NL1006679C2 - Telecommunication network. - Google Patents

Description

Telecommunication network

The invention relates to a telecommunication network, comprising a number of interconnected signal distributors / collectors, each of which comprises a directional coupling with at least four two-pole connections, the first connection of one of the signal distributors / collectors being connected to a common signal supply line, the second connection of each signal distributor / collector is connected to the first connection of an adjacent signal distributor / collector, the third connection of each signal distributor / collector is connectable to a user station, and the fourth connection of each signal distributor / collector is connected to a signal output line, which signal distributors / collectors 15 are each arranged for distributing reception signals from the signal supply line among the user stations in a predetermined manner and for substantially collecting user signals from the user stations on the signal discharge line, characterized in that each signal distributor / collector is provided with means for independently allowing the distribution of the reception signals among the user stations and the collection of the user signals on the signal output line.

In a first preferred embodiment, the means are arranged to interrupt the connection between the signal supply line and the user station as well as to connect the user station to the signal output line.

30 For the distribution of signals, as practically carried out in the district networks of a telecommunications network, such as a wire broadcasting device or cable television network, 1006679 2 signals from one point, such as the district center, are distributed among a large number of users by application. of signal distribution elements, including both equally and unevenly distributing elements. The 5 distribution gives such a district network a star-shaped structure.

Furthermore, in the district networks of the current cable television networks in the signal path from the district center to the users, after the last amplifier used, the so-called power amplifier is usually carried out once more, using one or more distributor (s) on which some to several dozen users are directly connected with cables.

The radio and television receivers, which are connected to the users' network on the district network, usually have the disadvantage that they produce unwanted signals, which can be observed on the "antenna connection" of these receivers. These receivers 20 are now precisely connected to the network via that antenna connection, which creates the possibility that these and any other undesired signals arising from the users will be sent back into the cable television network. The undesired return signals thus generated need not be objectionable per se, as long as these signals can then be prevented from ending up with other users. The distributors used for the signal distribution for the users must therefore be designed in such a way that they do not transfer any occurring return signals from the user terminal where these return signals arrive to any other user stations. The desired property of the signal distributors is indicated by decoupling or isolation between user stations. In general, for this insulation the technical requirement applies that the transferred voltage cannot exceed a certain value, which, depending on the applicable regulation, approximately 1% of the voltage (approximately -40 dB) of 1006679 3 originally at the distributor arrived return signal may amount.

For this purpose, the distributors are built up using one or more so-called "directional couplings" or "directional couplings" known in the art. In principle, such a directional coupling has four two-pole connections. In principle, each of these connections can function as a signal input in which the supplied signal is divided between two of the three other connections, in theory the fourth connection receives no signal at all. For such a directional coupling, one can imagine for a good understanding the connections such that they form the four vertices of a square, and that when signal is supplied to any of the four connections, the signal is distributed to the two connections next to it (above and below) and not at all to the diagonally opposite connection.

20 A directional coupling can be either frequency dependent or frequency independent. For example, a frequency-dependent directional coupling comprises a number of conductors, which are mutually coupled inductively as well as capacitively. The intended signal attenuation can be adjusted by varying the mutual distance between the conductors. A frequency-independent directional coupling is, for example, built up from transformers, in which the winding ratios determine the signal attenuation.

With these directional couplings it is possible to build multiple distributors (multi-distributors) that meet the requirements of distribution and insulation.

In recent years, the use of 35 cable television networks has created a need to enable, in addition to the distribution of signals intended for users, the processing of signals that are purposefully generated by users, also known as desired return signals or 1006679 4 user signals. One could think of signals related to the initially intended distribution (for example, interactive radio and television, etc.), but also 5 signals that are completely separate from the distribution, for example security, etc. The aforementioned known signal distributors are passive. . Passive distributors have the property that they can not only distribute signals from one signal supply line, but also collect 10 signals from multiple user stations to one signal output line. In addition, a signal loss occurs in the said set which is equal to the signal loss in the said distribution; in other words, the signal distributors can function in the same way as signal collectors.

