DE20116529U1 - Antenna and computer equipment with antenna - Google Patents

Description

Antenna and computer equipment with antenna

The present invention relates to an antenna and in particular a printed circuit board antenna for the DECT standard and a computer device, in particular a web pad, containing such an antenna.

Modern computer systems, especially laptops, are increasingly being equipped with radio modules that allow wireless data communication. DECT or Blue Tooth are often used as the radio communication standard. The corresponding radio modules are often designed as so-called PCMCIA cards, which are inserted into a slot provided for this purpose. The PCMCIA card has an antenna that usually protrudes from the laptop's casing and can therefore radiate freely.

In order to comply with the relevant legal regulations regarding interference emissions, computer devices with high-speed processors usually have shields that prevent the interference radiation from escaping. The shielding can be achieved by means of a metallic layer on the inside of the computer casing.

As with mobile phones, it would be desirable for modern portable computer devices to be able to place the antenna required for radio communication inside the housing and thus not have it protrude to the outside. With mobile phones , it is often possible to place the antenna inside the housing without any problems, as the corresponding mobile phone housings are generally not shielded themselves and thus the waves emitted by the antenna can easily penetrate to the outside. This is different with computer devices, as shown above, due to the interference emissions that occur. If an antenna were to be placed inside a computer device, its radiation behavior would be significantly impaired by the shielding.

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It is particularly desirable to place antennas inside the casing of web pads, which are becoming increasingly popular today. These devices are wireless terminals for accessing the Internet, but these devices generally do not have a mouse input device or keyboard. All inputs are made via a touch-sensitive screen, with the screen telling the user which function they can perform by touching which part of the screen. This type of computer also has high-speed processors and must therefore be shielded in order to comply with legal requirements.

It is the object of the present invention to provide a solution which makes it possible to arrange corresponding antennas inside the computer housing of computer devices despite shielding.

This object is achieved by a circuit board antenna according to claim 1 and by a computer device according to claim 13.

Preferred embodiments are the subject of the subclaims.

The special antenna arrangement according to claim 1 has a surprisingly good radiation behavior and is particularly suitable for installation in computer housings.

The computer device according to claim 13 contains such an antenna and is shielded over the entire housing except for the area in which the antenna device is arranged.

It is pointed out that as a further independent aspect of the present invention, a computer device is proposed whose housing is completely shielded and which has any antenna inside it. At the point where the antenna device is provided, the corresponding shield is cut out, wherein this corresponding section is preferably at a

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a location where no major interference emissions occur anyway due to the lack of radiating components in the corresponding area. In particular, the unshielded area can only be a few square centimeters in size and is preferably provided at the edge of the computer device or a web pad. The antenna then provided inside the computer device corresponds in its dimensions to the unshielded area.

In the following, preferred embodiments of the present invention are explained in more detail with reference to the accompanying drawings. The drawings show in detail:

Fig. 1 is a schematic representation of an embodiment of the antenna structure according to the invention;

Fig. 2 is a schematic representation of a web pad with an antenna arranged inside; and

Fig.3 is a detailed view of the part of the web pad according to Fig. 2 in which the antenna structure is arranged.

Fig. 1 shows a schematic view of a preferred embodiment of the antenna structure according to the invention.

The antenna 1 is constructed as a circuit board antenna. In particular, it is made of glass fiber reinforced epoxy resin on a piece of copper-clad circuit board material, whereby the antenna is produced as a conductor structure using photolithography. As an alternative to epoxy resin, Teflon can also be used, which has better properties from an RF technical point of view.

The circuit board 2 has a circular shape, along the edge of which two circular ring sections 3, 4 made of conductive material are applied. The two circular

ring sections 3, 4 are fed by a coaxial cable 5. At the base of the antenna there is a comb-like capacitance structure.

The diameter of the circular disk 2 is preferably between 25 and 35 mm and preferably 28 mm. The thickness of the circuit board is preferably 1 mm. The width b of the circular ring sections is between 2 and 5 mm and preferably 3 mm. The two circular ring sections 3, 4 are closely adjacent at their lower ends, i.e. the ends that are fed by the coaxial cable 5. In contrast, the free ends are clearly spaced apart from one another. This distance is preferably between 10 and 30 mm and particularly preferably 18 mm.

The segment of the disk 2 not occupied by an antenna conductor is between 45 and 90°, in particular between 70 and 80° and preferably about 75°, as shown in the figure.

