NO178130B - Device for distributing a broadband signal over a branched coaxial cable network - Google Patents

Abstract

A device for distributing broadband signals via a branched coaxial cable network containing several network levels, comprising broadband amplifiers, with amplifier points containing auxiliary devices and with passive arrangements for signal distribution. To increase the transmission capacity, an optical waveguide network is provided in addition to the coaxial cable network, the ends of which are connected via opto-electrical transducers to output amplifiers of the coaxial cable network. The device can be advantageously used for distributing television and/or radio programmes. <IMAGE>

Description

The invention relates to a device for distributing broadband signals over a branched coaxial cable network according to the preamble of claim 1.

A device for distributing broadband signals over a branched coaxial cable network that includes several network areas and is provided with broadband amplifiers and with auxiliary devices is already known from DE-AS 23 64 061.

The known device is divided into several network areas. The broadband signal processed in a main station is distributed via spending or distribution areas to further network areas, whose lowest network plan is made up of the subscribers. The auxiliary devices serve for power supply and fault location. The power feed devices include devices for feeding in power feed energy and power feed filters for bypassing the amplifiers for the remote power flow. A device for direct current fault location serves for fault location, as its calculation results can be transmitted to a central transmission location. In addition, significant frequencies generated in the individual intermediate amplifiers are obtained for evaluation at the remote power site.

Furthermore, from DE-OS 23 46 834 a broadband cable network divided into several levels and strongly branched at its outlets is already known, which is equipped with a device for remote power supply.

In addition, FR-PS no. 2558674 discloses a device for the distribution of a broadband signal that accommodates television and/or radio signals, over a coaxial cable network branched over several network levels, which for the distribution of further broadband signals is extended with an optical waveguide network. The additional broadband signals, like the original signals, are routed via a coaxial cable network and an amplifier to a distribution point, from where the optical waveguide forwards the additional signals to the correct subscriber location.

Distribution networks of the aforementioned kind are set up for a signal transmission within a predetermined frequency range which enables the transmission of a predetermined number of television and/or radio programmes.

If the device's transmission capacity is no longer sufficient, the device can be replaced with one that has the desired, increased transmission capacity. However, this is particularly associated with a relatively large cost, when auxiliary devices of the aforementioned kind are integrated to a significant extent in the existing device.

Assessments within the framework of the invention have, however, shown that, in the case of the desired expansion of the transmission capacity, it is advantageous to use each of the passive components of the existing device in the area of the electrical distributors behind the last amplifier up to the handover point for the increased transmission capacity and to install an expanding fiber optic network in the areas of this part of the facility.

Based on these assessments, the purpose of the invention is to extend a device for the distribution of broadband signals over a branched coaxial cable network which, for the transmission of the broadband signals to be distributed, in particular no longer provides a sufficient frequency band, so that it is suitable for the distribution of additional broadband signals .

According to the invention, the device for achieving this purpose is carried out in the manner indicated in the characteristic of claim 1. This means that the passive parts of the coaxial network from the electrical distributor behind the last amplifier to the handover point on the subscriber side can each be used together for both frequency bands.

With the measures according to the invention, the advantage is obtained that the existing device for distributing broadband signals can thus be expanded in a particularly economical way with regard to its transmission capacity, so that the existing device for broadband communication, television program distribution and the like can find additional applications. The further development of the invention according to claim 2 has the advantage that existing passive devices for signal distribution can be kept unchanged when expanding an existing coaxial cable network, when the resulting increase in transmission capacity is sufficient.

The measures according to claim 3 have the advantage that the existing end amplifiers can find further applications and that an additional amplifier is only used to amplify the further frequency band to be distributed.

On the other hand, the further development according to claim 4 can prove to be particularly appropriate, when the space and/or the available remote power output is not sufficient for two amplifiers in the relevant final amplifier point. In this connection, the last amplifier in the amplifier chain is designed so that it amplifies the two frequency bands together and feeds the passive part to the handover point, especially to the house handover point.

Based on a broadband communication network in coaxial cable technology whose frequency range goes from 47 MHz to 450 MHz, the frequency range for the broadband signals to be further distributed preferably has the limits specified in claim 5.

Advantageous embodiments of the device in connection with the distribution of the further broadband signals appear from claims 6-8. On one and the same optical fiber network, all variants can occur together or in part.

In the further development according to claim 6, each of the optoelectric converters feeds in an appropriate manner

electric distributor. In the device according to claim 7, each amplifier for the upper frequency band appropriately feeds via an electric filter with the lower frequency band together the passive part up to the handover point. Free amplifier outputs for

the upper frequency band can possibly be fed to nearby amplifier points.

The measures according to claim 8 are advantageous when more distant amplifier points are to be fed.

Advantageously, according to claim 9, a double splitter arranged in a third grid plane is used to feed the upper frequency band to signal transmission paths. The branch's top is connected to an amplifier in said grid plane and one branch with an amplifier in a first or second grid plane and the other branch to an optoelectronic converter.

