DE10055266A1 - Method of manufacturing a radio unit and radio unit - Google Patents

Abstract

The invention relates to a method for producing a radio unit (10), particularly a mobile telephone, wherein an (2), particularly a planar antenna is electrically and mechanically firmly connected to a transmitter and/or a receiver part (1), preferably to the conductor plate thereof (6), the impedance of the antenna (2) is temporarily compensated in a frequency range relevant for the transmission and/or the reception of radio signals and finally the transmitter and/or receiving part (1) is tested, particularly for determining the limits of the sensitivity thereof. As said antenna (2) can be soldered together with other components in one working step, a higher level of rationalisation is achieved when producing radio units (10), resulting in lower production costs.

Description

The object of the invention relates to a method for producing egg ner radio unit as well as on a radio unit.

The need for means for fast, individual and mobile communication has increased dramatically in recent decades. There are radio units Become part of everyday life and it falls to the process Manufacture of radio units not least because of the high number of units per year radio units are of great importance. Optimal transfer properties at the lowest possible cost must be in their manufacture be taken into account.

Radio units, such as cell phones, increasingly have antennas that are integrated in a plastic housing in a very small space. A typical installation The place for such integrated antennas is the back of the device board. Advantageous are mostly planar antennas because they require little space. A Antenna has at least one supply connection, which is connected to the transmitter and / or Receiver part is electrically connected. By the position of the feeding point on the input impedance can be set for the antenna. The antenna must a so-called λ / 2 radiator be designed such that the resonant length in corresponds approximately to half the wavelength at the desired operating frequency. Advantageous due to its smaller space requirement, the so-called λ / 4- The antenna additionally emits the electrical mass of the transmitter and / or Receiver part connected. It is very important for the function of planar antennas It is important that the antenna has a defined position relative to the device board after installation  occupies. So far, a defined location has been achieved either by additional Support elements made of plastic or the antenna as such was made made of a metallized plastic or ceramic block, which on the Device board was applied.

When manufacturing radio units, it is usually necessary to use radio frequency circuit of the transmitter and / or receiver part to test. For example measured the input sensitivity of the circuit, which happens by that a signal at the input of the RF circuit is fed and the level so is reduced until the bit error rate at the output of the RF circuit unites reached a certain limit.

The problem arises when carrying out a test measurement reliably, that on the one hand the antenna has a defined position relative to the transmitter and / or Receiver part must take, but on the other hand, the antenna is not yet with sem may be electrically connected, because otherwise via the frequency-dependent Impe the antenna and by coupling in interference from the outside properties of the RF circuit can be falsified. Automatic manufacturing, in which the HF circuit is equipped with an antenna before the test measurement, is not yet possible. For this reason, the antenna is used in manufacturing usually mounted after the complete measurement of the HF circuit. A sepa rater operation in the manufacturing is required, in which the antenna (often from Hand) is soldered or inserted.

A possible solution to this problem is described in the U.S. 5,832,372, in which a switch is inserted between the antenna and the RF circuit. The disadvantage of this solution is that an additional component is required for this.

Proceeding from this, the present invention is based on the objective of to specify a method by which a radio unit with an antenna and a Sender and / receiver part can be produced without additional funds  to interrupt the electrical connection between antenna and transmitter and / receiver part or supporting elements of the antenna are necessary. Another one The aim of the invention is to provide a radio unit that is compatible with the above Process is made.

According to the invention, this objective is achieved by a method with the features according to claim 1 or by a radio unit with the features achieved according to claim 8. Advantageous further developments and refinements, which can be used individually or in combination with one another are Ge subject of the respective dependent claims.

In the method according to the invention for producing a radio unit, in particular of a cell phone, first an antenna, especially a planar type tenne, with a transmitter and / or receiver part, preferably with its Lei terplatine, electrically and mechanically firmly connected and the impedance of the An tenne in a relevant for the transmission and / or reception of radio signals Frequency range temporarily compensated. Then the transmitter and / or receiver part tested, in particular its limit sensitivity is determined. The advantage of this method is that the antenna both mechanically fixed as well as electrically with the transmitter and / or receiver part is bound, so that the step of retrofitting the antenna and / or the use of an additional component such as a switch becomes superfluous. The retroactive influence of the antenna on the RF circuit is avoided by compensating for the impedance of the antenna and it can the test measurement of the HF circuit after assembling the antenna and transmitter and / or receiver part.

It is advantageous to have the antenna with the printed circuit board of the transmitter and / or receiver to be soldered to other components in the same operation. Hereby will achieved a higher degree of rationalization and thus production costs saves.  

According to a further embodiment of the invention, the antenna and at least a supporting element carrying the antenna is made from one part. Preferably the antenna and the support element are made from a sheet of metal a stamping and bending process.

According to a further embodiment of the invention, the antenna is min least a contact point with the electrical mass of the transmitter and / or Receiver part connected. The advantage of such a λ / 4 radiator over that λ / 2 radiator is the smaller space requirement of the antenna.