Electrically, the antenna is a dipole. The circular shape of the radiator halves greatly reduces the space required. Instead of a length of, for example, 8 cm, which a dipole would need for frequencies in the range of 1890 MHz (DECT standard), the result is a disk with a diameter of around 30 mm (preferably 28 mm).

A stretched dipole with very thin conductors has a length I of

I = λ/2 λ =3x10 ⁸ /ff in MHz, I in m.
For a frequency of 1890 MHz, &lgr; is therefore 39.7 mm.
The finite conductor shortening b results in a shortening factor

V=(l/b)/(lb+l) of approx. 4%.
Further reductions result from

the capacitive coating of the dielectric material (ε _{Γ approx.} 4.5),
the mutual influence of the two dipole ends through ring shape,
capacitive loads caused by metallic and dielectric parts in the environment
environment.

An analysis using the EZNEC program resulted in a total reduction factor of 15%. It must be noted that the antenna's efficiency decreases the closer the two dipole branches come to each other. A compromise must be made between size and radiation properties. A corresponding simulation resulted in a degradation of just under 2% for a selected distance of 18 mm. This is a negligible value in practice.

In actual fact, the dipole has a shortening factor of 20% compared to the theoretical value when installed. The difference of 5% compared to the simulation is explained by additional capacitive loads from the antenna's surroundings, such as metal parts of a loudspeaker or plastic parts of a housing. These components cannot be determined precisely either analytically or by simulation. Accordingly, one has to rely on empirical investigations.

A disadvantage of any capacitive load on the antenna radiator is the shift of the base resistance to low values. Since the connected coaxial cable has 50Ω, the impedance would have to be adjusted using a transformation element. In order to avoid additional components, it is suggested that the length of the antenna be chosen to be somewhat longer than would actually be necessary for the resonance frequency. This increases the base resistance and an inductive reactive component occurs. This is compensated by a capacitance directly at the feed point of the antenna so that the input impedance is again purely real. Although this reduces the usable bandwidth of the antenna by around 5% to around 3%, this is not a problem with a relative bandwidth in the DECT band of 1%.

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The round shape of the antenna has the additional advantage that the polarization of the emitted wave is no longer purely linear, but the energy is distributed across horizontal and vertical components. This results in fewer cancellation effects, especially when illuminating buildings.

Fig. 2 shows an example of a computer device, namely a so-called web pad. This web pad 5 has a housing 6 and a display surface 7. The web pad also has a cylindrical battery receiving area 8 in which additional loudspeakers 9, 10 are integrated. According to the teaching of the present invention, the web pad 5 shown has an antenna (not visible) inside, which is arranged completely inside the housing 6 and thus does not protrude from the housing, as is the case with conventional solutions.

Fig. 3 shows the upper left corner of the web pad shown in Fig. 2 in the opened state in detail.

As can be seen, an antenna structure 11 similar to the structure of Fig.1 is inserted into the cylindrical receiving area of the web pad in such a way that the axis of the antenna disk runs parallel to the cylinder axis and preferably coincides with it.

Preferably, the antenna is thus arranged in an area that is close to or in the loudspeaker resonance volume of the web pad or the computer device.

This has the advantage that the antenna is essentially located in a volume of air, which only moderately affects the antenna's impedance. Since there are no electronic components near the antenna, the radiated RF energy hardly has any disruptive influence on the device's electronics. Although some RF voltage is radiated into the loudspeaker cable, this can be relatively easily diverted to the circuit.

couple. There are also no components around the antenna that emit radiation themselves. For this reason, the so-called coating, i.e. a shielding layer, is not required in this area of the housing. Such a shielding layer is otherwise distributed over the entire housing of the computer device or web device in order to comply with the legal regulations on interference emissions. This shielding is preferably implemented by a metal layer applied inside the housing. This coating is only not applied in the part of the housing in which the antenna is located, although this is easily possible with the special arrangement of the antenna within the housing described above, since little radiation occurs at this particular point anyway.

By arranging the antenna as shown in Fig. 2 and 3 in the corner of the web pad facing away from the user, a free radiation angle of approximately 270° is created, which ensures optimum range.

In order to achieve an exactly reproducible position of the antenna within the computer device during series production, which is particularly important in order to maintain the resonance frequency and corresponding adjustments, devices are provided to prevent the antenna disk from rotating relative to its reference position.

