NL1010769C2 - Telecommunication system and connection device for use therein. - Google Patents

Description

Telecommunication system and connection device for use therein.

The present invention relates to a telecommunication system comprising first telecommunication means capable of receiving a first telecommunication signal in a first frequency domain, second telecommunication means capable of transmitting a second telecommunication signal in a second frequency domain and a telecommunication network. The invention further relates to a connection device for coupling to a common telecommunication connection 10 first telecommunication means capable of receiving a first telecommunication signal in a first frequency domain as well as of second telecommunication means intended for transmitting a second telecommunication signal in a second frequency domain, comprising an output for the first telecommunication means, an input for the second telecommunication means and a common connection for the telecommunication connection.

The majority of telecommunications services take place over tailored telecommunications networks. For example, for voice transmission use is generally made of public telephone networks, referred to as PSTN (Public Switched

Telephony Network) and numerous data networks specifically designed for that purpose are operational for data exchange between computers. Video and audio signals usually find their way through the airwaves and in many industrialized countries increasingly in cable television networks built on high quality transport media such as fiber optic and co-axial cables. A user wishing to make use of all these services will therefore have to have a corresponding number of connection facilities.

The advancing computerization of society leads to an ever-expanding existing telecommunications services or even to the emergence of ever new telecommunications services, which moreover are increasingly aimed at private users. In addition, these services are increasingly interactive, sometimes requiring high data throughput rates to transmit large amounts of information to the user at an acceptable time. Examples of this are forms of telemetry, pay-per-view and in particular the internet, which, due to the further implementation of multi-media applications, also requires an increasingly higher data throughput speed.

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As the maximum data throughput speeds and the achievable bandwidth of a public telephone network are increasingly perceived as limitations with such interactive services, alternative networks for data transfer are being searched diligently. A candidate that presents itself is the cable television network, as it has now been widely branched out in many 10 industrialized countries. This network differs from the public telephone network in that it is based up to the end user on a high-quality transport medium that varies from high-quality fiber optic connections in higher parts of the network to high-quality co-axial cables for connection of the subscribers. Such connections offer a considerably larger bandwidth and allow a considerably higher throughput than the public telephone network to which subscribers are connected by means of a simple pair of twisted copper wires. Moreover, the integrity of digital signals in such a high-quality network is better guaranteed.

However, 20 cable television networks have been designed primarily for the distribution of radio and television programs, which take place in one direction from the network to subscribers. Return traffic from the subscriber to higher-lying parts of the network, such as the second telecommunication signal of the second communication means mentioned in the preamble, was not provided at first instance, but is increasingly required in present-day telecommunications. In order to make the latter possible, existing cable television networks are increasingly being upgraded and made suitable for two-way traffic. These adaptations mainly consist in the installation of bypass filters and bypass amplifiers that allow the transmission of return signals in parallel to the existing amplifiers in the network. These return signals are thereby located in a relatively low frequency domain which is not occupied by the radio and television channels to be distributed and which suffers less from 1010769 -3 signal attenuation. A problem that arises here is that after such an adaptation of the network not only data traffic in the return direction is possible, but also noise generated by the end user, referred to as ingress noise, can now freely enter the network and be amplified. Ingress noise is largely derived from connection cables that are used in the home for connecting the equipment present there. Such cables act as antennas that capture any electromagnetic disturbances in the house and transmit them to the cable network. The latter is, of course, undesirable, the more so because the lower frequency bands in which the digital data transport must take place are relatively noise sensitive.

Another incident is that with two-way use of a cable television network, no longer only receiving devices, such as a radio or television receiver, will be present at an end user, but also sending equipment for sending return signals. If all equipment is simply connected together to the existing connection facility for the cable television network, the return signals from such transmitting equipment will inevitably also flow to the receiving devices and may interfere with the intended communication signals. Typical cable television transmission equipment is usually optimally tuned to send signals without regard to the influence thereof on any other equipment present. The output level is usually 80-115 dBpV. Since television and radio signals are adjusted to a standard level of 60-80 dBpV as standard, this quickly leads to an annoying interference with the received radio and 25 television programs.

The object of the present invention is to provide a telecommunication system and a connection device of the type mentioned in the preamble, which enables shared use of a connection of a telecommunication network 30, while at least largely solving the above-described problems.