According to a preferred embodiment of the invention, the impedance of the An compensated by the antenna at at least one contact point with the electrical ground of the transmitter and / or receiver part is connected. This can by a simple electrical bridging by means of a short circuit direction for the suitably on the antenna and on the transmitter and / or receiver part contact points are provided. The short circuit has essentially two functions: first, it detunes the resonance frequency of the Antenna so that no more interference radiation is received, on the other hand from an electrical point of view, the antenna feed contact is idle. In practice this short circuit can be realized by a suitable device in which spring pins special mounting holes on the antenna and device board to contact. The correct position of the short circuit on the antenna can by Test measurement of the input impedance can be determined.

In a further development of the method, the impedance of the antenna is compensated based on at least one compensation antenna in the vicinity of the antenna is brought, and the compensation antenna with the transmitter and / or receiver gerteil and / or the antenna is contacted such that the electro magnetic field of the compensation antenna by the electromagnetic field the antenna is lifted. Sending or receiving  Signals from the antenna are avoided by the compensation antenna because the antenna and the compensation antenna are polarized in opposite directions pick up.

In a further embodiment of the invention, the impedance of the antenna compensated by using the transmitter and / or receiver part and / or the antenna a compensator circuit can be electrically contacted, the freq dependent impedance of the compensator circuit opposite the fre is a sequence-dependent impedance of the antenna. In this process, Ver keep the antenna simulated by an electrical circuit. So sturgeon radiation from outside does not affect the sensitivity measurement, is pre suggest that when using a compensator circuit the measurement in an electromagnetic shielded room (Faraday cage) becomes.

A radio unit according to the invention, in particular manufactured according to the inventions method according to the invention, comprises a transmitter and / or receiver part and a Antenna, in particular a planar antenna, the antenna and at least a support element are made from one piece and the support element is an electri cal connection and / or a mechanical stable connection with the transmitter and / or receiver part. It is advantageous that the support element and the antenna consist of one piece, so that additional components are not necessary for a mechanical or electrical connection between the antenna and the transmitter and / or receiver part.

It is advantageous if the antenna with the transmitter and / or receiver part is soldered directly. Soldering avoids contact resistance, as caused by corrosion or contamination of the contact surfaces in one Switches can arise.  

According to a further embodiment of the invention, the transmitter and / or emp catcher part applied to a printed circuit board. Transmitter and / or receiver part, Printed circuit board and antenna thus form a compact, mechanically strong as robust module with optimal electrical and radiative properties.

According to a further development of the radio unit according to the invention, the transmitter and / or receiver part, or the antenna, provided with contact points for an external electrical contact, for example with the short circuit device device, the compensator circuit, the compensation antenna or the test device serve direction.

The radio unit is characterized in an advantageous manner in that the equipment kung the transmitter and / or receiver part with an antenna automatically in egg Nem work can be done with other components, so that the subsequent Assembly after the test measurement of the transmitter and / or receiver part falls and costs are saved. On the other hand, the radio unit has the advantage that the antenna and her at least one support element made from one piece are, so that the manufacturing process is simplified here.

Further advantages and details of the invention are based on the in the drawing illustrated embodiments explained. However, the invention is not limited to this, since numerous changes, especially the special one Interconnection, the geometry of the antenna or the transmitter and / or receiver partly and the special execution regarding the impedance compensation, are possible without changing the essential content of the invention.

They show schematically:

FIG. 1 shows an embodiment of a load applied to a printed circuit board together with a planar antenna short-circuit device;

Is brought compensation antenna in the vicinity of Figure 2 is a planar antenna.

Fig. 3 is a planar antenna with a transmitter and / or receiver part, and a compensator; and

Fig. 4 is a planar antenna, which is provided with an additional electrical Mas connection.

Fig. 1 shows a planar antenna 2 , which is soldered to a circuit board 6 with its support elements 3 . By the support elements 3 , the antenna 2 is held at a defined distance from the circuit board 6 , or the transmitter and / or receiver part 1 . The feed connection 12 coming from the transmitter and / or receiver part 1 is contacted via an electrically conductive support element 3 with the antenna ne 2 . During the test measurement of the RF circuit of the transmitter and / or receiver part 1 , the antenna 2 is electrically connected to the electrical ground 11 on the printed circuit board 6 by means of the short-circuiting device 7 . For the electrical contact of the short-circuiting device 7 with the antenna or the printed circuit board 6 , resilient pins and receiving bores are advantageous for a reliable reproducibility. Alternatively, flat contact points 4 made of corrosion-resistant material are proposed

Fig. 2 shows schematically the antenna 2 and a compensation antenna 8 , which are connected in opposite directions to the transmitter and / or receiver part 1 , so that the radiation emitted by the antenna 2 can be picked up by the compensation antenna 8 and is electrically short-circuited , It is important here that the antennas 2 , 8 are close together, the distance between the two antennas 2 , 8 being smaller than the wavelength of the emitted electromagnetic radiation. It would also be conceivable to mount the feed connections 12 of the respective antennas 2 , 8 not on the opposite side but on the same side, but then a phase shifter between the transmitter and / or receiver part 1 and the compensation antenna 8 is necessary so that the phase position of the emitted field of the compensation antenna 8 is shifted relative to the antenna 2 by 180 °.

