EP1597881A1 - Data sink/data source data transmission device and data terminal device for a circuit-switched and packet-switched network - Google Patents

Abstract

The aim of the invention is, in a data sink/data source data transmission device and data terminal device for a circuit-switched and packet-switched network, to be able to eliminate the logical separation between applications, which are based on the circuit-switched network, e.g. PSTN, ISDN, and applications, which are based on the packet-switched network, e.g. Internet. To this end, a data transmission device (DUE) for transmitting and receiving data into/from the circuit-switched network (LVN) comprises controllable switch-over means (UMS). This data transmission device is or can be assigned to a universally useable unit (DVG) for automatically processing data and for transmitting and receiving data to/from the packet-switched network and is assigned or can be assigned to the at least one data terminal device (DEE) for transmitting and receiving data into/from the circuit-switched network (LVN). Said switch-over means can be controlled in such a manner that the data terminal device (DEE) which, in a first operating mode is connected to the circuit-switched network (LVN) via the data transmission device (DUE), can be switched from the first operating mode into a second operating mode, during which the data terminal device (DEE) is connected to the packet-switched network (PVN) via the data transmission device (DUE) and the data processing device (DVG), and from the second operating mode into the first operating mode.

Description

description

Data sink / source, data transmission device and data terminal device for a circuit and packet switched network

The present invention relates to a data sink / source for a line and packet-switched network according to the preamble of claim 1, a data transmission device for a line and packet-switched network according to the preamble of claim 25 and a data end device for a line and packet-switched network according to the preamble of claim 44.

Publications on the subject of 'Home Networking ^ or' Connected Home '' or 'Telephony and Control' refer to the networking of private devices such as TVs, personal computers and other everyday devices spoken. The telephone, landline telephone or cordless telephone preferably serves as network access to the circuit-switched network (voice network). Access to the packet-switched network (data network) - e.g. Internet access - is irrelevant and can be done in different ways.

According to FIG. 1, the connection between the packet-switched and circuit-switched network is only available to the extent known, as the devices, for example a personal computer, which are used to transmit packet data via an Ethernet, digital subscriber line (DSL) or cable connection to the packet-switched network, e.g. the Internet, and, for example, cause a cordless base station, which is connected to the circuit-switched network for voice data transmission via an ISDN / PSTN network termination, to establish a connection (control) or to use the device to configure a cordless handset (configuration). Parts of the cordless base station or the telephone functionality are transferred to the personal computer. The control and Configuration can of course also be done in the opposite direction.

It is crucial, however, that no voice data is processed in the packet-switched network or in the data network, but that there is always a logical connection between the voice terminal, the cordless handset, and the switching center, the cordless base station. There is therefore no logical connection between the circuit-switched voice network and the packet-switched data network (e.g. Internet) with regard to voice data. The use of voice services of the packet-switched data network (such as internet telephony, voice messages) is currently not used via the cordless handset registered at the cordless base station.

The object on which the invention is based is to specify a data sink / source, data transmission device and data terminal device for a circuit-switched and packet-switched network which provide the logical separation between applications which are on the circuit-switched network, e.g. PSTN, ISDN, and applications based on the packet switched network, e.g. Internet, based, repeals.

This object is achieved on the basis of the data sink / source defined in the preamble of patent claim 1 by the features specified in the characterizing part of patent claim 1.

In addition, the object is achieved on the basis of the data transmission device defined in the preamble of claim 25 by the features specified in the characterizing part of claim 25.

Furthermore, the object is achieved on the basis of the data terminal device defined in the preamble of patent claim 44 by the features specified in the characterizing part of patent claim 44. The idea on which the invention is based is to provide a data transmission device for transmitting and receiving data, in particular voice and / or packet data, into the circuit-switched or from the circuit-switched network, which is a universally applicable device for automatic processing of data and for transmission and receiving or assigning data to the packet-switched network or from the packet-switched network and which is assigned to the at least one data terminal device for transmitting and receiving data, in particular voice and / or packet data, into the circuit-switched network or from the circuit-switched network or can be assigned to be provided with controllable switching means, which can be controlled in such a way that the data terminal device, which is connected to the circuit-switched network in a first operating mode via the data transmission device, from the first operating mode to a second operating mode, in which the data terminal device, on the one hand, uses the data transmission device and the data processing device are connected to the packet-switched network, can be switched over and vice versa, that is to say an operating mode change takes place.

The invention is the extension of an Datenübertra ^¬ restriction device, for example, according to the claims 19, 20, 21, 40, 41, 42 as a cordless base station formed by a switchover which is 39 preferably implemented by software according to claim 18, so that the voice data streams can be forwarded to a data processing device, which is preferably designed as a personal computer, notebook or server for home and / or for the office, thus enabling new applications. With the data transmission device or cordless base station thus created, there is the possibility of forwarding voice and / or signaling data streams to a data processing device, for example a personal computer, which is networked with the Internet. This enables Internet or personal computer-based voice applications (such as Internet telephony, "voice messaging", etc.) can be used by data end devices operated on the data transmission device.

This means that data terminals, e.g. a cordless handset according to claims 23, 51 or a telephone, a logical connection for voice data in the packet switched network, e.g. can switch to the Internet or to a local data network of the "Home Networking * scenario.

Above all, this increases user friendliness. The applications which are currently possible with a headset operated on the personal computer can also be carried out on a cordless handset on the basis of the invention.

Due to the switchover option according to the invention in the cordless base station, the user can optionally set two operating modes on the cordless handset.

In a first operating mode, the cordless handset works like a normal telephone on the circuit-switched network.

In a second operating mode, the voice and protocol data are sent to the data processing device, e.g. a personal computer, or to the data network. There is no connection to the wired network. In addition, information about user input on the cordless handset is forwarded to the personal computer and display information is sent to the cordless handset from the personal computer. In addition, the voice channels are transparent, switched to the personal computer via a so-called tunnel connection.