1010769 -4-

In order to achieve the intended object, a connection device of the type mentioned in the preamble according to the invention has the feature that the connection device to the input and the output comprises separate signal paths which are coupled to the common connection for the telecommunications connection by means of separating means and that the separating means are able to route the first telecommunication signal at least almost exclusively over a first signal path between the output and the common terminal and the second telecommunication signal at least almost exclusively over a second signal path between the common terminal and the input. The invention is based on the insight that mutual interference and also the influx of noise into the network can be reduced by an effective separation of the signal paths for the downstream and upstream communication traffic by the user. In the connection device according to the invention this means that upstream signal traffic, which will come from the second communication means, is guided entirely over the second signal path, while the downstream signal traffic, intended for the first communication means, finds its way via the first signal path. The two traffic flows are thus shielded from each other so that mutual interference is prevented.

A special embodiment of the connecting device according to the invention is characterized in that the separating means comprise frequency filtering means capable of routing both telecommunication signals over their respective signal paths. By allowing traffic in both directions in the network to proceed strictly in different frequency domains, such separating means can relatively easily provide the intended separation of both signal paths. More in particular, such a special embodiment according to the invention is characterized in that the frequency filter means comprise a low-pass filter with a limit value above a lowest of the first and second frequency domain and a high-pass filter with a limit value below a highest of the first and second domain. frequency domain. The upstream traffic, including the second communication signal, preferably takes place in the 1010769-5 lowest frequency domain, while for the downstream traffic, such as the first communication signal, the higher frequency domain is allocated. The lower frequency bands will still be available in many existing cable television networks for return traffic, so that upstream traffic can take place therein. An additional advantage is the lower signal attenuation at lower frequencies, so that less or less powerful amplifiers have to be included in the return path of the network.

The strict separation of both signal paths in the connection device according to the invention also offers an opportunity to strongly reduce the influx of noise and other undesired signals into the network. According to the invention, a preferred embodiment of the connecting device is for this purpose characterized in that the signal path for the first telecommunication means comprises blocking means which are capable of at least largely suppressing signal transport in a direction opposite to that of the first telecommunication signal. Since the blocking means at least largely suppress any upward signal flow in the first signal path, the entry of ingress noise into the network via the first signal path is effectively avoided. Since the desired return traffic from the second communication means takes place completely in the separated second signal path, this is not hindered by the blocking means. In this respect, a specific embodiment of the connecting device according to the invention has the feature that the blocking means comprise an operational amplifier.

25 For interactive services, such as internet, telephony and pay-per-view. a further embodiment of the connection device according to the invention is characterized in that the output is split into a number of outputs, one of which is intended for the second communication means. Using this embodiment, outgoing signals from the second communication means will be strictly on the second signal path, while incoming signals are strictly on the first signal path. This offers the second communication means the possibility of 1010769-6 two-way traffic while retaining the advantages of the invention. Sending information takes place in the second frequency domain, while information in the first frequency domain is received. Thus, thanks to the invention, full-duplex two-way traffic is possible without annoying interference from the incoming and outgoing signals. Since usually more information will be received than sent, it is preferable to choose the first frequency domain higher than the second in view of the larger bandwidth in that higher domain. In a further preferred embodiment, the connection device according to the invention further has the feature that at least the output for the second communication means is electrically insulated for direct current. An electrical decoupling of the second communication means is thus achieved in the case of direct current components in the signal which is supplied thereto via the said connection. In that case, any span from the network or from the first communication means does not bother the second communication means. This is particularly important if the first communication means comprise an older type of television receiver, the chassis of which, where appropriate, is at a high voltage. In that case, if the network connection in the television receiver is not adequately grounded, in this preferred embodiment it is nevertheless avoided that said high voltage has adverse consequences for the second means of communication.

In order to make possible, among other things, contemporary but also future telecommunication services, a telecommunication system of the type mentioned in the preamble according to the invention has the feature that the first and second telecommunication means are coupled to the telecommunication network by means of a connecting device according to the invention described above. The telecommunication network can in principle be any existing or future network, but in a special embodiment according to the invention comprises a cable television network, intended for distribution of radio and / or television programs, wherein the first telecommunication means comprise a radio receiver and / or a television receiver.

1010769 -7-

As mentioned above, such a network usually offers a particularly high-quality infrastructure that allows large data flows and is subject to little distortion.

A special embodiment of the telecommunication system according to the invention is characterized in that the second communication means comprise conversion means which are coupled on the one hand to an input and an output of the connection device and on the other hand to digital third telecommunication means. The conversion means are capable of converting digital signals from the third communication means to a communication signal compatible with the telecommunications network and vice versa. This makes it possible to include digital third-party telecommunication means in the telecommunication system, although the network would not directly allow this, for example because it is analog or uses different signal frequencies. Examples of such digital communication means are computers, digital telephone devices and various devices intended for many forms of telemetry and remote control.