Fig. 3 shows a transmitter and / or receiver part 1 , which is connected to an antenna 2 and a compensator circuit 9 , wherein the compensator circuit 9 electrically simulates the electrical behavior of the antenna 2 and is canceled by opposite polarity. With this electrical compensation of the frequency-dependent impedance of the antenna 2 , however, interference radiation from the outside, which prevents reliable and accurate measurement of the RF circuit of the transmitter and / or receiver part 1 , is not compensated for. For this purpose, a Faraday cage 13 is advantageous, which shields the entire measuring apparatus from disturbing radiation.

Fig. 4 shows a planar antenna 2 with four supporting members 3, wherein two support alarm zelemente 3 serve as electrical contacts on the one hand as a supply terminal 12 and the other as an electrical mass 11. The support elements 3 are soldered onto the printed circuit board 6 . The advantage of connecting the antenna 2 to an electrical ground 11 is that it turns the antenna 2 into a λ / 4 radiator, which is half the size of a λ / 2 radiator without electrical mass circuit.

The invention is particularly suitable for the automated and inexpensive manufacture of radio units in which the step of electrically connecting the antenna 2 to the transmitter and / or receiver part 1 after the test measurement is omitted, and the use of an additional component, such as an electrical switch , becomes superfluous. This results in a higher rationalization and the manufacturing costs for a radio unit are reduced.

LIST OF REFERENCE NUMBERS

1

Sender and / or receiver part

2

antenna

3

support element

4

electrical contact point

5

Test radio unit

6

printed circuit board

7

Short circuit device

8th

compensation antenna

9

compensator

10

radio unit

11

electrical ground

12

supply terminal

13

Faraday cage

Claims (12)

1. A method for producing a radio unit ( 10 ), in particular a mobile phone, in which first
an antenna ( 2 ), in particular a planar antenna, with a sensor and / or receiver part ( 1 ), preferably with its circuit board ( 6 ), is electrically and mechanically connected; and
the impedance of the antenna ( 2 ) is temporarily compensated in a frequency range relevant for the transmission and / or reception of radio signals;
and subsequently
the transmitter and / or receiver part ( 1 ) is tested, in particular its limit sensitivity is determined. 2. The method according to claim 1, wherein the antenna ( 2 ) with the circuit board ( 6 ) of the transmitter and / or receiver part ( 1 ) is soldered in the same operation as other components. 3. The method according to claim 1 or 2, wherein the antenna ( 2 ) and at least one supporting element ( 3 ) supporting the antenna ( 2 ) is made from one part, preferably with the aid of a stamping and bending process. 4. The method according to claim 1, 2 or 3, wherein the antenna ( 2 ) is connected at least at least one point to the electrical ground. 5. The method according to any one of claims 1 to 4, wherein the impedance of the antenna ( 2 ) is compensated by the antenna ( 2 ) by means of a short-circuit device ( 7 ) at least one contact point ( 4 ) with the electrical mass of the transmitter and / or receiver part ( 1 ) is connected. 6. The method according to any one of claims 1 to 4, wherein the impedance of the antenna ( 2 ) is compensated by
at least one compensation antenna ( 8 ) is brought close to the antenna ne ( 2 ); and
the compensation antenna ( 8 ) with the transmitter and / or receiver part ( 1 ) and / or with the antenna ( 2 ) is electrically contacted such that the electromagnetic field of the compensation antenna ( 8 ) with the electromagnetic field of the antenna ( 2 ) lifts each other away. 7. The method according to any one of claims 1 to 4, wherein the impedance of the antenna ( 2 ) is compensated by the transmitter and / or receiver part ( 1 ) and / or the antenna ( 2 ) with a compensator circuit ( 9 ) electrically contacts is, the frequency-dependent impedance of the compensator circuit ( 9 ) is set opposite to the frequency-dependent impedance of the antenna ( 2 ). 8. radio unit ( 10 )
with a transmitter and / or receiver part ( 1 ); and
with an antenna ( 2 ), in particular a planar antenna; in which
the antenna ( 2 ) and at least one support element ( 3 ) are made from one piece and
the support element ( 3 ) is an electrical connection and / or a mechanically stable connection with the transmitter and / or receiver part ( 1 ). 9. radio unit ( 10 ) according to claim 8, characterized in that at least two support elements ( 3 ) electrically connect the antenna ( 2 ) with the transmitter and / or receiver part ( 1 ), the antenna ( 2 ) on the one hand with the The supply connection ( 12 ) is connected to the electrical ground ( 11 ) of the transmitter and / or receiver part ( 1 ). 10. Radio unit ( 10 ) according to claim 8 or 9, characterized in that the antenna ( 2 ) with the transmitter and / or receiver part ( 1 ) is soldered. 11. Radio unit ( 10 ) according to claim 8, 9 or 10, characterized in that the transmitter and / or receiver part ( 1 ) on a circuit board ( 6 ) is brought up. 12. Radio unit ( 10 ) according to one of claims 8 to 11, characterized in that the transmitter and / or receiver part ( 1 ) and / or the antenna ( 2 ) have contact points for external electrical contacting.