As a result, the cordless handset connected to the cordless base station can use an application running on the personal computer, such as a headset, for example. turn. Additional applications can be activated through interaction with the user via display and control data, which further increases user friendliness. For example, "Voice over Internet Protocol" telephony (VoIP telephony) is possible with a conventional cordless telephone (telephony functionality must be made available to all applications in a network (eg personal computers in the home network)). It is also possible, for example, to play online games with the conventional cordless telephone, to implement voice controls in the home network and to operate devices in the home network remotely.

With the invention it is also possible, for example, to integrate conventional cordless telephones in a “connected home” scenario. Here, the personal computer for "VoIP telephony" serves as a "VoIP gateway". Integration into the game consoles, e.g. the X-Box, possible.

Furthermore, the invention offers the possibility to control applications of the data processing device by the data terminal device based on voice control and voice recognition mechanisms (Voice Control and Voice Recognition), to use the data terminal device as a remote control unit, to access the messenger service from To manufacture Microsoft via the data terminal equipment, to implement an Internet radio, to carry out Internet chatting using a cordless handset or telephone, to convert text messages into voice messages ("Text to Speech"), for example E-mails can be read aloud and / or use the display of messages on the display of the data terminal device.

However, the invention is not only applicable for the home area as explained above, if the data transmission device as a cordless base station, the data terminal device as a cordless handset and the data processing device as Personal computers or servers are designed, but is also readily available for the public sector if the data transmission device is designed as a cellular mobile radio infrastructure consisting of a base station and central switching system, the data terminal device is designed as a mobile radio telephone (cell phone) and the data processing device is configured as a server. applicable.

Further advantageous developments of the invention can be found in the remaining subclaims and the following description of an embodiment of the invention.

The exemplary embodiment of the invention is described with reference to FIGS. 2 to 4. Show it:

FIGURE 2 shows a first data sink / source for a circuit and packet switched network consisting of a data terminal device, a data transmission device and a data processing device,

FIGURE 3, starting from FIGURE 2, a second data sink / source for a circuit and packet-switched network consisting of a data terminal device and a data processing / data transmission device,

FIGURE 4 Realization of the first data sink / source with a cordless telephone and a personal computer.

FIGURE 2 shows a first data sink / source DSQ1 for a line-switched network LVN, which is preferably in the form of a “Public Switched Telephone Network (PSTN)” or “Integrated Services Digital Network (ISDN)”, and a packet-switched network PVN, which is preferably in the form of an Internet from a data terminal DEE, a data transmission device DUE and a data processing device DVG. The data terminal device DEE contains a first central control unit ZSE1, control means STM and a first terminal device / transmission device interface EUSS1. The first central control unit ZSE1 is used to control the functional sequences in the data terminal device DEE and is connected both to the control means STM and to the first terminal device / transmission device interface EUSS1. Via the first terminal device / transmission device interface EÜSS1, the data terminal device DEE is connected to the data transmission device DÜE, which has a second terminal device / transmission device interface EÜSS2 for this connection. Either a first line connection LV1 or a first free space connection FRV1 is provided as the connection between the data terminal device DEE and the data transmission device DÜE.

In addition to the second terminal device / transmission device interface part EÜSS2, the data transmission device DÜE also contains a second central control unit ZSE2, a first network / transmission device interface NUSS1, first switching means USM1 and a first device / transmission device interface GÜSS1. The second central control unit ZSE2, which serves to control the functional sequences in the data transmission device DÜE and has first switchover control means USSM1, is equipped with the second terminal device / transmission device interface EUSS2, the first network / transmission device interface NUSS1 and the first device / transmission device interface GÜSS1 connected. The first changeover control means USSM1 of the second central control unit ZSE2 form a functional unit with the first changeover means USM1 such that the changeover control means USSM1 control the changeover means USM1, which is shown in FIGURE 2 by the connection between the two means. The data transmission device DÜE is on the one hand via the first network / transmission device interface NUSSL with the circuit-switched network LVN and on the other hand via the first device / transmission device interface GÜSS1 connected to the data processing device DVG, which has a second device / transmission device interface GÜSS2 for this connection. Either a second line connection LV2 or a second free space connection FRV2 is again provided as the connection between the data transmission device DÜE and the data processing device DVG.

In addition to the second device / transmission device interface GÜSS2, the data processing device DVG also contains a third central control unit ZSE3 and a first network / device interface NGSS1. The third central control unit ZSE3, which is used to control the functional sequences in the data processing device DVG and, in addition to the first switching control means USSM1 of the second central control unit ZSE2 in the data transmission device DUE, optionally has dashed second switching control means USSM2 in FIG connected to the second device / transmission device interface GÜSS2 and the first network / device interface NGSSl. About the first

Network / device interface NGSS1, the data processing device DVG is connected to the packet-switched network PVN.

In the following, based on the explanation of the structure of the first data sink / source DSQ1, the functioning of the data sink / source DSQl with a view to eliminating the logical separation between first applications based on the circuit-switched network LVN and second applications, which are based on the packet-switched PVN network.

From the point of view of the data terminal DEE, which has previously been connected to the circuit-switched network LVN via the first line connection LV1 or the first free space connection FRV1 and the data transmission device DÜE (see cordless base station as data transmission device and cordless handset as data terminal device in FIGURE 1), this means that the user of the data terminal device DEE can use services of the circuit-switched network LVN on the one hand and services of the packet-switched network PVN on the one hand as addressees and senders, respectively. In other words, the transmission path from the data terminal device DEE to the circuit-switched network LVN and packet-switched network PVN must be available to the user, that is, the user must be able to change it if necessary (change of operating mode of the data terminal device). For example, in a first operating mode, the data terminal device DEE is connected to the circuit-switched network LVN via the data transmission device DUE and in a second operating mode via the data transmission device DUE and the data processing device DVG to the packet-switched network PVN.

Because of the already existing connection between the data terminal device DEE and the data transmission device DUE for the known scenario specified (data terminal device <- circuit-switched network), the first switching means USM1 and the first switching control means USSM1, m in the data processing device DVG are possibly in the data transmission device DUE for this purpose the second switchover control means USSM2 and the control means STM are present in the data terminal device DEE. Apart from the control means STM in the data terminal device DEE, which are preferably designed as a keyboard, all of the above means are preferably designed as program modules (software). Instead of the keyboard, it is also possible to use voice control.

