FR2685586A1 - Device for routing in terms of frequency, with impedance matching - Google Patents

Abstract

Device for routing (1) in terms of frequency between a first channel (2) and at least two second channels (10, 20), each including a filter (13, 23) transmitting a frequency band specific to the second channel (10, 20), having a circuit (14, 24) blocking the frequency band of the other second channel (10, 20), these filters (13, 23) being linked to the first channel (2) via a specific line (12, 22) amplifying more the impedance of the tuned filter (13, 23) for the frequency band of the other second channel (20, 10) than it does for the frequency band of the second channel in question (10, 20). Application to radiotelephone diplexers.

Description

FREQUENCY SWITCHING DEVICE
ADAPTATION OF INDEPENDENCE
The present invention relates to a frequency switching device between several individual channels connected to a common channel.

Such frequency switching devices are known which allow a common channel to be put in communication simultaneously with several other channels, each other channel having a filter allowing a frequency band specific to the channel to pass and blocking the passage of the other frequency bands. , the filters being combined at the level of the common channel. Such a switching device is, for example, used for putting several transmitters and / or receivers into communication with a common antenna.

For each individual channel, however, its frequency band must not be attenuated by the impedance of the filters of the other channels, which are connected in parallel at the level of the common channel.

One solution consists in choosing a filter structure which causes an increase in the impedance considered outside the passband of this filter. However, this imposes constraints on the structure of the filter which can adversely affect the quality of transmission in bandwidth. In addition, if the frequency bands are close, it is difficult to have a filter impedance which varies abruptly, so that it is necessary to add additional stages to the filter, which become bulky and expensive.

 It is often necessary to achieve a compromise leading to choosing a filter having a mediocre transmission at the end of the transmitted band, owing to the fact that its impedance begins to increase, which makes it possible to have an impedance having increased sufficiently for the frequency band of the neighboring channel. . The result of this compromise degrades the performance of the device. It is obviously possible to choose frequency bands which are very far apart from each other, but this leads to improper use of the bandwidth of the transmission medium.

The present invention aims to solve this problem.

To this end, the invention relates to a frequency switching device between a first channel and at least two second channels, each comprising a filter allowing a frequency band of its own to pass and blocking the frequency band of l another second channel, characterized in that the homologous terminals on one side of said filters are each joined by a proper impedance transformer amplifying the impedance of the associated filter perceived by this impedance transformer for the frequency band of the other filter and amplifier, but to a lesser extent, this impedance for the frequency band of the filter considered.

Each filter can thus interrupt, for example by a high impedance series circuit, the passage of the frequencies of the bands of the other channels and present, on the first channel, a higher impedance, for the frequencies transmitted by the other second channel, than for its own transmitted frequencies, which avoids a diversion of energy towards a second channel not concerned by the frequencies of the second channel considered. Said impedance amplifications, resulting in the change in the ratio of the impedances in the own frequency band relative to the other band, cut, can have any desired value, by a factor, specific to each, lower, equal or much higher to unity.

Advantageously, said filters are of the Cauer type
Chebyshev. Such filters are described in ............

It is thus possible to choose the position of the poles of the voltage transfer function of the filters so as to block the frequencies of the other second channel, and to have a filter impedance which varies little in the frequency band of the other second channel. , which ensures maintenance of the high impedance characteristics in the other, or the others, second channel.

Said impedance transformer can consist of a transmission line of suitable length. Thus, this line is used both to convey the frequency band and to carry out the impedance transformation, which avoids the installation of additional equipment.

Advantageously, this transmission line has a characteristic impedance equal to the impedance presented, on the side of said transmission line, by the connected filter.

This transmission line can be a microstrip line. It can thus be produced on a printed circuit module carrying the other components. Its realization by engraving does not induce any additional cost and its geometrical form, therefore its electrical characteristics, are fixed, which ensures its quality.

This transmission line can also be a coaxial line. The filters can thus be connected to a first remote channel.

The switching device according to the invention can comprise two second tracks. A simple construction diplexer is thus produced.

The invention will be better understood using the description of the preferred embodiment of a frequency switching device according to the invention, with reference to the drawing, in which - FIG. 1 represents the electrical circuit of a
diplexer according to the invention; - Figure 2 illustrates the evolution, depending on the
frequency, voltage transmission
filters of the diplexer - Figure 3 illustrates the evolution of the module of a
impedance at the end of a line and - Figure 4 illustrates the evolution of the impedance module
of figure 3 at two frequencies
different.

The switching device 1 represented in FIG. 1 comprises a first channel 2 connected to a first and a second second channel, respectively 10 and 20, each having a so-called output terminal, respectively 11 and 21. Each second channel 10 and 20 comprises an impedance transformer, respectively 12 and 22, consisting of a microstrip line, connected, on one side, to the first channel 2 and connected, on the other side, to a filter, respectively 13 and 23, specific to the second associated channel 10 and 20.

Each filter 13,23 of a second channel 10,20 allows its own frequency band to pass and attenuates the frequency band of the other second channel 20,10 by means of a dipole circuit, respectively 14 and 24 , consisting of a "plug" circuit formed by an inductor respectively 15 and 25, connected in parallel to a capacitor, respectively 16 and 26, this dipole 14 or 24 being tuned in the vicinity of the central frequency of the frequency band of the other second channel 20 or 10. One side, arbitrarily called output, of this dipole 14 or 24, is connected to terminal 11 or 21 of the second channel 10 or 20 concerned.