It is generally desirable to be able to use commercially available communication means in a telecommunication system without having to modify the telecommunication means. As a result, the system 20 can be used more universally and the chance of malfunctions in the equipment to be connected is smaller. In view of this, a special embodiment of the telecommunication system according to the invention has the feature that a port unit is coupled between the third communication means and the conversion means and that the port unit has, on the one hand, a connection, optionally in combination with an interface 25, specifically adapted to the type of third communication means and, on the other hand, is suitable for communication with the conversion means. In that case, the gate unit provides any necessary adjustments between the third communication means on the one hand and the conversion means on the other and also provides a standard connection for the third communication means. The third communication means therefore generally do not themselves require any further modification to be included in the system.

1010769 -8-

A further special embodiment of the telecommunication system is characterized in this respect in that the gate unit is suitable for connecting third communication means from a group comprising a computer, whether or not coupled into a computer network, a device for non-digital telephony and a device for communication about a standardized serial RS 232 connection. In its most extensive form, the port unit has all these connections and any interfaces required for this, so that a wide variety of standard telecommunications equipment can be directly connected. In order to save specific interfaces, a further embodiment is already characterized in that the gate unit 10 is able to communicate with the conversion means according to a telecommunication protocol which allows integration of different telecommunication services, whereby the signals of different types of telecommunication equipment, where appropriate, without the intervention of a specific interface can be passed through the gate unit to the conversion means.

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According to the invention, a further embodiment is characterized in that the third telecommunication means are coupled to a local digital telecommunication network, which further telecommunication network is coupled to the input and output of the connection device through the conversion means.

The addition of this digital network makes digital protocols possible therein; and provide digital telecommunications services that may not be supported by the primary network. The conversion means ensures the requirement: conversion between both networks. A hybrid telecommunication system is thus achieved, which is based on the one hand on a primary network with a high-quality infrastructure in which, thanks to the invention, two-way signal traffic is possible, and on the other hand, a local network that supports the various telecommunication services required by the user.

The invention will be explained in more detail below with reference to an exemplary embodiment and an accompanying drawing. In the drawing: 1010769-9 Figure 1 shows a schematic representation of a telecommunication system according to an embodiment of the invention; and figure 2 shows a schematic representation of an embodiment of a connection device according to the invention, as used in the telecommunication system of figure 1.

Corresponding parts are indicated in the figures with the same reference numerals for the sake of clarity.

The telecommunication system of Figure 1 comprises an existing cable television network 1 10 primarily intended for the transmission and distribution of radio and television programs. First communication means in the form of a radio receiver 11 and a television receiver 12 are coupled to the network. To this end, the subscriber has a central, common connection 2 for the network 1, from which a specific combination connection 3 for radio and television has been branched off. Such a network is usually designed for distribution of signals in discrete frequency bands typically in the range of 5 MHz - 862 MHz, and the radio and television receiver are therefore capable of receiving a first telecommunication signal in a frequency domain within these limits. For example, the domain of 87.5-108 MHz is occupied for distribution of radio programs, while for television programs the domain of 115-862 MHz is allocated.

The area below 87.5 MHz is therefore still free and is increasingly being used to provide return traffic therein, i.e. signal traffic from the subscriber to higher parts of the network. In that case, the subscriber will also have communication means, such as the conversion means 21, decoder 34, computers 31, digital telephone sets 32 and / or analog telephone sets 33 shown in the figure, which are capable of sending a second telecommunication signal, the return signal, in this second frequency domain. The possibility of return traffic thus opens the way to many interactive telecommunication services over the network 1, but also presents the risk of noise and other disturbance penetrating from the subscriber into the network, commonly referred to as ingress noise. In addition, a return signal generated at the subscriber may interfere with the first telecommunications signal for the receiving equipment if both are presented to that equipment.

To avoid all this, the receiving, first communication means 11,12 and the transmitting communication means 21,31,32,33,34 according to the invention are via a connecting device 40 according to the invention, which is shown in more detail in figure 2. displayed. The connection device 40 comprises a common connection 41 for connection to the network 1, an output 42 for the receiving first communication means 11, 12 and an input 43 for any present, sending second communication means 21. According to the invention, the connection device 40 comprises the output 42 and the input 43 separate signal paths 44 and 45, respectively, which are coupled to the common connection by means of separating means 460. The separating means 460 comprises a high-pass filter 461 whereby the first communication signal is passed exclusively over the first signal path 44 in combination with a low-pass filter 462 which forces the second communication signal over the second signal path 45. In this case, both filters are integrated into a single component, referred to as a diplex filter, of greater than -60 dB, but this is not essential per se.

