WO2005122477A1 - Method for the broadband transmission, complementary to xdsl technology, of return channel data in a connection between a server of a packet switching network and a terminal thereon - Google Patents

Abstract

The invention relates to a method for the broadband transmission, complementary to xDSL-technology, of return channel data in a connection between a server of a packet switching network and a terminal thereon which is connected to the packet switching network by xDSL technology. Return channel data is transmitted from the server (4) to a broadband return channel access switch (5), from said access switch (5) via the packet switching network (3) to an xDSL-connection node (31) of the terminal (1) on the packet switching network (3) and subsequently from the xDSL-connection node (31) to the terminal (1) by means of xDSL-data transmission technology. An examination is repeated on the switch (5) in order to establish whether a control signal, which is triggered by the user of the terminal (1) or a management system, in order to complement or alternatively use a broadband return channel until the terminal (1) in order to transmit return channel data, is present. If a control signal is present, an exchange occurs on the transmission via the broadband return channel, or a connection is established on a broadband return channel, whereby the return channel data is transmitted, in broadband, on the broadband return channel to the terminal (1). If another corresponding control signal of the user or the management system is present, a reverse exchange takes place on a transmission of the return channel data only via the packet switching network and the xDSL connection.

Description

 Method for the broadband transmission of return channel data supplementing xDS technology in a connection between a server of a packet switching network and a terminal thereon

description

The invention relates to a method for xDSL technology-supplementary broadband transmission of return channel data in a connection between a server of a packet switching network and a terminal thereon, which is connected to the packet switching network using xDΞ technology.

Background of the Invention

From DE 196 45 368 AI a method for the transmission of digital data in a telecommunications network is known, in which, when a control signal is present, there is a change between a packet-switched and a circuit-switched data transmission during an existing connection.

EP 0 998 093 B1 describes a method for the transmission of return channel data in a connection between a terminal and a server of a packet switching network, in which at least on a portion of the return channel, data transmission is either narrowband over the packet switching network and / or POTS / ISDN lines and / or broadband via a broadband return channel. In one embodiment, the broadband return channel is provided by a satellite transmission link. The bandwidth of the narrowband data transmission is in the Usually limited by the low bandwidth of the POTS / ISDM connection of the terminal to the packet switching network.

In this document, the acronym "xDSL" (DSL = digital subscriber line = digital subscriber line) denotes all transmission techniques for digital data - both via telephone lines made of two-wire copper cables and via other physical media (such as TV cables, DVB-T lines or further terrestrial or satellite-based radio links) - for data transmission between the computer of a user of a packet switching network and this

Packet switching network (preferably the Internet), with the exception of ISDN technology and the conventional analog modem technology

(for example, according to the V series of ITU recommendations) for telephone lines made of two-wire copper cables.

The most common form of xDSL. Technology is the aDSL technology (asymmetric digital subscriber line) on the physical medium "copper telephone pair": It is asymmetrical in the sense that it has a fast receive and a slower transmit channel for this data transmission Another common form of telephone wire-bound xDSL technology is sDSL technology (symmetric digital subscriber line): Here there is a symmetrical, equally fast design of the receive and transmit channel. With telephone wire xDSL technology, transmission rates in megabits / s are preferred Range is possible, eg the bandwidth provided on an aDSL connection for receiving data from the end system is usually around 0.8 Mbit / s to 3 Mbit / s.

Object of the invention

The present invention is based on the object of providing a method for xDSL-supplementary broadband transmission of return channel data in a connection between a terminal and a server of a packet switching network to be provided, which, depending on the requirements of a management system and / or a user, provides a high degree of flexibility in setting the bandwidth with which the return channel data is transmitted to a terminal connected to the packet switching network via an xDSL connection.

Summary of the invention

This object is achieved according to the invention by a method with the features of claim 1. Preferred embodiments of the invention are specified in the subclaims.