For the first second channel 10, an inductor 17 and a capacitor 18 are connected in parallel between the terminal 11 and the ground, while an inductor 19 is connected between the side, arbitrarily called input, which is not connected to the terminal 11, dipole 14 and ground.

For the second second channel 20, a capacitor 27 is connected between the input of the dipole 24, opposite the terminal 21, and the ground. The elements other than the dipole 14 or 24 have, among other things, the purpose of adapting the impedance of the filter 10 or 20 on each side of the respective dipole 14 or 24, so that, in particular, there is no sudden variations in impedance in each second channel 10 or 20 for the frequencies of the band transmitted by this second channel 10 or 20, lines 12 and 22 here having a characteristic impedance equal to that of the input side of the filter 13 or 23 concerned The impedance of the filter 13 or 23 perceived by the associated line 12 or 22, for the frequency band of the other second channel 20 or 10, is transformed, at the other end of this line 12 or 22 connected to the first channel 2, at an almost infinite impedance, with quality close to the components and near impedance variations in the frequency band considered. This transformation is regulated by choosing an appropriate length of line 12 or 22 which, according to the theory, well known to those skilled in the art, lines with distributed constants, performs a transformation from one impedance value to another dependent value of the length of the line 12 or 22 and passing cyclically through a maximum as a function of the line length, which can be of infinite value if the impedance has no resistive component, the spacing of these maxima depending on the frequency .

As regards the frequencies of the transmitted band, the impedance adaptation between filter 13 or 23 and line 12 or 22 means that there is no significant change in the impedance of filter 13 or 23 Even in the event of imperfect adaptation of impedance between the filter 13 or 23 and the line 12 or 22, it is sufficient that the impedance in the pass band is increased less than is that in cut band to reach the desired result.

In the case of more than two second channels 10 and 20, it is necessary to choose the respective lengths of the lines such as 12 and 22 so that each filter 13 and 23 has, through the associated line, a high impedance for the bands of frequencies of the other second channels. This can be calculated and carried out because, as indicated above, the distance of the impedance maxima depends on the frequency. There is therefore theoretically a plurality of appropriate lengths for each frequency, and there is at least one length for which all the impedances are approximately maximum (FIG. 3).

The disclosed embodiment uses passive elements. It is obvious that active elements would also be suitable.

FIG. 2 shows, as a function of the frequency, the evolution of the transmission T of the filters 13 and 23.

The filter 13 of the first second channel 10 transmits the frequency band around a frequency f1, for example 400 MHz, and prevents the passage of the frequency band around a frequency f2, for example 900 MHz, as indicated by curve C1. The curve C1 passes through O for f2 and includes a portion of value of
T close to 1 around f1. For its part, the filter 23 allows the frequency C to pass and prevents the passage of the frequency f1, as represented by the curve C2.

Figure 3 shows the variation of the impedance module
Z at the end of a line with distributed characteristics, as a function of the length of this line, at a given frequency. So, if you connect an impedance Z1 (point A) to the line, you can choose a length
L2-L1 line at the end of which (point B) the impedance is of very high value.

FIG. 4 schematically shows, for two frequencies f and f4, the variations of the module Z of the impedance as a function of the length of the line, the distance of the maxima of the same frequency being equal to half a length d 'wave. We thus see that there are periodically coincidences of position (points C and
D) maxima relating to the two frequencies f3 and f4.

We have described a filter 13,23 blocking the transmission of the frequency f2, f1 concerning the other second channel 20,10 by means of a series dipole 14,24. It is obvious that a person skilled in the art knows other ways of achieving this blocking, for example by means of a dipole tuned to the frequency to be blocked, consisting of an inductor in series with a capacitor, dipole connected, in this case, in parallel to ground, instead of being connected in series, which is equivalent to a short circuit at the blocked frequency, therefore at zero voltage.

Claims (8)

1. Frequency switching device (1) between a  first channel (2) and at least two second channels  (10,20) each comprising a filter (13,23) leaving  pass a specific frequency band and  blocking the frequency band of  the other second path (20,10), characterized by the fact  that the homologous terminals on one side of said filters  (13,23) are each brought together by a transformer  own impedance (12,22) amplifying the impedance of the  associated filter perceived by this transformer  impedance (12,22) for the frequency band of  the other filter (23,13) and amplifying, but so  lower, this impedance for the frequency band  of the filter (13,23) considered. 2. Referral device according to claim 1,  wherein each filter (13,23) has a circuit  blocking series (14,24). 3. Referral device according to one of  claims 1 or 2, wherein the filters  (13,23) are of the Cauer-Chebyshev type. 4. Referral device according to one of  claims 1 to 3, wherein said trans  impedance trainer (12,22) is a line of  transmission of suitable length. 5. Referral device according to claim 4,  in which the transmission line (12,22) has a  characteristic impedance equal to impedance  presented, on the side of said transmission line  (12,22), by the connected filter (13,23). 6. Referral device according to one of  claims 4 or 5, wherein the trans line  mission (12,22) is a microstrip line. 7. Referral device according to one of  claims 4 or 5, wherein the trans line  mission (12,22) is a coaxial line. 8. Referral device according to one of  Claims 1 to 7, comprising two second tracks  (10.20).