WO2006012883A1 - Method for transmitting data between a server in a hybrid network and a receiver device of said hybrid network (dynamic transmitter selection) - Google Patents

Abstract

The invention relates to a method for transmitting data. To transmit said data between a server (S) in a hybrid network and a receiver device (E; E*; E**; E1; E2; E3) of the hybrid network, the following method steps are carried out: a) identification of a receiver device of the hybrid network, which is required by a user to transmit data between the server and the receiver device; b) identification of accessibility variants of the hybrid network to implement the required data transmission to the receiver device and c) transmission of a quality test sequence for at least one system accessibility variant by the server; d) generation of a quality acknowledgement that is assigned to the received quality test sequence by the receiver device and e) transmission of the assigned quality acknowledgement to the server by the receiver device.

Description

 Method for data transmission between a server in or on a hybrid network and a receiving device of the hybrid network (dynamic transmitter selection)

description

The invention relates to a method for data transmission between a server in or on a hybrid network and a receiving device of the hybrid network.

Background of the invention

In the case of data transmission in networks, a distinction is fundamentally made between unidirectional and bidirectional transmission. While in bidirectional transmission, each station of the network is at the same time the transmitting and receiving station, there are stations in unidirectional networks which are designed either as pure receiving stations or as pure transmitting stations.

In cellular bidirectional network systems, ie network systems whose transmission ranges are divided into several regional cells with overlapping areas, a so-called local roaming is known. It is used to support user mobility and to make better use of the network system's transmission bandwidth. By the regular localization of a mobile terminal ("location update") and the handover of the assignment of a mobile terminal from one cell to an adjacent one Cell, it is sufficient to send the desired data to be sent only in the relevant cells.

In known unidirectional network systems is not considered whether the radiated from multiple stations

Data in the receiving areas are needed at all. For example, from DVB-T or satellite systems as

Radio systems always sent the data to be transmitted simultaneously from a plurality of transmitters, in the example of multiple transmit antennas or transponders.

The present invention has for its object to provide a method by which a better utilization of the data transmission capacities of a hybrid network is made possible, in particular a digital radio system.

Summary of the invention.

This object is achieved by a method having the features of claim 1.

Thereafter, the invention relates to a method for data transmission between a server in or on a hybrid network and a receiving device of the hybrid network. The hybrid network consists of at least two different network systems, which may include both satellite systems and terrestrial systems. This means that stations that send data to your coverage area can have at least two different network systems, such as a DVB-T system and a satellite transponder system. Each of the different network systems has at least one user area at which a user can receive data with a receiving device. For example, the hybrid network could include a WLAN network and a GSM network. In a method step, a receiving device of the hybrid network is determined or identified, with which a user desires a data transmission between the server and the receiving device. This is initially merely an identification of the receiving device, which can be done, for example, by a user requesting specific data from a receiving device and thereby transmitting an identification code of its receiving device to the server (for example, an IP address).

The server identifies accessibility variants of the hybrid network with which the desired data transmission with the receiving device can be realized. In hybrid networks, a multiplicity of possible accessibility variants can often exist due to overlaps of various regional reception areas. For at least one reachability variant of the hybrid network, a quality sequence is sent by the server to the receiving device. Thereafter, one of the receiving quality sequence is assigned in the receiving device

Quality feedback generated and sent back by the receiving device to the server.

The server can be designed both as an application server, via which several terminals of a terminal system can be controlled, or as a gateway server in a transit system between different networks.

Decisive in the method according to the invention is the checking of a reachability variant of a receiver of the

Network system through the quality sequence. The quality sequence can be used to check the signal strength, the required signal bandwidth, the desired signal duration, the maximum guaranteed bandwidth, the bit error rate, a delay and / or other characteristics of the signal transmission from a transmitting device to the receiving device. The method according to the invention therefore checks the quality of a reachability variant in the hybrid network for realizing a desired data transmission with the receiving device and sends it to the server.

In contrast to the bidirectional radio systems known hitherto, a quality control of the accessibility variants is made possible by the method according to the invention.

Compared with the previously known unidirectional network systems, the method according to the invention has the advantage of being able to assess the quality of a reachability variant in a hybrid network. The server can then decide whether or not the data transmission with the transmission element which is assigned to the special accessibility variant is sufficient for data transmission. Then the other transmitting elements would no longer need to transmit meaningless data into various regional broadcasting areas in which they are not needed the data.