According to this, the method according to the invention is characterized in that the return channel data to be transmitted to the terminal device first of all from the server of the packet switching network to a switch, namely a broadband return channel access switch, from this access switch via a packet switching network to an xDSL connection node of the terminal device

Packet switching network and then transmitted from this to the terminal using xDSL data transmission technology. The bandwidth of this transmission is largely determined by the bandwidth of the xDSL connection of the terminal to the packet switching network.

In this switch it is checked whether one generated by the user of the terminal and / or a management system

Control signal for the additional or alternative use of a broadband return channel up to the terminal for transmitting the return channel data is present. If such a control signal is present, there is a change to transmission via a broadband return channel, or alternatively a broadband return channel is switched on. The switching or switching on is preferably carried out immediately, in particular in the sub-millisecond time grid. The return channel data is then first transmitted in broadband from the server to the access switch, from Access switch given to the broadband return channel and broadband transmission to the end device. The transmission over the broadband return channel takes place outside the packet switching network and via an independent telecommunications network.

If there is a corresponding further control signal from the user or the management system, the switch back to a transmission of the return channel data takes place solely via the packet switching network and the xDSL connection.

The solution according to the invention is thus characterized in that, depending on the requirements of a management system and / or a user of an existing xDSL connection, a broadband return channel is connected up to the terminal or, alternatively, a switch is made to such a broadband return channel as far as the terminal. When a broadband return channel is switched on, data transmission takes place within a time interval under consideration both via the previous connection via the packet switching network and the xDSL connection and also via the broadband return channel. This increases the total return channel bandwidth. In general, other data or data packets are transmitted via the broadband return channel than via the xDSL connection.

In the event of a change to a data transmission via a broadband return channel, only a data transmission via the broadband return channel takes place within a period under consideration and generally no longer at the same time a data transmission via the packet switching network and the xDSL connection. In general, it will make more sense to connect a broadband return channel to the end device, i.e. to keep the xDSL connection and continue to use it for data transmission, so that the summed bandwidth of both transmission channels is used. The acronym "xDSL" (DSL = digital subscriber line = digital subscriber line) in the sense of the present invention denotes all transmission techniques for digital data - both via telephone lines made of two-wire copper cables and via other physical media (such as TV cables, DVB-T). Routes or other terrestrial or satellite-based radio links) - for data transmission between the computer of a user of a packet switching network and this packet switching network (preferably the Internet), with the exception of ISDN technology and the commercially available analog modem technology (e.g. according to the V series of ITU recommendations ) for telephone lines made of two-wire copper cables.

Other variants of xDSL technology to be understood in this way are, for example: • unidirectional digital data transmission technologies from the user computer to the packet switching network (more precisely: to one of its servers) on any physical medium, • non-obvious variants of the standardized xDSL technologies on copper wire pairs such as the "inverse" use of aDSL technology (with fast transmission and slower reception channel) on the route between the user computer and server, and • all types of xDSL techniques on physical media other than copper telephone wire pairs on such a route. • Any series connection of such xDSL data transmission sections.

The invention makes it possible, if required, to provide a terminal which is connected to a packet switching network via an xDSL connection with a substantially greater bandwidth than is possible with xDSL techniques. An xDS connection is currently generally regarded as broadband. However, the bandwidth of an xDSL connection with its average bandwidth far below 9 Mbit / s is not sufficient to meet the bandwidth requirements of the LAN or WLAN Techniques to match that are around 75-100 Mbit / s. The broadband return channel provided according to the invention enables a data rate in this latter area. A "broadband return channel" is therefore considered to be a return channel on which a bandwidth above 128 Kbit / s, preferably from 1 to 75, in particular from 10 to 75 Mbit / s can be requested and possibly also guaranteed.

The switch is preferably a central switch via which a large number of connections between end devices and servers are routed. The switch can be located at any point in the packet switching network and can make all decisions centrally about the provision of broadband return channels to end devices.