For any other conceivable scenario, however, the distribution of the funds mentioned can be different, for example. For example, in a scenario (data terminal device - packet-switched network), if the data terminal device is connected to the packet-switched network, for example, via a line connection or a free space connection and the data processing device that is. In this case, the switching means and the switching control means are preferably in the data processing device, while additional switching control means may be present in the data transmission device.

Alternatively, a configuration is also conceivable in which the data transmission device is connected to the packet-switched network and the data processing device is connected to the circuit-switched network.

For the scenario on which FIGURE 2 is based (data terminal device <-> circuit-switched network), in which the first switching means USM1 are present in the data transmission device DÜE, depending on whether

(i) only the first switching control means USSM1 in the data transmission device DÜE,

(ii) both the first changeover control means USSM1 in the data transmission device DÜE and the second changeover control means USSM2 in the data processing device DVG, both changeover control means USSM1, USSM2 controlling the first changeover means USM1 in the data transmission device DÜE, (iii) both the first changeover control means USSMl in of the data transmission device DÜE and also the second switchover control means USSM2 in the data processing device DVG, however, in contrast to (ii) only the first switchover control means USSM1 control the first switchover means USM1 in the data transmission device DÜE, three variants, based on the scenario of the change of operating mode in the first data sink / source DSQl can be realized.

Realization variant (i):

For the description of this implementation variant, it is now assumed that the data terminal device DEE, for example, se is in the first operating mode, according to which the data terminal device DEE is connected to the circuit-switched network LVN via the data transmission device DUE. Of course, the other case is also possible in which the data terminal device DEE is in the second operating mode.

The user of the data terminal device DEE now wanted to switch to the second operating mode. The aforementioned change in operating mode is initiated by the user of the data terminal device DEE by actuating the control means STM. Thereupon, the first central control unit ZSE1 controls a first signal S1 for signaling the change in operating mode from the data terminal device DEE via the first line connection LV1 or the first free space connection FRV1 to the second terminal device via this and the first terminal device / transmission device interface EUSS1 - / Transfer device interface EUSS2 in the data transmission device DUE, which forwards the first signal S1 transmitted by the data terminal device DEE to the first switching control means USSM1.

The first switching control means USSM1 then generate a second signal S2, which they transmit to the data processing device DVG and there, in particular, to the third central control unit ZSE3 and with which the data processing device DVG is informed that the data terminal DEE has a connection to the packet-switched network via the data processing device DVG To build PVN. After the data processing device DVG has been informed, the first switching control means USSM1 generate a third signal S3 and transmit this to the first switching means USM1. With the transmission of the third signal S3, the first switching means USM1 are instructed to resolve the transmission path to the circuit-switched network LVN previously used by the data terminal device DEE and instead to use the data processing device DVG to transmit a new transmission path to the packet-switched network. set up PVN network. In FIGURE 2, this process is indicated in the first switching means USM1 by the switch symbol. The data terminal DEE is thus connected to the packet-switched network PVN via the second line connection LV2 or the second free space connection FRV2 and the data processing device DVG. This transmission path belonging to the second operating mode now remains switched or set up until a renewed change of operating mode, this time a change from the second operating mode to the first operating mode, is initiated by the user.

In order to inform the user of the data terminal device in which operating mode the data terminal device is, the respective activated operating mode is preferably shown on a display of the data terminal device (cf. FIG. 4). Furthermore, it is possible to prioritize the connection to the circuit-switched network in the case of data terminal devices which are primarily used for voice transmission (telephony) (cf. FIG. 4) and with which a "Voice over IP" connection is not yet possible the packet-switched network. This can e.g. can be achieved by a time-controlled default setting. This means that if an operating mode change from the first operating mode to the second operating mode has been carried out as described and the data terminal device is not reset within a predetermined time after the end of a session in the second operating mode, the reset to the original state (default state) takes place automatically.

Realization variant (ii):

For the description of this implementation variant, it is again assumed that the data terminal DEE is, for example, in the first operating mode, according to which the data terminal DEE uses the data transmission DÜE direction is connected to the LVN circuit-switched network. Of course, the other case is also possible in which the data terminal device DEE is in the second operating mode.

The user of the data terminal device DEE now wants to switch to the second operating mode or the first operating mode. The respective change of operating mode is initiated by the user of the data terminal device DEE by actuating the control means STM. For each change this can e.g. always be the same key or softkey key or different keys can be used for both operating mode changes. With voice control, however, the matter is clear, because the spoken change of operating mode is always implemented.

Thereupon, a fourth signal S4 is controlled by the first central control unit ZSE1 via this and the first terminal device / transmission device interface EUSS1 for signaling the change in operating mode from the data terminal device DEE via the first line connection LV1 or the first free space connection FRV1 to the second terminal device - / Transmission device interface EÜSS2 transmitted in the data transmission device DÜE, via which the fourth signal S4 transmitted by the data terminal device DEE in

In the event of a change to the second operating mode (the current operating mode is therefore the first operating mode) is forwarded to the first switching control means USSM1 and in the event of a change to the first operating mode (the current operating mode is therefore the second operating mode) via the first device / Transmission device interface GÜSS1, the second line connection LV2 or the second free space connection FRV2 and the second device / transmission device interface GÜSS2 are forwarded in the order mentioned to the second switching control means USSM2 in the data processing device DVG. The first and second changeover control means USSM1, USSM2 receiving the fourth signal S4 then each generate a fifth signal S5 with which the other changeover control means USSM2, USSMl are informed of the respective change in operating mode. The fifth signal S5 is transmitted via the first device / transmission device interface GÜSS1, the second line connection LV2 or the second free space connection FRV2 and the second device / transmission device interface GÜSS2 or in the opposite direction to the relevant switching control means USSM2, USSM1. After the relevant switching control means USSM2, USSM1 and thus the data processing device DVG or the data transmission device DÜE have been informed of the change in operating mode, the first and second switching control means USSM1, USSM2 receiving the fourth signal S4 each generate a sixth signal S6 and transmit this to the first Switching device USM1. In the case of a change to the second operating mode, the first switching control means USSM1 generate the sixth signal S6, while in the case of a change to the first operating mode the second switching control means USSM2 generate the sixth signal S6. With the transmission of the sixth signal S6, the first switching means USM1 are instructed to dissolve the transmission path previously used by the data terminal device DEE to the circuit-switched network LVN or packet-switched network PVN and instead a new transmission path via the data processing device DVG to the packet-switched network PVN or via to set up the data transmission device DÜE to the circuit-switched network LVN. In FIGURE 2, this process is again indicated in the first switching means USM1 by the switch symbol. The data terminal device DEE is thus connected to the packet-switched network PVN via the second line connection LV2 or the second free space connection FRV2 and the data processing device DVG or to the line-switched network LVN via the data transmission device DÜE. This transmission path belonging to the second operating mode or to the first operating mode now remains switched or set up for a long time until a new change of operating mode, this time a change from the second operating mode to the first operating mode or from the first operating mode to the second operating mode, is initiated by the user.