For this purpose, it is proposed to provide the antenna disk with notches or payment elements that have corresponding counterparts in the computer housing, whereby the position of the antenna in relation to the computer housing can be clearly determined. In addition, it can be provided to apply the antenna disk to a disk made of porous foam that has a slightly larger diameter in order to avoid the antenna disk itself resting on the housing plastic. The disk made of porous foam has a low relative dielectric constant s _r , whereby the relatively poor HF properties can have less of a negative effect. The area of the web pad shown in Fig. 3 is, as mentioned, covered by both the bottom and the top.

on the upper shell of the coating is kept free to allow the antenna to radiate freely to the outside.

According to a further aspect of the invention, the antenna structure can be designed as a closed conductor loop. A capacitor arranged at the base of the antenna is then required for adaptation.

Claims (18)

1. Printed circuit board antenna with a circular dipole conductor geometry, which is formed by two mutually symmetrical circular ring sections applied to the circuit board, wherein the circular ring sections are closely adjacent at their base points and are fed there via a cable, preferably a coaxial cable, and wherein the free ends are preferably spaced apart from one another according to a circular angle of 45 to 90° and particularly preferably approximately 75°. 2. Printed circuit board antenna according to claim 1, characterized in that the printed circuit board is designed as a circular disk and the antenna structure is formed along the edge of the circular disk. 3. Printed circuit board antenna according to claim 1 or 2, characterized in that the antenna structure is formed on the printed circuit board by means of photolithographic processes. 4. Printed circuit board antenna according to one of the preceding claims, characterized in that the diameter of the circle described by the circular ring sections is between 25 to 35 mm and is preferably 28 mm. 5. Printed circuit board antenna according to one of the preceding claims, characterized in that the distance between the free ends of the circular ring sections is between 10 and 25 mm, preferably 18 mm. 6. Printed circuit board antenna according to one of the preceding claims, characterized in that the printed circuit board consists of glass fiber reinforced epoxy resin or of Teflon. 7. Printed circuit board antenna according to claim 5, characterized in that the printed circuit board material has a relative dielectric constant of ε _r = 4.5. 8. Printed circuit board antenna according to one of the preceding claims, characterized in that the width of the circular rings is between 2 and 5 mm and preferably amounts to 3 mm. 9. Printed circuit board antenna according to one of the preceding claims, characterized in that the antenna is designed for a frequency range around 1890 MHz according to the DECT standard. 10. Printed circuit board antenna according to one of the preceding claims, characterized in that a capacitor is provided at the base of the antenna structure to adapt the base impedance to the resonance frequency. 11. Printed circuit board antenna according to claim 9, characterized in that the capacitor is designed as an SMD component or as a conductor structure. 12. Printed circuit board antenna according to one of the preceding claims, characterized in that in order to avoid an additional component for achieving an adaptation transformation, the length of the antenna is chosen to be greater than is necessary for the resonance in order to thereby increase the base point resistance and the resulting inductive reactance is compensated by a capacitance directly at the feed point of the antenna so that the input impedance is again purely real. 13. Computer device, preferably a web pad, with a built-in radio module for achieving wireless data communication, preferably in accordance with the DECT standard, the computer device having a shield for interference emissions in order to comply with legal regulations, characterized in that the computer device has a circuit board antenna according to one of claims 1 to 12, which is arranged completely within the computer housing and that a layer is provided for shielding, which extends over the entire computer housing with the exception of the area where the circuit board antenna is arranged. 14. A computer device according to claim 13, characterized in that the circuit board antenna is arranged on the outer edge of the side of the computer device which is opposite the position of the user during normal use of the computer device. 15. Computer device according to one of claims 13 or 14, characterized in that the circuit board antenna is arranged near or in the resonance volume of a loudspeaker provided in the computer device. 16. Computer device according to one of claims 13 to 15, characterized in that the computer device is a web pad which has a cylindrical receiving area for batteries on its upper edge facing away from the user and the circuit board antenna is designed as a disk which is arranged such that the axis of the circular disk coincides with the cylinder axis. 17. Computer device according to one of claims 13 to 16, characterized in that the circular printed circuit board is applied to a disk made of porous foam and the axis of the foam disk coincides with the cylinder axis of the battery housing. 18. Computer device according to one of claims 16 or 17, characterized in that the circuit board disk or the disk made of porous foam has notches or teeth which engage in corresponding counterparts of the computer housing in order to thereby determine an exact orientation of the antenna structure within the computer housing.