The management system, which preferably decides on the possible provision of a broadband return channel to the terminal, is preferably integrated in the switch itself as internal network management. The integration of the management system in the switch has the advantage that the switch provides the decision-making authority as to whether a broadband return channel to the terminal is provided or not. The switch or its management system can thus operate autonomously and quickly. As a rule, decisions are made about the transmission of return channel data over a broadband return channel in the sub-millisecond range.

Alternatively, the network management can also be an external network management.

The management system is preferably network management in that it utilizes the broadband telecommunications infrastructure; monitored and their

Controls utilization as optimally as possible. If, for example, what is in a preferred embodiment of the invention If it can be the case that the broadband return channel is implemented via a satellite transmission link, the management system ensures optimum utilization of the transponder (s) used and their “spot beams” of the satellite (s) of the satellite transmission link (s). Broadband transmission via an additional broadband return channel to the end device is only provided to the extent that the proceeds from this transmission and the capacities and costs of the transponder (s) used justify and allow this.

In any case, switching to a transmission via broadband return channel or switching on a broadband return channel can take place, for example, within an internet session of the terminal. A session (e.g. internet session) is defined as the period between the login of the end device with its service provider (e.g.: Internet service provider, ISP) and its logout. A large number of applications (= applications) can be executed during a session. Applications differ from each other through the protocols they use, such as the IETF-compliant (IETF = Internet Engineering Task Force) http (hypertext transport protocol) and ftp (file transfer protocol) or the proprietary protocols for "streaming applications". It is possible that the broadband - Return channel for the transmission of

Return channel data that is used by a specific application to the terminal, while return channel data from another application is transmitted to the terminal via the packet switching network and the xDSL connection.

In the preferred embodiment of the invention, however, a switch to a transmission via broadband return channel or a connection of a broadband return channel takes place within or during an application. In other words, a broadband return channel is switched on or switched to one during the use of an application. For example, part of one is sent to the terminal transmitted amount of data of an application over the packet switching network and the xDSL connection to the terminal, while another part of this amount of data is transmitted over the broadband return channel.

An application in turn consists of a layer 7 connection (layer 7 alias L7 connection) according to the OSI reference model - but only if it only involves a single original application context. However, if it involves several original application contexts, it can also use several L7 connections. The use of several original application contexts in a single person-to-person communication process is well known.

The construction of a WWW page on the screen of a device can therefore involve a large number of L7 connections: firstly because the screen shows the status of very different applications under user control (with their respective L7 connections), and secondly because each such application has different ones original application contexts (with their respective L7 connections) and thirdly because server-controlled / -tolerated non-original application contexts (with their respective L7 connections, eg advertising ads) can be integrated into each such application. In a further embodiment of the invention, a broadband return channel can be switched on or switched to such a broadband return channel even during each such L7 connection - literally at any time.

It is pointed out that the activation of a broadband return channel, the switching to a broadband return channel and the possible switching back (to a transmission solely via the packet switching network and the xDSL connection) are transparent to the user. The considered application (s) or their current L7 connection (s) will not be affected by these switches affected. A broadband return channel is switched on / off on deeper layers of the OSI reference model, namely on OSI layers 1-4. In particular, Internet protocol pairs such as IP / UDP or IP / TCP both essentially represent protocols for communication processes on the OSI layers 1-4.

In other words, the invention enables a user and / or a management system, while using an application, in particular during an existing L7 connection within such an application, the currently practiced data transmission via the packet switching network and the xDSL connection (overall: Ll / 4 connection) to supplement a data transmission via broadband return channel (also Ll / 4 connection) or to switch to such a broadband connection. Such an L1 / L4 broadband return channel can be switched on and off dynamically. It is thus possible to dynamically change the quality of service available for data transmission and to adapt it to requirements. This is done in a way that is transparent to the user.