The device can be used particularly advantageously when additional television programs are to be distributed in connection with an existing coaxial broadband communication network.

The invention shall be explained in connection with the embodiment examples shown in the figures. Fig. 1 shows a device for distributing broadband signals over a coaxial cable network and a fiber optic network which is superimposed on this. Fig. 2 shows a coaxial cable network for superimposing a fiber optic network.

Fig. 3 shows an amplifier point with two end amplifiers.

Fig. 4 shows an amplifier point with one final amplifier.

Fig. 5 shows a frequency plan for the transmission of approx. 50 television programs. Fig. 6 shows a frequency plan for a transmission of approx. 7 0 television programmes.

The one in fig. The device shown in 1 is used for the distribution of television and radio programmes. The distribution takes place over the branched coaxial cable network 2, which contains several network planes and the additionally arranged optical fiber network 10.

The main station 1 serves for the input of the signals to be distributed in the coaxial cable network 2 and in the optical fiber network 10. Optionally, separate main stations can be arranged for the input of the additional broadband signals to be distributed.

The coaxial cable network 2 contains a number of amplifier points with broadband amplifiers for amplifying the broadband signals to be distributed. These broadband amplifiers are equipped with auxiliary devices, as is common with devices for distributing television signals. Consequently, each auxiliary device is not shown in more detail in the drawing.

The device contains electrical end amplifiers 6a in a part of the amplifier points. The output of the final amplifiers 6a is each via a passive device for signal distribution led to an equally passive house handover point 9 where all signals arriving for distribution or a selectable part of these signals are handed over to a subscriber.

The optical fiber network contains optical fibers 10a...10h connected at the main station 1. The optical fiber network 10 ends in each case at one of the amplifier points, i.e. at the location of a broadband amplifier arranged in the coaxial cable network 2. The ends of the optical fiber network are each via an optoelectric converter lia...Ild led to one or more end amplifiers 6a,6b in the coaxial cable network 2.

At the location Cl of the device, the end amplifier 6c in the coaxial cable network 1 is retained. Its bandwidth only covers the lower of the two assigned frequency bands. In this case, the optoelectric converter 11a is connected via its own amplifier 6b to the output of the final amplifier 6a.

At the amplifier location C2, the end amplifier in the coaxial cable network 1 has been replaced by the more broadband amplifier 6b, whose bandwidth includes both of the two assigned frequency bands. In this case, the optoelectric converter 11b is connected to an input on the final amplifier 6b.

In fig. 1 shows several appropriate designs of the nodes for the optical fiber network 10.

The optical fiber network 10 feeds the passive optical distributor 12 placed in one of the amplifier points with the upper frequency band. At the optical distributor 12, the final amplifier point C2 and further, not shown, final amplifier points are connected. In this connection, an end amplifier point shall be understood as an amplifier point with end amplifiers.

The light guides 10g lead to the optoelectric converter lid arranged in an end amplifier, to which the electric amplifier 6c1 for the upper frequency band is connected. This amplifier 6c1 has three outputs, two of which are led to each of two further amplifiers 6c2 for the upper frequency band. Two amplifier outputs 6c2 are used in the separate final amplifier point, so that the output of the relevant amplifier for the upper frequency band and the relevant final amplifier in the coaxial cable network 2 is via a filter led to a common distributor. The further outputs of the amplifiers 6cl and 6c2 are e.g. led to not shown end amplifier points in the coaxial network 2.

The light guides 10a are led to the optoelectric converter lic in the final amplifier point C4. At the output of the optoelectric converter 1c, the broadband amplifier 6c is connected. A first output of the broadband amplifier 6c is via the fork 13 led to the optoelectric converters 14a...14c, whose outputs over each of the further light guides 15...15c are led to further final amplifier points. A further optical spreader is connected to the light guide 13a. The free output of the wideband amplifier 6c and an end amplifier in the end amplifier point C4 are suitably led via a filter to the common distributor.

Fig. 2 shows a section of a coaxial cable network that is to be expanded. In a branch of the coaxial cable network 2, several broadband amplifiers are connected in chain which can belong to the first or the second network plane, A resp. B. One of these amplifiers 3 is connected to the final amplifier 6c with an additional output. The output of this final amplifier 6 is connected to the top of the double taper 16. One of the two outputs of the double taper is led to the C distributor 7 in the third network plane C. Respectively the A and B broadband amplifiers 3, the C amplifier 6, the C double taper 16 and the C distributor 7 form the amplifier point CO. The C-distributor 7 has several outputs which are led via a branching device to respective several house handover points. The branching device connected to one of the outputs of the C-distributor 7 consists of a chain connection of several branches 8.

Fig. 3 shows that in fig. 2 showed section after extension of the coaxial cable network with the optical fiber network.