In order to inform the user of the operating mode in which the data terminal device is located, the respective activated operating mode is again preferably shown on a display of the data terminal device DEE (see FIG. 4). Furthermore, it is also possible again to prioritize the connection to the circuit-switched connection in the case of data end devices which are primarily used for voice transmission (telephony) (cf. FIG. 4) and with which a "Voice over IP" connection is not yet possible Network compared to the packet-switched network. This can e.g. can be achieved by a time-controlled default setting. This means that if an operating mode change from the first operating mode to the second operating mode or from the second operating mode to the first operating mode has been carried out as described and the data terminal device does not return after a session in the second operating mode or in the first operating mode within a predetermined time is reset, the reset process to the original state (default state) takes place automatically.

Realization variant (iii):

For a description of this implementation variant is now assumed again, the data terminal DEE that for example is in the first operating mode, the data is the terminal DEE on Datenubertragungsein ^¬ direction DCE to the circuit-switched network LVN connected under. Of course, the other case is also possible in which the data terminal device DEE is in the second operating mode. The user of the data terminal device DEE now wants to switch to the second operating mode or the first operating mode. The respective change of operating mode is initiated by the user of the data terminal device DEE by actuating the control means STM. For each change, this can always be the same key or softkey key, for example, or different keys can be used for both operating mode changes. With voice control, however, the matter is clear, because the spoken change of operating mode is always implemented.

Then the fourth central control unit ZSE1 controls the fourth signal S4 to signal the change of operating mode from the data terminal device DEE via the first line connection LV1 or the first free space connection FRV1 to the second line via this and the first terminal device / transmission device interface EUSS1 - Device / transmission device interface EÜSS2 transmitted in the data transmission device DÜE, via which the fourth signal S4 transmitted by the data terminal device DEE in the event of a change to the second operating mode (the current operating mode is therefore the first operating mode) is again forwarded to the first switching control means USSM1 and in In the event of a change to the first operating mode (the current operating mode is therefore the second operating mode) again via the first device / transmission device interface GÜSS1, the second line connection LV2 or the second Freira rerouting FRV2 and the second device / transmission device interface GÜSS2 in the order mentioned is forwarded again to the second switching control means USSM2 in the data processing device DVG.

The first changeover control means USSM1 receiving the fourth signal S4 then generate a seventh signal S7, with which they inform the second changeover control means USSM2 of the change in operating mode signaled to them. The seventh signal S7 is transmitted via the first device / transmission transmission device interface GÜSS1, the second line connection LV2 or the second free space connection FRV2 and the second device / transmission device interface GÜSS2 to the second switching control means USSM2. After the second switchover control means USSM2 and thus the data processing device DVG have been informed of the change in operating mode, the second switchover control means USSM2 receiving the seventh signal S7 generate an eighth signal S8 and transmit this via the second device / transmission device interface GUSS2, the second line connection LV2 or the second free space connection FRV2 and the first device / transmission device interface GÜSS1 in the order mentioned to the first switching control means USSMl. With this eighth signal S8, the second changeover control means USSM2 signal the first changeover control means USSM1 that they signal the changeover from the second operating mode to the first operating mode and should therefore control the first changeover means USM1. The first switching control means USSM1 then generate a ninth signal S9 and transmit this to the first switching means USM1. With the transmission of the ninth signal S9, the first switching means USM1 are instructed to dissolve the transmission path previously used by the data terminal device DEE to the circuit-switched network LVN or packet-switched network PVN and instead a new transmission path via the data processing device DVG to the packet-switched network PVN or via the data transmission device DÜE to set up the circuit-switched network LVN. In FIGURE 2, this process is again indicated in the first switching means USM1 by the switch symbol. The data terminal device DEE is thus connected via the second line connection LV2 or the second free space connection FRV2 and the data processing device DVG to the packet-switched network PVN or via the data transmission device DÜE to the line-switched network LVN. This transmission path belonging to the second operating mode or to the first operating mode now remains switched or set up until in the same way Another change of operating mode, this time a change from the second operating mode to the first operating mode or from the first operating mode to the second operating mode, is initiated by the user.

In order to inform the user of the operating mode in which the data terminal device is located, the respective activated operating mode is again preferably shown on a display of the data terminal device DEE (see FIG. 4). Furthermore, it is also possible again to prioritize the connection to the circuit-switched connection in the case of data end devices which are primarily used for voice transmission (telephony) (cf. FIG. 4) and with which a "Voice over IP" connection is not yet possible Network compared to the packet-switched network. This can e.g. can be achieved by a time-controlled default setting. This means that if an operating mode change from the first operating mode to the second operating mode or from the second operating mode to the first operating mode has been carried out as described and the data terminal device does not return after a session in the second operating mode or in the first operating mode within a predetermined time is reset, the reset to the original state (default state) takes place automatically.

In the case of the implementation variants (i), (ii) and (iii) presented, it is advantageous if the change in operating mode signaled with the signals S2, S5, S7, S8 is confirmed by the switchover control means receiving these signals with a tenth signal S10 before the change of operating mode is carried out by the first switching means USM1.