The switch is preferably a proxy server or the switch is integrated in a proxy server. As already mentioned, the proxy server can be arranged at any point in the packet switching network or can have access to the packet switching network at one point. The broadband return channel provided by the switch to the end device is unidirectional and takes place directly to the end device insofar as it does not have to access the infrastructure of the packet switching network or the xDSL data transmission technology to the end device or other potentially potentially bandwidth-limiting telecommunications components. Rather, the broadband return channel is provided outside the packet switching network and the xDSL data transmission technology and is free of incalculable bandwidth restrictions right up to the terminal. The broadband return channel is preferably implemented by a satellite transmission link. The return channel data is transmitted broadband from the switch to a satellite uplink, sent from the satellite uplink to a satellite transponder, broadcast by the transponder, received by a terrestrial antenna of the user and transmitted to the terminal. The data can be received, for example, by means of a satellite dish directly assigned to the terminal or the LAN (to which it belongs).

It is also possible to receive the data or data packets broadcast by the transponder by means of a TV cable head station of a TV cable network operator and to enter them into the corresponding cable network. The data packets are then received by the end device via the TV cable. The TV cable can also be used to implement xDSL data transmission technology.

The broadband return channel data transmitted by the transponder can also be directed to the receiving antenna of a DVB-T service provider. The data packets are then received on the terminal in accordance with the DVB-T channel.

Finally, the broadband return channel data transmitted by the transponder can also be sent to the receiving antenna

WLAN and / or radio network and / or electricity network service providers are routed. The data packets are then received on the terminal in accordance with the respective protocols.

In all cases, the data packets are preferably identified on the basis of their address fields as being intended for the terminal. For example, the data sent contains the IP address of the terminal in the connection under consideration or the MAC address of the terminal.

As an alternative to the satellite data transmission link, the broadband return channel is used in whole or in part, for example by means of a dedicated (glass fiber) cable, the channel of a television cable of a television cable network, a channel of a DVB-T system, a power cable of a power network, a broadband radio link (in particular roughly in accordance with the UMTS standard, Universal Mobile Telecommunications System, or the WLAN standards)). For this purpose, suitable dedicated (glass fiber) cable technology, television cable technology, power network technology and radio technology for data transmission are used for the connection between the switch and the end user, which are known per se to the person skilled in the art.

Description of several preferred exemplary embodiments

The invention will be explained in more detail below with reference to the figures of the drawing using several exemplary embodiments. Show it:

1 schematically shows a telecommunications network which serves the xDSL-supplementary broadband transmission of return channel data between a terminal and a server of a packet switching network; and

Fig. 2 in detail the xDΞLi connection of the terminal of Figure 1 to the packet switching network.

FIG. 1 shows a communication system in which a terminal 1 is connected to a long-distance packet network 3 via an xDSL connection shown in detail in FIG. 2, which can in particular be the Internet. Furthermore, the terminal 1 is connected, for example via an Ethernet connection, to a broadband reception system 2 which receives data transmitted by a transponder via a satellite antenna 91, 92. The broadband reception system 2 is designed, for example, as a PC card or as an external PC or TV box.

The satellite antenna is in particular a conventional satellite dish 91 or the receiving station 92 of a satellite communal antenna system. Provision can also be made for the data sent by the transponder to be received by a head station, fed into a broadband network (for example a television cable network or a WLAN or a radio cell or a power network) and via the broadband network corresponding to this head station are transmitted to the broadband reception system 2.

It is pointed out that the term “end device” stands for any communication end system. The "end device" can be, for example, a PC, but it can also be a line or packet-switching PBX that serves a LAN (such as an internal company network) or something similar.

The xDSL connection of the terminal 1 to the packet switching network 3 is shown by way of example in FIG. 2 - other forms of the xDSL connection are also useful. Here, the terminal 1 is connected to a telephone line (TAL) via an xDSL modem 101 and a splitter 102. The splitter 102 ensures that xDSL data arriving at the terminal are separated from telephone signals. Telephone signals are supplied, for example, to a user telephone, not shown in the figure.

