallic parts and surfaces of the radio-operated Kommumkationsendgerates as mass. The additional ground surface can be shaped in any way and does not necessarily have to be adapted to the shape of the radiator element.

8 shows stepped and compressed variants of the meander antenna according to the invention. That is, the height of the antenna above the device PCB can vary within its length / width. It is assumed that the contour of the antenna antenna element usually adapts to the course of the housing in order to utilize the volume as well as possible. In order to improve the radiation properties and to increase the bandwidth, it can also be advantageous that the plane of the antenna is not parallel to the metallic surface, but is at a variable distance from the metallic EMC shielding of the radio-operated communication terminal.

Fig. 9 is to show that the webs or bridges can take almost any position and shape. They can also be implemented with the aid of discrete components or bond wires.

In Fig. 10, the webs are designed as line inductors.

Fig. 11 shows that the structure can also include holes that can be used, for example, for attachment.

12 shows the use of possible stepped and tapped ends to increase the bandwidths.

Fig. 13 shows that for the tuning of the different resonance frequencies and bandwidths also several bridges and bridges can be inserted between different sections of the meander.

Fig. 14 shows the possibility that the end branches (in the figure only one branch) can be shaped in such a way that they also have a different direction than that which would correspond to the shape of a meander.

15 shows that the meander antenna can have a higher or a lower number of turns, depending on the desired frequency behavior.

Fig. 16 is intended to show that the meander can stop at any point in its structure. It is not absolutely necessary to maintain an integer number of turns (oscillation trains).

17 shows a dimensioned functional model, which in this form represents a demonstration model (integrated solution) that has already been produced.

There are several ways to design the integrable multiband Maander antenna. The antenna can be manufactured using any manufacturing process.

Only three possibilities are mentioned here by way of example: You can structure the antenna structure on a PCB (Pnnted Circuit Board), you can manufacture the antenna from a metal sheet (with the contact elements) using a stamping and bending technique, and you can m Implement MID (Molded Interconnected Device) technology.

The material on which the structure is applied in the case of a PCB and the MID technique is freely selectable, but it should preferably be suitable for high frequencies. In a special case, it can also be flexible, flexible material (for adaptation to housing device contours). The height of the spotlights Structure above the antenna ground can be flexibly incorporated ^¬ be presents. So you can run in stairs form or in a ge ^¬ bent shape that conforms, for example, the housing.

All of these forms have the advantage that the parts of the radiator structure which are responsible for the radiation in a specific frequency range can be optimized with respect to the distance from the antenna ground. In addition, when using MID technology, the antenna can be designed as part of the housing.

In general, it can be said that the antenna is easy and inexpensive to manufacture, requires little space and can be easily configured for a function in one or more frequency bands (or in a broadband frequency range).

For mechanical reasons or to improve the radiation properties or optimal use of a available volume, it is also possible to introduce suitable dielectric or magnetic materials into the antenna structure. These can partially or completely fill the antenna structure. Combinations of different dielectric and / or magnetic substances or air are also possible. The advantage of the antenna is that a part of the radiator length, which determines the lowest frequency, can also be used for radiation at higher frequencies. As a result, the space requirement or the volume requirement can be kept small. Since an impedance of 50 ohms can be set for all frequency ranges at the single base point of the antenna, no further external wiring is necessary.

The antenna form presented is not necessarily tied to installation in a communication terminal; it can also be trained with a communica- tion transmitter must be connected (e.g. placed on the outside or fold-out) or mounted on an ordinary circuit board (e.g. in GSM desk phones, in radio or telecommunications modules) or operated as an independent external antenna, whereby in all cases a suitable antenna mass must be observed.

Claims

claims

1. Integrable multiband antenna, characterized in that the antenna essentially has the shape of a meander with three bays, the length of the meander being approximately equal to half the wavelength of a first higher frequency, that at one end of the meander a feeding point and in A mass point is provided in the area of the center of the meander, and the dimensions of the bays of the meander on the food side are selected such that a wave of a second lower frequency couples over the first two bays, so that the antenna essentially has the shape of a A meander with at least three bays, the length of the meander being approximately equal to half the wavelength of a first higher frequency, a feed point being provided at one end of the meander and a mass point in the region of the center of the meander, and the dimensions of the Bays of the meander on the

The feed side is chosen such that a wave of a second lower frequency crosses over the first two bays, so that a wave of a quarter of the wavelength of the lower frequency crosses from the feed point to this diagonally opposite corner of the meander and from there to the other end of the meander.

2. Integrable multiband antenna according to claim 1, characterized in that the meander structure is composed of any curved elements.

3. Integrable multiband antenna according to claim 1 or 2, characterized in that the width of the meander structure varies over the length.

4. Integrable multiband antenna according to one of claims 1

characterized in that the feed point and / or the ground point are designed as conductive edges.

5. Integrable multiband antenna according to one of claims 1

characterized in that the feed point and / or the ground point are formed as conductive edges.

6. Integrable multiband antenna according to one of the preceding claims, characterized in that the antenna structure is compressed and / or stepped out

7. Integrable multiband antenna according to one of the preceding claims, characterized in that webs or bridges are arranged within the bays of the meander.

8. Integrable multiband antenna according to one of the preceding claims, characterized in that the maander structure has at least two bays.

9. Integrable multiband antenna according to one of the preceding claims, characterized in that the end branch of the maander structure has a different direction than that which corresponded to the maander structure.