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Because both signals strictly follow their own signal path, interference between the two is effectively prevented. This means, inter alia, that a return signal which continues its way from the input 43 via the second signal path 45 cannot appear at an output 42 of the connecting device to which receiving devices 11, 12 are coupled. The output power of the second communication means can therefore be increased within reasonable limits without any risk of interference to radio and television programs, which are after all offered strictly to the radio and television receiver via the first signal path 44. Thus, the output power of the transmitting communication means can be freely optimized to obtain a high quality output signal without compromising the quality of the signal received by the receiving communication means.

1010769 -11-

The separation of the two signal paths 44, 45 in the connection unit 40 such that for the analog signal traffic downstream only the first signal path 44 is used and the digital signal traffic upstream in the network only goes through the second signal path 45, offers the possibility to enter the first signal path 5 to provide blocking means 46 to suppress any traffic in the first signal path 44 in the opposite direction. The advantage of this is that any noise generated by the user, referred to as ingress noise, no longer has a chance to penetrate network 1 via this signal path 44. In this example, an operational amplifier is used for the blocking means with an attenuation of more than -70 dB, which has proved amply sufficient in practice to suppress an important part of ingress nois in the network 1. The return path 45, on the other hand, including the filter 460, has an attenuation of only -1 dB, so that return traffic on this side is still possible. The use of an operational amplifier 46 as blocking means has the additional advantage that its amplification factor, which here is approximately 6 dB, compensates for the attenuation of approximately -5.6 dB resulting from the splitter 48 which outputs 42. of the establishment into three branches. Thus, the user has three terminals 42, 42 ', 42 ”at his disposal to extract signal traffic downstream from network I. At least one of these terminals 42 ”is insulated for direct current because a capacitor 49 is included in the signal path there. This connection is in particular intended for high-quality, often (high) voltage-sensitive equipment which is thus electrically insulated from the other equipment which is coupled to another output 42, 42 of the unit 40, such as, for example, the first communication means 11, 12. The connection 42 ”thus offers protection against any overvoltage and poor earthing of these other equipment. Such a shielding also applies to the input 43 of the device, because a capacitor 49 is also included in the second signal path 45.

Secondly, communication means 21 are coupled to the thus protected input 43 and output 42 ”of unit 40, which in this example comprise conversion means in the form of a modulator-demodulator unit, briefly referred to as 1010769-12 modem, which is specifically suitable for a cable television network, such as network 1 of this example. The modem is capable of converting digital signals from the connected equipment into signals suitable for transport in the network 1 and vice versa. To receive signal traffic from the network 1, which takes place in the first frequency domain, the modem 21 has an input 211 which is coupled for this purpose to the output 42 'of the unit 40, while an output 212 returns traffic in the a second frequency domain is presented and is fed via the input 43 of the connection unit 40 over the designated signal path 45. The modem is able to apply a specific modulation frequency for both routes, tuned to the separating means 460 in the connection unit 40. On the other side, the modem 21 has a combined digital input / output 213 for connection of digital, third communication means, such as the computers 31, telephones 32, 33 and decoder 34 shown in this example.

In this example, the connection of these third communication means 31..34 is effected through the intermediary of a gate unit 50. This gate unit has connections on the one hand, whether or not in combination with necessary interfaces 51.54, adapted to the specific type of third communication means, and on the other hand common port 55 for communication with the modem 21. As such, the port unit 50 in this example has a network connection 51 in combination with a usual network interface for a further telecommunications network 30 (LAN) of computers 31, a DECT connection 52 in combination with a DECT interface for connection of digital handsets 32 of cordless telephones based on the DECT protocol, a connection 53 with 25 built-in analog / digital converter interface for conventional analog telephones 33 and a standard RS 232 interface for, for example, telemetry applications, in which in this case the decoder 34 is headed pin. The decoder 34 hereby communicates digitally via the RS 232 of the gate unit 50 with the network 1 for the exchange of key and verification information and, on the other hand, outputs analog program data from the network 1 in a conventional manner and for this purpose is directly connected to an output 42 of the connection unit.

1010769 -13-

Internally, if necessary, the signals from all this equipment are converted into a common protocol, for which the Internet Protocol (EP) has been chosen in this example, which in itself already supports the integration of various telecommunication services. Based on this protocol, the port unit and modem 21 communicate with each other. Thus, the third communication means 31 ..34 need not be adapted for use in combination with the modem 21 and the network 1 and, conversely, in the network 1 it is hardly necessary to take into account the type of equipment 31 ..34 which will be used by the bailiff. The connection unit 40, the modem 21 and the port unit 50 each take care of a number of necessary conversions or adjustments for this purpose.