With xDSL technology, the subscriber connection instructions (TAL) can be implemented as a pair of telephone copper cables. In this case, another splitter 103, which is assigned to a main distributor, in turn, separates the xDSL data arriving at it from the telephone signals. The latter are fed to a conventional switching center 108 of a telephone network and from there are further transmitted via the I SDN / POTS network. POTS stands for "Piain Old Telephonie System", the conventional and partially analog telephone network. ISDN stands for "Integrated Services Digital Network", the continuously digital network. In the example in FIG. 2, the xDSL data are fed to a DSLAM (Digital Subscriber Line Access Multiplexer) 104 and from there routed to a concentrator network 106. Concentrator network 106 is a

Broadband network, for example an ATM broadband network.

The broadband network 106 can be connected to the packet switching network 3 via a plurality of xDSL access points 31, also referred to as xDSL connection nodes 31 (cf. also FIG. 1), only one access point 31 being shown in FIG. 2. The access point 31 of FIG. 1 thus abstracts from the details of FIG. 2 and includes all of its components.

Numerous servers 4 are connected to the packet switching network, also referred to as host computers or application servers 4, between which the user of a terminal 1 can "surf". In doing so, it retrieves data from a server 4 for its terminal 1. A user "browses" using a commercially available browser installed on his / her end device 1 between the individual servers 4 of the

Packet switching network, two return channels being available for this data retrieval according to the invention.

On the one hand, the return channel data is transmitted to

Terminal 1 in a manner known per se via the

Packet switching network 3 and the xDSL connection to it. On the other hand, the data to be downloaded are transmitted in broadband from the server 4 to a broadband access switch 5 and from there with a high bandwidth via a satellite 8 to the terminal. For this purpose, the return channel data is transmitted from the switch 5 to a satellite uplink 6, sent from the satellite uplink 6 via a satellite transmission antenna 7 to a satellite transponder 8, broadcast by the latter and via the satellite reception antenna 91 assigned to the terminal 1 , 92 received broadband. In FIG. 1, the data streams are represented by arrows drawn in bold. Depending on the decision of the user concerned and the management system at this time, the bandwidth of the return channel transmission via satellite can be significantly larger or smaller than the return channel bandwidth via the packet switching network and its xDSL connection.

The decision of whether the return channel routing from the switch takes place via satellite 8 or via the Internet 3 is made by the user of the terminal 1 and / or a network management. For this purpose, the broadband access switch 5 has a control device which, depending on the control signals of the terminal 1 and / or the network management, transmits the return channel data either to the packet switching network 3 or to the satellite uplink 6.

Overall, the communication between the terminal and the server preferably proceeds as follows. First, the terminal 1 establishes an xDSL connection to the dial-in node 31, which provides it with access to the packet switching network 3. In a further method step, this L7 connection is expanded from the terminal 1 to the server 4. This L7 connection is preferably set up with the interposition of the broadband return channel access switch 5, which in turn is broadband connected to the satellite uplink 6. Data from the terminal 1 to the server 4 and from the server 4 to the terminal 1 are preferably always routed with the interposition of the switch 5.

After the L7 connection has been set up, the data of the return channel are preferably first transmitted to the terminal 1 via the packet switching network 3 and the xDSL connection. The switch 5 checks at regular intervals (approximately every 1 millisecond or less) whether a one generated by the user of the terminal 1 and / or a management system Control signal for changing the return channel to a return channel via satellite or for connecting a return channel via satellite to the existing return channel is present. If the control signal is generated by the management system, it is preferably integrated in the broadband return channel access switch 5 - it is then generated in the broadband return channel access switch 5 itself.

As soon as the switch 5 finds a corresponding control signal, it changes - preferably immediately, ie during the existing application and L7 connection - to a broadband return channel via the satellite 8. The switch 5 thus serves as a control unit. To switch to a broadband return channel, the switch 5 sends the data in broadband to the satellite uplink 6, to which it is connected, for example, via a glass fiber cable. The data is then transmitted from the satellite uplink 6 in broadband via the satellite 8 and the satellite antenna 91, 92 to the terminal 1.