Another great advantage of the method according to the invention is that different network systems can be combined with each other. Both bidirectional network systems and several unidirectional network systems as well as uni- and bidirectional network systems can be combined.

Decisive here is that accessibility variants are identified by the server and then at least one reachability variant is checked for quality.

In particular, for example, all reachability variants of a hybrid network can be checked for their quality, and the reachability variant that has the best quality can be used for the actual data transmission. In another embodiment, the various possible Reachability variants in turn only checked until a sufficient quality of a reachability variant has been determined, which is then used by the server for subsequent data transmission.

The method steps do not have to take place in the sequence described above, but can also follow each other differently or take place at the same time.

In one embodiment, information about the position of the receiving device is determined by the server at the same time in the identification of the receiving device. These can be either relatively exact position information such as GPS coordinates, or the information that the receiving device is located in the transmission range of a particular transmitting antenna.

Particularly preferred is at least one of the at least two hybrid network systems as a unidirectional digital

Radio system formed. Especially with unidirectional radio systems was previously a local roaming, so switching between different accessibility variants or user areas not possible. The sending of the quality feedback to the server by the receiving device then takes place in a different network system of the hybrid network than in the unidirectional network system over which the quality sequence is sent.

Advantageously, one of the unidirectional digital radio systems is designed as a DVB-T system (DVB: Digital Video Broadcasting) with a multiplicity of transmitting devices, wherein geographically defined, at least partially spatially different user areas are covered by the respective associated transmitting devices. A reachability variant of a user area is then the data transfer to the Receiving device by the respective user area associated transmitting device to make. The user areas may partially overlap so that a receiving device located in an overlapping area of two user areas can be reached by two or more transmitting devices which are respectively assigned to different user areas.

In one embodiment, a network system of the hybrid network is a satellite-based unidirectional

• digital radio system is formed and has a geographically defined transmission range. The geographically defined

Transmission area has at least partially spatially different user areas, which are covered by different transmission facilities of the satellite. The "footprint" of the satellite is therefore in several

Areas of broadcasting (also called "spots"), which may partially overlap each other

Transponder of the satellite associated with a data transmission from the satellite to receiving equipment in the

User area allows.

Preferably, at least one network system of the hybrid network is designed as a cellular network. The data transmission into a cell of the network by means of a transmitter associated with the cell then represents a reachability variant.

In one embodiment, when determining the receiving device, position data are determined which represent a current location of the receiving device.

Then a user area of a unidirectional digital radio system for data transmission is determined in which the location of the receiving device is located. Subsequently, at least one preferred user area and its associated transmitting device based on

Quality criteria selected. Data requested by the user are then sent exclusively via a subset of all transmitting devices of the unidirectional digital radio system, the subset of all transmitting devices at least the associated transmitting device of the preferred user area urnzufasst. The other transmitting devices can be used for data transmission of other data to other users, since they are not required for data transmission to the above-mentioned users.

In a preferred embodiment, the quality sequences of a reachability variant are sent together with an identifier of the transmitter associated with the reachability variant. The identifier of the transmitter can either consist of an ID number, ie be transmitted explicitly, or implicitly emerge from the way the signal transmission or their physical properties. For example, as an implicit identifier, the signal field strength may vary in a specific manner or vary the polarization of the signal in a specific manner associated with a particular transmitter. This frees up transmission capacities that can be used for data transmission.

This method can be accelerated by sending data desired to the receiver device of the user via the transmission facilities of a unidirectional digital radio system up to the method step of determining the reachability variants, together with the quality sequence. In this case, a response regarding the location of the receiving device is requested. The quality sequence contains an identifier of the transmitters of the hybrid network over which the quality sequence was sent. The quality feedback contains the information about which transmitter the receiving device has received the quality sequence, whereby the reachability variant only as possible Reachability variant for the receiving device is identified and can be selected by the server. Thus, the time that was previously necessary for determining position data and dependent accessibility variants, already used for data transmission, whereby the data transmission is accelerated.