FIGURE 3 shows a second data sink / source DSQ2 for a line-switched network LVN, which is preferably designed as a "Public Switched Telephone Network (PSTN)" or "Integrated Services Digital Network (ISDN)" and a preferably as Internet-based packet-switched network PVN consisting of a data terminal device DEE and a data processing / data transmission device DVÜG. The data processing device DVÜG shown in FIG. 2 and the data transmission device DÜE shown in FIG. 2 are combined in the data processing / data transmission device DVÜG to form a structural and functional unit.

The data terminal device DEE contains the first central control unit ZSE1, the control means STM and the first device / transmission device interface EUSS1. The first central control unit ZSE1 is used to control the functional sequences in the data terminal device DEE and is connected both to the control means STM and to the first terminal device / transmission device interface EUSS1. Via the first terminal device / transmission device interface EÜSS1, the data terminal device DEE is connected to the data processing / data transmission device DVÜG, which has a third terminal device / transmission device interface EÜSS3 for this connection. Either the first line connection LV1 or the first free space connection FRV1 is again provided as the connection between the data terminal device DEE and the data processing / data transmission device DVÜG.

In addition to the third terminal device / transmission device interface EÜSS3, the data processing / data transmission device DVÜG also contains a fourth central control unit ZSE4, a second network / transmission device interface NUSS2, second switching means USM2 and a second network

/ Device interface NGSS2. The fourth central control unit ZSE4, which is used to control the functional sequences in the data processing / data transmission device DVÜG and has third switchover control means USSM3, is connected to the third terminal device / transmission device interface EUSS3, the second network / transmission device interface NUSS2 and the second network. / NGSS2 device interface connected. The third changeover control means USSM3 of the fourth central control unit ZSE4 form a functional unit with the second changeover means USM2 such that the changeover control means USSM3 control the changeover means USM1, which is shown in FIG. 3 by the connection between the two means. The data processing / data transmission device DVÜG is connected on the one hand via the second network / transmission device interface NUSS2 to the circuit-switched network LVN and on the other hand via the second network / device interface parts NGSS2 to the packet-switched network PVN.

In the following, based on the explanation of the structure of the second data sink / source DSQ2, the mode of operation of the data sink / source DSQ2 with a view to eliminating the logical separation between first applications based on the circuit-switched network LVN and second applications based on based on the packet-switched network PVN.

For the scenario shown in FIG. 3, it is now assumed that the data terminal device DEE is, for example, in the first operating mode, according to which the data terminal device DEE is connected to the circuit-switched network LVN via the data processing / data transmission device DVÜG. Of course, the other case is also possible in which the data terminal device DEE is in the second operating mode.

'The user of the data terminal device DEE now wants to switch to the second operating mode. The mentioned change of operating mode is initiated by the user of the data terminal device DEE by actuating the control means STM. Thereupon an eleventh signal Sll is controlled by the first central control unit ZSE1 via this and the first terminal device / transmission device interface EUSS1 to signal the change of operating mode from the Data terminal device DEE via the first line connection LV1 or the first free space connection FRV1 to the third terminal device / transmission device interface EÜSS3 m to the data processing / data transmission device DVUG, which transmits the eleventh transmitted by the data terminal device DEE

Signal Sll forwards to the third switching control means USSM3.

The third switchover control means USSM3 then generate a twelfth signal S12 and transmit this to the second switchover means USM2. With the transmission of the twelfth signal S12, the second switching means USM2 are instructed to resolve the transmission path previously used by the data terminal device DEE to the circuit-switched network LVN and instead to set up a new transmission path to the packet-switched network PVN. In FIGURE 3, this process is indicated in the second switching means USM2 by the switch symbol. The data terminal device DEE is thus connected to the packet-switched network PVN. This transmission path belonging to the second operating mode now remains switched or set up until a new change of operating mode, this time a change from the second operating mode to the first operating mode, is initiated by the user.

In order to inform the user of the data terminal device of the operating mode in which the data terminal device is located, the respective activated operating mode is preferably shown on a display of the data terminal device (cf. FIG. 4). Furthermore, it is possible to prioritize the connection to the circuit-switched network in the case of data end configurations which are primarily used for voice transmission (telephony) (cf. FIG. 4) and with which a "Voice over IP" connection is not yet possible the packet-switched network. This can be achieved, for example, by a time-controlled default setting. This means that if there is an operating mode change from the first drive mode for the second operating mode has been carried out as described and the data terminal device is not reset within a predetermined time after the end of a session in the second operating mode, the reset to the original state (default state) takes place automatically.

FIGURE 4 shows the implementation of the first data sink / source DSQ1 in FIGURE 2 in accordance with implementation variant (i) with a cordless telephone SLT as the data terminal device and data transmission device, which is connected to the circuit-switched network LVN, and a personal computer PC as the data processing device with is connected to the packet-switched network PVN. The personal computer PC has a screen next to BSC (monitor), an input device EV consisting of a keyboard TA and a "mouse" MA, on a Sys ^¬ temeinheit SYE, known from FIGURE 2 facilities. In addition to the third central control unit ZSE3, the system unit SYE also includes the second device / transmission device interface GÜSS2, which is designed as a USB interface (Universal Serial Bus), and the second is an Ethernet, DSL interface (Digital Subscriber Line) first network / device interface NGSSl arranged. The personal computer PC is connected to the cordless telephone SLT via a USB connection USBV, LV2 as the second line connection. The cordless telephone SLT has a cordless base station SLB as the data transmission device and a cordless mobile part SLM as the data terminal device, which are connected to one another via a radio connection FRV1 as the first free space connection. In addition to a display device AE (display), an input unit EGE designed as a keyboard and input means EGM consisting of a microphone and an earphone, the cordless mobile part SLM has the first central control unit ZSE1 and a first radio interface EÜSS1 as the first terminal device / transmission device interface. The display device AE, the input unit EGE and the input means EGM form the elements shown in FIG. provided control means STM. In the cordless base station SLB are the second central control unit ZSE2 with the first switching control means USSM1, the first switching means USM1, a second radio interface EÜSS2 designed as a second terminal device / transmission device interface, a line interface NUSS1 and a further USB interface GÜSS1 designed as a first device / transmission device interface is arranged. The connection to the circuit-switched network LVN is established via the line connection NUSS1 and the USB interface GUSS1 is connected via the USB connection USBV, LV2 to the USB interface GUSS2 arranged in the personal computer PC.