Instead of the usual bandwidth of around 1 Mbit / s of an xDSL connection for bridging the "last mile" from Internet access 31 to the terminal, the return channel data transmission is now carried out with a higher bandwidth, for example on average with 2, 4, 8, 16, 32 or 64 Mbit / s - depending on the wishes of the PC user or headend manager.

If a switch back to transmission via the packet switching network and the xDSL connection is desired, the user or the management system generates a further control signal for the switch 5, which then routes the data to be downloaded again via the Internet 3.

It has already been pointed out that a preferred embodiment of the described method provides for the broadband return channel to be connected to the transmission via the Internet 3 and the xDSL connection without interrupting the transmission via the Internet 3 and the xDSL connection. Different data are transmitted over the Internet than over the broadband return channel. The bandwidth of both return channels is then additionally available for the return channel data transmission.

In particular, it can also be provided that the network management provides a bandwidth regulation device, with the help of which the user of the terminal 1 can set the bandwidth of the data transmission via the satellite 8 to his terminal 1, depending on the load on the transponders of the satellite 8 involved. This enables him to request certain speed or quality of service classes. The change between different bandwidths or quality of service classes can take place dynamically during an existing connection. This makes it possible to change the transmission speed even during a connection.

In order to be able to implement this average bandwidth requested by a PC or headend manager - it is generally significantly reduced compared to the total available return channel bandwidth, but is generally significantly higher than the average bandwidth available to all users the bandwidth control device (in cooperation with the network management and the switch) divide the total available transponder bandwidth into channels (following the DVB-S standard, for example) and a PC or headend manager only requests one such sub-channel Provide bandwidth, or he can still operate this PC or headend manager with the full transponder bandwidth, but only send him information packs less frequently, so that he is served on average with this reduced bandwidth. In cooperation with the bandwidth regulation device, the management system has to ensure in particular that the maximum fees of the subscriber do not exceed a predetermined amount in a certain period of time, such as a month.

Claims

Expectations

1. Method for broadband transmission of return channel data supplementing xDSL technology in a connection between a server of a packet switching network and a terminal thereon, which is connected to the packet switching network via xDSL technology, with the following steps: a) transmission of return channel -Data from the server (4) to the terminal (1), the data a. from the server (4) to a switch (5) which is part of the packet switching network (3) or has access to it, b. from the switch (5) via the packet switching network (3) to an xDSL connection node (31) of the terminal (1) to the packet switching network (3), and c. then transmitted from the xDSL connection node (31) to the terminal (1) by means of xDSL data transmission technology, b) repeated checks at the switch (5) whether a control signal triggered by the user of the terminal (1) and / or a management system for the additional or alternative use of a broadband return channel up to the terminal (1) for the transmission of the return channel data, c) switching to a transmission via broadband return channel if a corresponding control signal is present, or switching on a broadband return channel, the Return channel data is first transmitted in broadband from the server (4) to the switch (5) and then transferred from the switch (5) to the broadband return channel and transmitted in broadband to the terminal (1) without the on Broadband return channel given data on their way to the terminal (1) pass through the xDSL connection node (31), d) switching back to a transmission of the return channel data solely via the packet switching network and the xDSL data transmission technology, provided that a corresponding further control signal from the user and / or the management system is present, wherein e) data transmission from the server (4) to the terminal (1) always takes place with the intermediary of the switch (5).

2. The method according to claim 1, wherein the switch (5) is not arranged in an xDSL connection node.

3. The method according to claim 1 or 2, wherein the management system is integrated in the switch (5).

4. The method according to any one of the preceding claims, in which a change to a transmission via broadband return channel or switching on a broadband return channel takes place within a session, in particular within an internet session of the terminal (1).