The C-double branch 16 occurring at the output of the C-amplifier 6 is no longer connected to one of the two branches, but is instead led via its top to the input of the C-distributor 7. One of the two branches of the C-branch 16 is connected to the C-amplifier 6, the second branch of the C-brancher 16 with the additional distributor 6c for the upper frequency band. Fig. 4 shows that in fig. 2 showed section after extension of the coaxial cable network with the optical fiber network. The one in fig. 2 C-double branches 16 originally occurring at the output of the C-amplifier 6 are connected at their apex to the input of the C-amplifier 6b. One of the two branches of the C branch 16 is connected to the A and B amplifiers 3, respectively, the other branch of the C branch 16 to the optoelectric converter 11b. Fig. 5 shows a first frequency plan for the one in fig. 1,3 and 4 showed equipment for the distribution of broadband signals. There are respectively 24 or 26 PAL channels and 12 D2-MAC channels for the transmission of television programs in the range 47-450 MHz. In addition, a number of radio channels are also located in this band. In addition, service lines, monitoring channels and return channels for broadband communication are transmitted via the coaxial cable network.

As an extension of the specified transmission band KX for the coaxial cable network, 12 PAL channels in the frequency range 470 to approx. 600 MHz in the frequency range LWL1.

The frequency plan in fig. 6 agrees with the one in fig. 5 as regards the KX frequency band. In contrast, an additional 35 PAL channels are also transmitted via the optical fiber network. The upper frequency band thus extends from 470 to 860 MHz.

The main station does not contain shown electro-optical converters which convert the upper frequency band correspondingly linearly. Preferably, DFB (distributed feedback) lasers with an optical isolator are used in this connection. As a transmission method, amplitude modulation with the residual sideband is used in particular. PIN diode receivers are suitable as optoelectric converters.

Claims (9)

1. Device for distributing a broadband signal which in a predetermined frequency band contains television and/or radio signals, over a coaxial cable network (2) branched over several network levels with at least one main station (1) for feeding in the signals to be distributed in the coaxial cable network (2 ) and with a further optical waveguide network (10) with at least one main station (1) for feeding in further broadband signals to be distributed and whose ends are in each case led to an optoelectronic converter (lia...Ild), characterized in that the coaxial cable network (2 ) have broadband amplifiers and amplifier points, with some of the amplifier points housing electric end amplifiers (6a) whose output via a passive device for signal distribution (7, 8) is led to passive handover points for handing over at least part of the signals to be distributed, that the ends of the optical fiber network (10) in each case is led to an optoelectric converter in the amplifier points, that the optoelectric converter e are connected to end amplifiers (6a, 6b) and that the signals fed into the optical fiber network (10) comprise a frequency band which, after the optoelectric conversion, lies above the frequency band transmitted over the coaxial cable network (1). 2. Device according to claim 1, characterized in that the upper limit of the upper frequency band is selected in such a way that the upper frequency band at the passive device for signal distribution (7,8) and the passive handover point can be transmitted on an existing coaxial cable network. 3. Device according to one of claims 1 and 2, characterized in that at least one place in the device the bandwidth of the final amplifier (6a) includes only the lower of the two frequency bands, and that the optoelectric converter (lia) is via a separate amplifier (6c) connected to the output of the final amplifier (6a). 4. Device according to one of claims 1 and 2, characterized in that at least one place in the device the bandwidth of the end amplifier (6b) includes both frequency bands, and that the optoelectric converter (11b) is connected to an input on the end amplifier (6b) . 5. Device according to one of claims 1-4, characterized in that the lower frequency band comprises the range from 47-450 MHz, and that the upper frequency band begins at 470 MHz and ends at a frequency that is at least approx. 600 MHz and a maximum of approx. 860 MHz. 6. Device according to one of claims 1-5, characterized in that the optical fiber network (1) comprises at least one optical fiber (10a) which ends in one of the amplifier points and feeds an optical distributor (12) with the frequency band, and that the outputs of the optical distributor (12) each is led to the optoelectric converter. 7. Device according to one of claims 1-6, characterized in that the optical fiber network (10) comprises at least one optoelectric converter (lid) fed via an optical fiber (10g) with the upper frequency band to which several electric amplifiers (6c) for the upper frequency band is connected, and that respectively one of these amplifiers (6c) and one of the final amplifiers is led to a common distributor (7). 8. Device according to one of claims 1-7, characterized in that a chain connection of an optoelectric converter (lic), an electric amplifier (6c) for the upper frequency band and an electrical distributor (13), and that the outputs of the electrical distributor (13) are connected to each of the electro-optical converters (14a...14c), whose output over at least one of the additional light conductors (15a...15d) ) is connected to one of the other amplifier points. 9. Device according to claim 1 or 2, characterized in that for feeding the upper frequency band into the signal transmission paths, a double branch (16) occurring in a third network plane is arranged, the top of which is connected to the input of the amplifier (6b) occurring in this plane, that one branch of the double branch (16) is connected to the output of an amplifier (3) occurring in a first or second grid plane and the other branch with an optoelectronic converter (11b), and that in that connection the first, second and third grid planes are also designated as A-, The B and C plane.