Is carried out via the server of the hybrid network, a data transmission to a receiving device at least one other user whose receiving device is arranged in an overlap region of the or the preferred user areas with adjacent user areas of the unidirectional digital radio system and / or another digital unidirectional or bidirectional radio system, can transmit the data transmission by roaming processes to the transmitting devices of the neighboring user areas. As a result, the preferred user areas, which have already been selected as reachability variant with good quality, freed from a transmission load, and therefore have a wider bandwidth for data transmission to the

Receiving device of the user available.

In one embodiment, the hybrid network includes a cellular digital radio system in addition to a unidirectional digital radio system. During the transmission of the desired data, a roaming process is carried out between the two radio systems.

This achieves great flexibility with regard to the use of various data transmission options.

The utilization of the various transmission devices of the different radio systems can also be matched or shifted to temporarily (cost) cheaper data transmission paths out.

Two accessibility variants can either differ from each other by giving them a different one Sender or different physical signal properties or both are assigned. In this case, different physical signal properties are understood to mean signal properties which can bring about a different transmission quality between transmitter and receiver, such as a different polarization of the signal or another transmission frequency.

Description of preferred embodiments

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

Figure 1 is a schematic representation of a unidirectional terrestrial radio system with three transmitting antennas.

Fig. 2 is a unidirectional digital satellite radio system with in single

User areas split footprint in a schematic representation; and

Fig. 3 is a hybrid network consisting of a respective terrestrial and a satellite-controlled unidirectional digital radio system in a schematic representation.

Fig. 1 shows a schematic representation of a unidirectional digital radio system, which is controlled by the server S. The server S is electrical with three

Transmit antennas Al, A2 and A3 are connected, for example, which are positioned relative to each other so that they are arranged approximately in the corners of an imaginary, not shown equilateral triangle. Each of the transmission antennas Al, A2 and A3 can transmit data by radio in a user area N1, N2, N3 marked with a circle Transmit reception facilities. The range of the respective transmitting antenna is represented in each case by a circle, in the center of which the transmitting antenna is arranged. Each of the transmission antennas A1, A2 or A3 can therefore transmit data within the associated user area N1, N2 or N3.

The user areas N1, N2 and N3 are designed such that each receiving device located within the equilateral triangle, which is formed by the transmitting antennas A1, A2 and A3, is within the range of at least one transmitting antenna A1, A2 or A3. This avoids that, for example, within a metropolitan area, a "radio hole" is formed.

In some areas, the user areas Nl, N2 and / or N3 overlap to overlap areas Ü12, Ü23, Ü13. For example, a receiving device E * located in the overlapping area Ü12 of the two user areas N1 and N2 can transmit both the transmitting antenna A1 and the transmitting antenna A2

Recommend data. The overlapping areas in each case of two areas of use, ie the overlapping area Ü12 as the overlapping area of the user areas N1 and N2, the overlapping area Ü13 as the overlapping area of the user areas N1 and N3 and the overlapping area Ü23 as the overlapping area of the user areas N2 and N3 form the intersection of two user areas.

At the center of the equilateral triangle formed by the transmitting antennas A1, A2 and A3 is an overlapping area Ü123, which forms the intersection of the user areas N1, N2 and N3. A receiving device E located in this overlapping region Ü123 can receive data transmitted by any transmitting antenna A1, A2 and A3.

In this spatial division of this embodiment the process according to the invention proceeds as follows:

In the case illustrated in FIG. 1, the hybrid network contains a terrestrial, unidirectional digital radio system which has three user areas N1, N2 and N3 which partially overlap. Instead of or in combination with a terrestrial radio system, satellite systems or controllable spotbeams can also be used. The aim of the method is to enable local roaming between the individual user areas N1, N2 and N3 within the unidirectional radio system. If a user desires a data transmission between the server S and the receiving device E, the position of the receiving device E is first determined.

This can be done by sending a control signal from the receiving device, which is transmitted via another network system of the hybrid network position data of the receiving device to the server, for example in GPS coordinates. The control signal is not sent via the unidirectional radio system but, for example, via the IP network, an ISDN network, or a PSTN network to which the server is connected. Thus, the identification of the receiving device E is carried out at the same time with a determination of information about the position of the receiving device at the initiative of the user.

Alternatively, the position of the receiving device can also be determined by sending an implicit or explicit identifier with the aid of the transmitting antennas A1, A2 and A3, which is sent back to the server S by the receiving device.