If the cordless base station SLB is integrated into the personal computer PC as a cordless data adapter, the second data sink / source DSQ2 according to FIG. 3 is obtained.

Claims

claims

1. Data sink / source for a circuit and packet-switched network, with a) a data transmission device (DUE) for transmitting and receiving data, in particular voice and / or packet data, m the circuit-switched or from the circuit-switched network (LVN), which can be connected to the circuit-switched network (LVN), b) a universally usable device (DVG) for automatic processing of data and for sending and receiving data m the packet-switched or from the packet-switched network (PVN), which connects the packet-switched network ( PVN) can be assigned and to which the data transmission device (DUE) is assigned, c) at least one data terminal device (DEE) for sending and receiving data, in particular voice and / or packet data, xxi the circuit-switched or from the circuit-switched network (LVN), that is assigned to the data transmission device (DUE), characterized in that d) in the data transmission device (DUE, DVUG) switching means (USM1, USM2) v that are controllable in such a way that the data terminal device (DEE), which in a first operating mode is connected to the circuit-switched network (LVN) via the data transmission device (DÜE), from the first operating mode m a second operating mode in which the data terminal device ( DEE) is connected to the packet-switched network (PVN) via the data transmission device (DUE) and the data processing device (DVG), is switchable and vice versa.

2. Data sink / source according to claim 1, characterized in that the data terminal device (DEE) control means (STM) and for controlling the functional sequence m of the data terminal device (DEE) has a first central control unit (ZSEl) which are connected to one another and are designed such that the switching means (USM) can be controlled.

3. Data sink / source according to claim 2, characterized in that the control means (STM) are designed as a key on the keyboard of the data terminal device (DEE) or as a softkey key or by a voice control implemented in the data terminal device (DEE).

4. Data sink / source according to claim 2, characterized in that first switching control means (USSMl) are present in the data transmission device (DÜE), which with first switching means (USMl), the control means (STM) and the first central control unit (ZSEl ) form a functional unit, the functional unit being designed in such a way that a) the control means (STM) signal a change of operating mode (Sl) to the first switching control means (USSML) via the first central control unit (ZSE1), b) the first switching control means (USSML) ) signal the operating mode change to the data processing device (DVG) (S2), c) control the first switching control means (USSMl) the first switching means (USMl) for the signaled operating mode change (S3).

5. Data sink / source according to claim 2, characterized in that there are first switchover control means (USSM1) in the data transmission device (DÜE) and second switchover control means (USSM2) in the data processing device (DVG), which are provided with first switchover means (USMl), form the control means (STM) and the first central control unit (ZSEl) a functional unit, the functional unit being such that a) the control means (STM), when the data terminal device (DEE) is currently in the first operating mode, via the first central control unit (ZSEl) signal the first switching control means (USSMl) in the data transmission device (DÜE) an operating mode change or when the data terminal device (DEE) is currently in the second operating mode, via the first central control unit (ZSEl) the second changeover control means (USSM2) in the data processing device (DVG) signal an operating mode change (S4), b) the changeover control means (USSMl, USSM2) the other Changeover control means (USSM2, USSMl) signal the change of operating mode (S5), c) the first changeover control means (USSMl) in the data transmission device (DÜE) signal the first changeover means

(USMl) for the operating mode change from the first operating mode to the second operating mode and the second switching control means (USSM2) in the data processing device (DVG) control the first switching means (USMl) for the operating mode change from the second operating mode to the first operating mode (S6).

6. Data sink / source according to claim 2, characterized in that first switching control means (USSMl) in the data transmission device (DÜE) and second switching control means

(USSM2) are present in the data processing device (DVG), which form a functional unit with the first switchover means (USMl), the control means (STM) and the first central control unit (ZSEl), the functional unit being such that a) the control means ( STM), when the data terminal device (DEE) is currently in the first operating mode, via the first central control unit (ZSEl) to the first switching control means (USSMl) in the data transmission device (DÜE) to signal an operating mode change or when the data terminal device (DEE) is currently in the second operating mode is via the first central control unit (ZSEl) signal the second changeover control means (USSM2) in the data processing device (DVG) an operating mode change (S4), b) the first changeover control means (USSMl) in the data transmission device (DUE) to the second changeover control means (USSM2) in the data processing device (DVG) signal the operating mode change (S7), c) signal the second changeover control means (USSM2) in the data processing device (DVG) to the first changeover control means (USSMl) in the data transmission device (DCE) to control the change in operating mode from the second operating mode to the first operating mode (S8), d) the first switchover control means (USSMl) in the data transmission device (DUE) control the first switchover means (USMl) for the respective operating mode change (S9).

7. Data sink / source according to claim 4, 5 or 6, characterized in that the functional unit is designed in such a way that the signaled change of operating mode must be confirmed by the first switching control means (USSMl) from the opposite side before the operating mode change by the first switching means ( USM) is carried out (SlO).

8. Data sink / source according to claim 1, characterized in that the data terminal device (DEE) and the data transmission device (DUE) are connected via a first line connection (LV1).

9. Data sink / source according to claim 1, characterized in that the data terminal device (DEE) and the data transmission device (DUE) are connected via a first free space connection (FRV1).

10. Data sink / source according to claim 1, characterized in that the data terminal device (DEE) is integrated to form a structural unit in the data transmission device (DÜE).

11. Data sink / source according to claim 1, characterized in that the data transmission device (DUE) is assigned to the data processing device (DVG) via a second line connection (LV2).

12. Data sink / source according to claim 1, characterized in that the data transmission device (DÜE) is assigned to the data processing device (DVG) via a second free space connection (FRV2).

13. Data sink / source according to claim 1, characterized in that the data transmission device (DUE) is integrated into the data processing device (DVG) to form a structural, functional unit m designed as a data processing / data transmission device (DVUG).