5. The method of claim 4, wherein switching to a transmission via broadband return channel or switching on a broadband return channel takes place within an application that is executed during the session.

6. The method according to any one of the preceding claims, wherein the switch is a proxy server or is integrated into such.

Method according to one of the preceding claims, in which the packet switching network in packet switching long distance network, especially the internet is.

8. The method according to any one of the preceding claims, in which the return channel data are retained in their format as data packets during transmission over the broadband return channel.

9. The method according to any one of the preceding claims, in which the user or the management system can set the bandwidth of the data transmission taking place over the broadband return channel to the terminal in question.

10. The method of claim 9, wherein an adjustment of the bandwidth of the data transmission via the broadband return channel takes place dynamically during an existing connection between the server and the terminal.

11. The method according to claim 9 or 10, in which the entire available bandwidth of the broadband return channel is divided into channels and the terminal (1) or a terminal upstream of the terminal (1) the maximum bandwidth of such a channel is provided.

12. The method according to claim 9 or 10, wherein a certain bandwidth of the data transmission to the terminal is set by the frequency with which data packets intended for the terminal (1) are given to the broadband return channel.

13. The method according to any one of the preceding claims, in which the broadband return channel is implemented by a satellite transmission link, wherein a transmission of the data from the switch to the terminal via satellite includes the following steps: a) Broadband transmission of the return channel data from the switch (5) to a satellite uplink (6) when the corresponding control signal is present, b) sending the data from the satellite uplink (6) to a satellite (8), c) broadcasting the Data from the satellite (8) and d) receiving the data and transmitting the data to the terminal (1).

14. The method according to claim 13, wherein the terminal (1) evaluates the address fields of the data packets received via satellite in order to recognize the data intended for it.

15. The method according to claim 13 or 14, in which the data transmitted by the satellite (8) are received by means of a satellite dish (91, 92) assigned to the terminal (1) or by means of a satellite network to which the terminal (1) belongs ,

16. The method according to claim 13 or 14, in which the data broadcast from the satellite is received by a cable head station of a cable operator, input into the corresponding cable network and received by cable from the terminal.

17. The method according to claim 13 or 14, in which the data broadcast by the satellite is routed to the receiving antenna of a DVB-T service provider and is received via a DVB-T channel at the terminal (1).

18. The method according to claim 13 or 14, in which the data transmitted by the satellite is routed to the receiving antenna of a WLAN and / or radio network and / or power network service provider and is received on the terminal in accordance with the respective protocols.

19. The method according to any one of claims 1 to 12, wherein the broadband return channel from the switch (5) to the terminal (1) is at least partially realized by a television cable of a television cable network.

20. The method according to any one of claims 1 to 12, wherein the broadband return channel from the switch (5) to the terminal (1) is at least partially realized by a power cable of a power network.

21. The method according to any one of claims 1 to 12, wherein the broadband return channel from the switch (5) to the terminal (1) is at least partially realized by an optical fiber cable of an optical fiber network.

22. The method according to any one of claims 1 to 12, in which the broadband return channel from the switch (5) to the terminal (1) is implemented by a broadband radio link, in particular in accordance with the UMTS or WLAN standard.

23. The method according to any one of claims 1 to 12, wherein the broadband return channel from the switch (5) to the terminal (1) involves a DVB-T data transmission link.

24. The method according to any one of the preceding claims, wherein the xDSL connection between the terminal (1) and the xDSL connection node (31) is an aDSL connection or an sDSL connection.

25. The method according to any one of the preceding claims, in which a connection between the terminal (1) and the server (4) is always established with the interposition of the switch (5), in particular also data from the terminal (1) to the server (4) Interposition of the switch (5) are transmitted.

26. The method according to any one of the preceding claims, in which a change to a transmission via broadband return channel, or alternatively a broadband return channel is switched on, in the presence of a control signal, immediately, in particular in the sub-millisecond time frame.