It should be noted that in theory the same frequencies could be used for the desired return signals as for the distribution signals. For technical reasons, however, this is not possible and in order to avoid annoying disturbances, it is necessary to avoid repetition of the applied frequencies in order to avoid the frequency selection for distribution and desired return signals. A suitable choice is, for example, 5-50 MHz for user signals or return signals and 50-1000 MHz for reception signals or distribution signals.

The invention will be described in more detail below with reference to the drawings, in which figure 1 schematically shows a known directional coupling; Figure 2 schematically shows a number of mutually connected signal distributors, each of which is provided with a directional coupling according to figure 1; figure 3 schematically shows a variant of figure 2, supplemented with a signal discharge line.

Figure 4 schematically shows one of the signal distributors of figure 2, which is provided with switching means; 1006679 Figure 5 schematically shows one of the signal distributors / collectors from the variant according to Figure 3, which according to the invention is provided with switching means; and Figures 6 and 7 schematically show two alternative embodiments of a signal distributor / collector according to the invention.

Fig. 1 shows a signal distributor designed as directional coupling. For example, a signal distribution of 10% / 90% on a power basis will be used here, based on lossless directional couplings. With signal connection to terminal a, 10% of this will become available at terminal c, 90% at terminal b and 0% at d. In practice, a signal distribution in the range 5% to 10% / 95% to 90% will preferably be realized.

Fig. 2 shows an assembly of several directional couplers 1 to 5 to a multiple distributor, u form the power supply connection of the assembly, v, w, x, y and z form the connections to which the user stations are connected. The signal to be distributed is supplied on signal supply line 6 (for this example the 10% / 90% power distribution is maintained here as before). 100% 25 is supplied to 1a, 10% subsequently becomes available to 1c, 90% to 1b and 0% to 1d. The 10% of lc is directed to user output w. The 90% of lb is delivered to 2a. 9% (10% of 90%) becomes available at 2c, 81% ((90%) 2) becomes available at 2b and 0% at 2d. The 30 9% of 2c is delivered to user station x. The 81% is delivered to 3a etc.

The special effect first appears with the return signals, for example with signal delivery (desired and undesired) from a user to, for example, user station x. 100% of this signal is supplied to 3c, 10% subsequently becomes available to 3a, 90% to 3d and 0% to 3b. So no signal becomes available at 3b and therefore at 4a. Thus, user stations y and z are 1006679 6 protected against the signals of x. The 90% at 2d ends up in the connected resistor. The 10% of 3a is delivered to 2b. 1% ((10%) 2) becomes available at 2a, 0% at 2c. So no signal becomes available at 5 2c and therefore at w and correspondingly then also not at v. The 9% of 2a is supplied to lb and will eventually become 8.1% ((90%) 2 x 10%) on la and thus become available to you.

In summary, the known signal divider / collector fulfills the intended function: 1. the receive signal supplied to the signal supply line is distributed to the user stations with attenuation of 10%, 9%, 8.1%, 7.3% etc; 2. user signals supplied by the user stations are collected to the signal supply line with attenuation to 10%, 9%, 8.1%, 7.3% etc; 3. user signals from one user station 20 cannot reach the other user stations.

A variant arises in the embodiment according to figure 3. Here, use is made of the fact that 90% of the return signals become available at the terminals d of the directional couplings 1, 2, etc., where they are then (according to figure 2) via the resistors R1, R2, etc. are connected to ground. Preferably, all resistors R1 through R5 each have a value of substantially 75Ω. By not connecting these resistors (according to figure 3) to earth, but to a signal output line 7 and via this to connection q, an alternative route for the return signals has been created. Since for other reasons it was already necessary to choose different frequencies for distribution and desired return signals, one can now make use of this circumstance and the connections of q and u by means of selective means, such as a so-called duplex filter, outside the multiple distributor 100667 © 7, which promotes a flexible application of the distributor. The values of resistors R6 through R10 are preferably adjusted such that terminals 1d through 5d "see" 75Ω.