14. Data sink / source according to claim 13, characterized in that the data processing / data transmission device (DVUG) is designed as a set-top box, notebook or personal computer,

15. Data sink / source according to claim 13 or 14, characterized in that third switching control means (USSM3) are present in the data processing / data transmission device (DVUG), which with second switching means (USM2) m the data processing / data transmission device (DVUG ), the control means (STM) and the first central control unit (ZSEl) a functional Form unit, the functional unit being such that a) the control means (STM) signal the third changeover control means (USSM3) an operating mode change, b) the third changeover control means (USSM3) control the second changeover means (USM2) for the signaled operating mode change.

16. Data sink / source according to claim 1, characterized in that the data processing device (DVG) is contained in the packet-switched network (PVN) - preferably on the Internet, in the LAN, in the WAN - and the data transmission device (DÜE) via a tunnel connection Data processing device (DVG) is assigned.

17. Data sink / source according to one of claims 1 to 16, characterized in that the first switching control means (USSMl) in a second central control unit (ZSE2) for controlling the functional sequences in the data transmission device (DÜE), the second switching control means (USSM2) in a third central control unit (ZSE3) for controlling the functional processes in the data processing device (DVG) and the third switching control means (USSM3) in a fourth central control unit (ZSE4) for controlling the functional processes in the data processing / data transmission device (DVÜG) are.

18. Data sink / source according to one of claims 1 to 17, characterized in that the switching means (USMl, USM2) and the switching control means (USSMl, USSM2, USSM3) are designed as software modules.

19. Data sink / source according to claims 9 and 11, characterized in that the data transmission device (DUE) is designed as a cordless base station and connected to the data processing device (DVG) via the second line connection (LV2)

20. Data sink / source according to claim 19, characterized in that the second line connection (LV2) is a "Universal Serial Bus" connection (USBV).

21. Data sink / source according to claims 9 and 12, characterized in that the data transmission device (DUE) is designed as a cordless base station and the data processing device (DVG) is assigned a cordless module designed for cordless transmission with the cordless base station.

22. Data sink / source according to claims 12 and 13, characterized in that the data processing / data transmission device (DVUG) is designed as a data processing device with an integrated cordless data adapter.

23. Data sink / source according to claim 9, characterized in that the data terminal device (DEE) is designed as a cordless mobile part.

24. Data sink / source according to one of claims 1 to 23, characterized in that the data processing device (DVG) is designed as a personal computer, notebook or server for home and / or for the office

25. Data transmission device, in particular voice and / or packet data, for a circuit and packet-switched network, a) which can be connected to the circuit-switched or from the circuit-switched network (LVN) for sending and receiving data, in particular voice and / or packet data, b) the one universal device (DVG) for automatic processing of data and for sending and receiving data in the packet-switched or from the packet-switched network (PVN) can be assigned, wherein the data processing device (DVG) can be assigned to the packet-switched network (PVN), c) the at least one data terminal device (DEE) for sending and receiving of data, in particular voice and / or packet data, can be assigned to the circuit-switched or from the circuit-switched network (LVN), characterized in that d) switching means (USM1, USM2) are present which can be controlled in such a way that the data terminal device ( DEE), which is connected to the circuit-switched network (LVN) in a first operating mode via the data transmission device (DÜE), from the first operating mode in a second operating mode in which the data terminal device (DEE) is connected to the packet-switched network (PVN) via the data transmission device (DÜE) and the data processing device (DVG), and can be switched over and vice versa.

26. Data transmission device according to claim 25, characterized in that there are first switchover control means (USSMl) which form a functional unit with first switchover means (USMl), control means (STM) and a first central control unit (ZSEl) in the data terminal device (DEE) , the functional unit being such that a) the first switchover control means (USSMl) is signaled by the control means (STM) and the first central control unit (ZSEl) an operating mode change (S1), b) the first switchover control means (USSMl) to the data processing device ( DVG) signal the change of operating mode (S2), c) the first switchover control means (USSMl) control the first switchover means (USMl) for the signaled operating mode change (S3).

27. Data transmission device according to claim 25, characterized in that there are first switchover control means (USSMl) which are connected to second switchover control means (USSM2) in the data processing device (DVG), first switchover means (USMl), control means (STM) and a first central control unit

(ZSEl) form a functional unit in the data terminal device (DEE), the functional unit being designed in such a way that a) the first switchover control means (USSMl) from the control means (STM) and the first central control unit

(ZSEl) when the data terminal device (DEE) is currently in the first operating mode ^ an operating mode change is signaled (S4), b) the first switching control means (USSM1) signal the second switching control means (USSM2) the operating mode change (S5), c) the first Switching control means (USSM1) is signaled by the second switching control means (USSM2) an operating mode change (S5) when the data terminal device (DEE) is currently in the second operating mode and the second switching control means (USSM2) in the data processing device (DVG) an operating mode change from the control means ( STM) and the first central control unit (ZSEl) is signaled. d) the first switching control means (USSMl) control the first switching means (USMl) for the operating mode change from the first operating mode to the second operating mode (S6).

28. Data transmission device according to claim 25, characterized in that there are first switchover control means (USSM1) which are connected to second switchover control means (USSM2) in the data Work device (DVG), first switching means (USMl), control means (STM) and a first central control unit (ZSEl) in the data terminal device (DEE) form a functional unit, the functional unit being such that a) the first switching control means (USSML) from the control means (STM) and the first central control unit (ZSEl), when the data terminal device (DEE) is currently in the first operating mode, an operating mode change is signaled (S4), b) the first switching control means (USSMl) the second switching control means (USSM2 ) in the data processing device (DVG) the operation mode switching signal (S7), c) is signaled to the first switchover (USSMl) of the two-th switchover (facility USSM2) in the Datenverarbeitungsgerat (DVG), an operation mode Wech ^¬ sel when the Data terminal device (DEE) is currently in the second operating mode and the second switching control means (USSM2 ) in the data processing device (DVG) an operating mode change is signaled by the control means (STM) and the first central control unit (ZSEl) to control (S8) from the second operating mode to the first operating mode, d) the first changeover control means (USSMl) the first change - Control switching means (USMl) for the respective operating mode change (S9).