Incidentally, the Internet Protocol is also supported in the computer network 30, which strikes both data transport and telephone traffic, so that telephone traffic is also possible instead of via a dedicated input of the gate unit 50.

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The invention thus provides a particularly universally applicable solution for connecting all kinds of telecommunications equipment to a common connection 2 of a telecommunications network 1, whereby a high quality of the reception as well as transmission signals can be realized, mutual interference is excluded as much as possible and intrusion. of noise from the user in the network is significantly suppressed.

Although the invention has been further elucidated above on the basis of only a single example, it will be clear that the invention is by no means limited to the given example. On the contrary, many variations are within the scope of the invention for an average skilled person and manifestations possible. Thus, the gate unit can be expanded or contained as desired, depending on the diversity of the equipment to be connected thereto. In addition, the invention has been described in more detail on the basis of a cable television network and is therefore particularly usable for this, but can nevertheless also be used for other types of networks, whereby thanks to the invention an adequate separation is always possible. between upstream and downstream signal traffic to the user, so that both do not interfere with each other.

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Claims (16)

1. Connection device for coupling to a common telecommunication connection first telecommunication means capable of receiving a first telecommunication signal in a first frequency domain as well as of second telecommunication means capable of transmitting a second telecommunication signal in a second frequency domain, comprising an output for the first telecommunication means, an input for the second telecommunication means and a common connection for the telecommunication connection, characterized in that the connection device to the input and the output comprises separate signal paths which are coupled to the common connection for the telecommunication connection by means of separating means and that the separating means be able to connect the first telecommunication signal at least substantially exclusively to the first 15 signal path between the output and the common terminal and the second The telecommunication signal at least almost exclusively agrees to route a second signal path between the common connection and the input. 2. Connection device according to claim 1, characterized in that the separating means comprise frequency filtering means capable of routing both telecommunication signals over their respective signal paths. Connection device according to claim 2, characterized in that the frequency filter means comprise a low-pass filter with a limit value above a lowest of the first and second frequency domain and a high-pass filter with a limit value below a highest of the first and second frequency domain. Connection device according to one or more of the preceding claims, characterized in that the signal path for the first telecommunication means 30 includes blocking means capable of counteracting signal transport in a direction opposite to that of the first telecommunication signal. 1010769 -16- Connecting device according to claim 4, characterized in that the blocking means comprise an operational amplifier. 6. Connection device according to one or more of the preceding claims, characterized in that the output is split into a number of outputs, one of which is intended for the second communication means. Connection device according to claim 6, characterized in that at least the output for the second communication means is electrically insulated for direct current. 10 8. Telecommunication system comprising first telecommunication means capable of receiving a first telecommunication signal in a first frequency domain, second telecommunication means intended for transmitting a second telecommunication signal in a second frequency domain and a telecommunication network characterized in that the first and second telecommunication means intervene of the connecting device according to one or more of the preceding claims, are coupled to the telecommunication network. 9. Telecommunication system according to claim 8, characterized in that the telecommunication network comprises a cable television network, intended for distribution of radio and / or television programs and that the first telecommunication means comprise a radio receiver and / or a television receiver. 10. Telecommunication system according to claim 8 or 9, characterized in that the second communication means comprise conversion means which are coupled to an input and an output of the connection device and in that digital third telecommunication means are coupled to the conversion means. 11. Telecommunication system according to claim 10, characterized in that the third communication means are coupled to the 1010759-17 conversion means through the intermediary of a gate unit and that the gate unit has an interface adapted to the type of third communication means. 12. Telecommunication system according to claim 11, characterized in that the port unit is suitable for connection of third communication means from a group comprising a computer, whether or not linked in a computer network, a device for non-digital telephony and a device for communication over a standardized serial RS 232 connection. Telecommunication system according to claim 11 or 12, characterized in that the gate unit is capable of communicating the conversion means according to a telecommunication protocol which allows integration of different telecommunication services. Telecommunication system according to claim 10, 11, 12 or 13, characterized in that the third telecommunication means are coupled to a digital further telecommunication network, which further telecommunication network is coupled to the input and output of the connection device by means of the conversion means. 20 Telecommunication system according to claim 14, characterized in that the further telecommunication network supports various telecommunication services in an integrated manner. Telecommunication system according to claim 15, characterized in that both data traffic and telephone traffic are possible over the further telecommunication network. 1010769