The processing of the signals described above is complicated by the fact that in a cable television network the applied signals have relatively high frequencies (approximately 5 to 1000 MHz) and because the directional couplers and other components to be used are in fact not ideal. In the first place, in order to avoid points at which these signals can reflect, measures must be taken for signals with these frequencies, so that the impedance of the signal paths is kept the same everywhere. This is referred to as impedance matching (or in the opposite case of impedance deviation). In the case of cable television, the desired impedance is usually 75 Ω.

Furthermore, it has proved useful in the technical and operational control of a cable television network to implement the discussed last distributor in such a way that the distributed distribution signals can be interrupted or passed on at will and per connected party (see figure 4.). technical and operational control of the network is increased by also being able to use the interrupting / passing through for each connected party for the purpose of the return signals to be collected. (see figure 5.)

Obviously, the shutdown required for such an interruption should itself be sufficiently effective in that it avoids the unwanted capacitive and inductive coupling easily occurring at higher frequencies, which may still cause transmission of switched signals; this desired property of the shutdown is referred to as insulation. In general, for this insulation the technical requirement applies that the transferred voltage cannot exceed a certain value, which in practice 1 0 06 6 79 8 is approximately 0.1 to 1% of the voltage (-60 to -40 dB ) of the original signal. This isolation can be realized with some effort when applying the intended high frequencies.

5 The intended good impedance matching of the signal paths is also extra complicated when switching off, because the interrupted signal path is usually not open or. may be left unloaded. Depending on the circumstances, one or both of the ends of the signal path cut open by the switch-off must be connected to earth via a resistor of 75 Ω, which necessitates, among other things, the use of switches, which are designed as switches.

The possible interruption of the signals will be explained below with reference to Figures 4 and 5.

It should be noted that the following examples use transfer switches. In this description, contact e is referred to as the "break contact" and contact f is referred to as the "make contact". The contact moving from 20 to 'X. (v.v.) is diverted is called "changeover contact".

In the following examples, for the sake of a good overview, switch S1 is referred to as the "distribution switch" and switch S2 is referred to as the "collection switch".

Fig. 4 shows part of the assembly of Fig. 2. The connection from lc to the user v is via distribution switch S1. This switch has two positions. In position e (shown), the user station v is connected to terminal lc via the changeover contact and the break contact. The switch is designed in such a way that in position f (not shown) any return signals from the user are connected to earth via the changeover contact and the make contact via resistor Ril. The value of both Ril and R12 is 75Ω.

FIG. 5 shows part of the assembly of FIG. 3. Here, too, the connection 1c to user stations v runs via the changeover contact and the break contact of distribution switch SI, such as via terminal 1d 1006679 9 and resistor Ril. The connection to signal drain line 6 is made via collector switch S2. This switch also has two positions. In position e (shown), the signal from resistor R13 is connected to signal output line 7 via the break contact and the changeover contact. In position f (not shown), the signal output line is connected to earth through resistance changeover contact and make contact via resistance R13. The resistance values are preferably chosen as follows: 10 Ril = 75Ω, R13 = 270Ω, R14 = 100Ω, R15 = 220Ω.

In this embodiment, the divided signals together with the collected signals can be interrupted with dividing switch S1. In addition, the collected signals can be interrupted separately with 15 collector switch S2. However, it is not possible to interrupt the distribution signals and at the same time pass the collection signals.

In connection with the return signals that may be desired in a cable television network, which are completely separate from the distribution, it may be important to be able to pass on return signals even in the event that the distribution signals are interrupted.

It is conceivable, for example, that if the cable television network offers both the service 'supply of radio and 25 television signals' and the service 'electronic security', these should be offered separately from each other (no tying) and should therefore be able to be interrupted separately and let through. The telecommunications network according to the invention makes this possible.

The invention will be explained in more detail below with reference to Figures 5 and 6.