29. Data transmission device according to claim 26, 27 or 28, characterized in that the functional unit is designed such that the signaled change of operating mode is confirmed by the first switching control means (USSMl) from the opposite side, before the operating mode change is carried out by the first switching means (USMl) becomes (SlO).

30th Data transmission device according to claim 25, characterized in that the s a first line connection (LV1) is present, via which the data transmission device (DÜE) is connected to the data terminal device (DEE).

31. Data transmission device according to claim 25, characterized in that a first free space connection (FRV1) is present, via which the data transmission device (DÜE) is connected to the data terminal device (DEE).

32. Data transmission device according to claim 25, characterized in that the data terminal device (DEE) is integrated into the data transmission device (DÜE) to form a structural, functional unit.

33. Data transmission device according to claim 25, characterized in that a second line connection (LV2) is present, via which the data transmission device (DÜE) is assigned to the data processing device (DVG).

34. Data transmission device according to claim 25, characterized in that a second free space connection (FRV2) is present, via which the data transmission device (DÜE) is assigned to the data processing device (DVG).

35. Data transmission device according to claim 25, characterized in that it is integrated into the data processing device (DVG) to form a structural unit designed as a data processing / data transmission device (DVÜG).

36. Data transmission device according to claim 35, characterized in that the data processing / data transmission device (DVÜG) is designed as a set-top box, notebook or personal computer.

37. Data transmission device according to claim 35, characterized in that third changeover control means (USSM3) are present in the data processing / data transmission device (DVÜG), the second changeover means (USM2) in the data processing / data transmission device (DVÜG), control means (STM ) and a first central control unit (ZSEl) in the data terminal device (DEE) form a functional unit, the functional unit being designed such that a) the third switching control means (USSM3) from the control means (STM) and the first central control unit (ZSEl) Operating mode change is signaled, b) the third switching control means (USSM3) control the second switching means (USM2) for the signaled operating mode change.

38, data transmission device according to one of claims 25 to 37, characterized in that for controlling the functional sequences in the data transmission device (DÜE) a second central controller (ZSE2) is present, in which the first switching control means (USSMl) are contained.

39. Data transmission device according to one of claims 25 to 38, characterized in that the switching means (USMl, USM2) and the switching control means (USSMl, USSM2, USSM3) are designed as software modules.

40. Data transmission device according to claims 31 and 33, characterized in that the data transmission device (DÜE) is designed as a cordless base station and via the second line connection dung (LV2) connected to the data processing device (DVG)

41. Data transmission device according to claim 40, characterized in that the second line connection (LV2) is a "Universal Serial Bus" connection (USBV).

42. Data transmission device according to claims 31 and 34, characterized in that the data transmission device (DUE) is designed as a cordless base station and a cordless module designed for cordless transmission with the cordless base station is assigned to the data processing device (DVG).

43. Data transmission device according to claims 34 and 35, characterized in that the data processing / data transmission device (DVUG) is designed as a data processing device with an integrated cordless data adapter.

44.Data terminal equipment, in particular of voice and / or packet data, for a circuit and packet-switched network which is used to send and receive data, in particular voice and / or packet data, into the circuit-switched or from the circuit-switched network (LVN) Data transmission device (DUE) for sending and receiving data, in particular voice and / or packet data, can be assigned to the circuit-switched or from the circuit-switched network (LVN), the data transmission device (DUE) being connectable to the circuit-switched network (LVN) and one universally applicable device (DVG) for automatic processing of data and for sending and receiving data in the packet-switched or from the packet-switched network (PVN) can be assigned, which in turn can be assigned to the packet-switched network (PVN)

characterized in that Control means (STM) and for controlling the functional sequences in the data terminal device (DEE) has a first central control unit (ZSEl), which are connected to each other and with which switching means (USMl, USM2) of the data transmission device (DÜE, DVÜG) can be controlled in this way, that the data terminal device (DEE), which is connected to the circuit-switched network (LVN) in a first operating mode via the data transmission device (DÜE), from the first operating mode to a second operating mode in which the data terminal device (DEE) via the data transmission device ( DÜE) and the data processing device (DVG) is connected to the packet-switched network (PVN), can be switched and vice versa.

45. Data terminal device according to claim 44, characterized in that the control means (STM) are designed as a key on the keyboard of the data terminal device (DEE) or as a softkey key or by a voice control implemented in the data terminal device (DEE) ,

46. Data terminal device according to claim 44 or 45, characterized in that the control means (STM) and the first central control unit (ZSEl) form a functional unit with first switchover control means (USSMl) and first switchover means (USMl) in the data transmission device (DÜE) the functional unit is designed in such a way that the control means (STM) and the first central control unit (ZSEl) signal an operating mode change (S1) to the first switchover control means (USSMl).

47. Data terminal device according to claim 44 or 45, characterized in that the control means (STM) and the first central control unit (ZSEl) with first switching control means (USSMl) in the data transmission device (DÜE) and second switching control means (USSM2) in the data processing device ( DVG) and the first switching means (USMl) in the data transmission device (DÜE) form a functional unit, the functional unit being designed such that the control means (STM) and the first central control unit (ZSEl) when the data terminal device (DEE) is up to date is in the first operating mode, signal the first switchover control means (USSM1) in the data transmission device (DÜE) an operating mode change or, if the data terminal device (DEE) is currently in the second operating mode, the second switchover control means (USSM2) in the data processing device (DVG) Signal operating mode change (S4).

48. Data terminal device according to claim 44, characterized in that a first line connection (LV1) is present, via which the data terminal device (DEE) is connected to the data transmission device (DÜE).

49. Data terminal device according to claim 44, characterized in that a first free space connection (FRVl) is present, via which the data terminal device (DEE) is connected to the data transmission device (DÜE).

50. Data terminal device according to claim 44, characterized in that it is integrated to form a structural unit in the data transmission device (DÜE).

51. Data terminal device according to one of claims 44 to 50, characterized in that the data terminal device (DEE) is designed as a cordless mobile part.