Because in the design according to Fig. 5 the break contact of switch SI in addition to the reception signals 35 inevitably switches off the user signals.

in order to realize the invention it is necessary in that situation to open a new signal path for the user signals. In position f of distribution switch SI

1006679 10, the user stations v are connected to earth via the make contact and the changeover contact via Ril. In position f of collector switch S2, connection q is connected to earth via the signal output line through the changeover contact and the make contact via R13.

According to the invention, in Fig. 6 the make contact of distribution switch S1 and the make contact of collector switch S2 are no longer connected to earth via resistors (only) but to each other via resistor R17. This ensures that a signal path to the signal output line is also available for the user signals from the user station v in position f of the distribution switch S1 when the collection switch S2 is placed in position f. Preferably the following applies: R16 = 100Ω and R17 = 220Ω.

It is noted that in various schemes (fig. 6, 7 and 8) only principles are indicated, which can be further developed in practice. For example, resistors R11 through R17 for optimum isolation, impedance matching and signal level constancy can be replaced by more complicated resistor networks or filter circuits.

The table below gives an overview of the various switching options.

position of switches signal path condition Si S2 distribution sign, return sign.

1 1 passage passage 30 2 l interrupted interrupted 2 2 interrupted passage 1 2 passage interrupted

By designing the distribution switch S1 and / or the collection switch S2 as a double-pole changeover switch, the insulation properties and impedance matching can be improved. This is shown in figure 7.

1006679 11

In the technical and operational control of the telecommunications network, it is useful to be able to control the signal interruption and thus the switching on and off remotely from one central point.

5 For this purpose, the switches must be designed as relays.

For the sake of minimal electricity consumption, it is also useful to design the relays as impulse relays.

A data communication system, in which use is made of the telecommunication possibilities of the own network, is very useful for controlling the above relays.

It will be clear that many variants of the shown embodiment are conceivable, all of which fall within the scope of the invention.

1 0 06 6 79

Claims (11)

Telecommunications network, comprising a number of interconnected signal distributors / collectors, each comprising a directional coupler with at least four bipolar connections, the first connection of one of the signal distributors / collectors being connected to a common signal supply line, the second connection of each signal distributor / collector is connected to the first connection of an adjacent signal distributor / collector, the third connection of each signal distributor / collector is connectable to a user station, and the fourth connection of each signal distributor / collector is connected to a signal output line, which signal distributors / collectors each are arranged for distributing reception signals from the signal supply line in a predetermined manner among the user stations and for substantially collecting user signals from the user stations on the signal output line, with the characterized in that each signal distributor / collector is provided with means for independently allowing the distribution of the reception signals among the user stations and the collection of the user signals on the signal output line. Telecommunication network according to claim 1, wherein the means are arranged for interrupting the connection between the signal supply line and the user station as well as connecting the user station with the signal output line. Telecommunication network according to claim 1 or 2, wherein the means are switching means. 4. Telecommunication network according to claim 3, wherein the switching means comprise a first switch, which is switchable between a first position, in which the first switch connects the user station to the 1006679 signal supply line, and a second position, in which the first switch connects the user station to the signal drain line. Telecommunications network according to claim 4, 5 in which the switching means comprise a second switch, which is switchable between a first position, in which the second switch connects the directional coupling to the signal output line, and a second position, in which the second switch connects the signal output line to the signal output line. user station. Telecommunications network according to claim 5, wherein the means further comprise a resistance network, which is included in the connection between the user station and the signal output line and which interconnects the first and the second switch in its second positions. Telecommunication network according to claim 3, wherein the switching means comprise relays. Telecommunication network according to claim 7, 20, wherein the relays are impulse relays. Telecommunication network according to claim 3, wherein the switching means comprise double pole switchers. A telecommunications network according to any one of the preceding claims, wherein one or more of the signal distributors / collectors are arranged in such a way that substantially 90 - 95% of a signal offered at the first connection is available at the second connection, and that substantially 10 - 5% of the signal is available at the third terminal, with substantially 0% of the signal available at the fourth terminal. Signal splitter / collector, as described as part of the telecommunications network according to any of the preceding claims. 1006679