With the knowledge of the location of the receiving device E, the server S can determine available reachability variants. In the case shown, the position of the receiving device E in the overlapping area Ü123 grants the three User areas Nl, N2 and N3 maximum accessibility over all three transmission antennas Al, A2 and A3. Therefore, the server S can decide which of the three transmission antennas to send the desired data.

This decision may make the server S dependent on what quality (e.g., what bandwidth, bit error rate, maximum guaranteed bandwidth, or the size of a signal delay) is achieved in transmitting data through one of the transmit antennas A1, A2, or A3 to the receiving device E. The transmission quality can be checked with - a quality test sequence for at least one accessibility variant by the server. Upon receiving a quality test sequence, the receiving device generates a quality feedback associated with the quality sequence and returns it to the server.

In one embodiment, the transmission of the quality feedback can coincide with the identification and the determination of the position of the receiving device. For example, transmitter-specific quality sequences for a specific receiving device can be sent from all the transmitting antennas at the same time, which can be sent by the receiving device with the quality feedback and the information. from which of the transmission antennas Al, A2 and A3 it has received the quality sequence, are sent back.

Thus, the server S receives in one fell swoop the information about how good the transmission quality is between all transmission antennas belonging to the radio system and the receiving device. A position determination of the receiving device is thus connected insofar as it is determined in which user area Nl, N2, N3, the receiving device is located. In addition, information about transmission qualities is transmitted between the receiving device and the respective transmitting antennas. However, the decision as to which of the three transmission antennas Al, A2 or A3 the data should be transmitted can also be made dependent on how many further reception devices are located in the user areas N1, N2 and N3. If, for example, the user areas N1 and N2 are well utilized, while transmission capacities are free in the user area N3, then the transmission antenna A3 is selected by the server in order to transmit data to the reception device E in the overlapping area U123.

In a variant of the method according to the invention, the desired data is first transmitted via all three transmission antennas Al, A2 and A3 up to the time at which the position of the receiving device E is determined. Only when the server has received the position of the receiving device E, the above-described optimization of data transmission by one of the transmission antennas Al, A2 or A3. Thus, although initially all three transmit antennas with the

Data transmission and only after positional transmission to the server, some of the transmit antennas are released to transfer other data to other users, but the data transfer is faster.

In a further exemplary embodiment according to the invention, the bandwidth available for a user of a receiving device E * in the overlapping area Ü12 for the transmission of data is increased by transferring parallel users in the overlapping area Ü13, Ü23 and Ü123 via local roaming to adjacent user areas of the same radio system , ie in the user area N3. Thereby, high-bandwidth data can be transmitted to the receiving device E * by the transmitting antennas Al and A3. This happens as far as a roaming by the position of the further users in one or more Overlapping areas of the corresponding user areas is possible. By using two transmit antennas, a higher transmission bandwidth or a redundancy increase can be achieved than if only one transmit antenna were available.

The named user areas and associated transmit antennas are to be understood as examples in this case. In the same way, for example, the transmission quality via transmission antenna A1 to a receiver E ** at any position in user area N1 could be optimized by forwarding data to as many other reception devices in overlap areas Ü12, Ü13 and Ü123 as possible to transmission antennas A2 and A3 transfer.

The three embodiments presented are also applicable to the radio systems shown in FIGS. 2 and 3.

In the unidirectional digital radio system shown in FIG. 2, the data is transmitted via a satellite ST in FIG

User areas Nl to N4 transferred. The satellite ST has at least four transponders (not shown), each of which is assigned to a regional user area N1 to N4 and sends data thereto. The satellite ST is controlled by the server S.

The user areas Nl to N4 are all rectangular in shape and arranged in the corners of a large rectangle that represents the total area of the area in which receiving devices can receive data through the radio system shown in FIG.

The intersection of two user areas is formed by a narrower rectangle, in which a user of a receiving device can receive data from the satellite ST. For example, the overlap area Ü12 forms the overlapping area of the two user areas N1 and N2, etc. In the middle of the entire reception area there is an overlapping area Ü1234 of all four user areas N1 to N4, which represents the intersection of all user areas. To a located in Ü1234 receiving device E can be transmitted from all four transponders of the satellite ST from data. If, for example, there are many receiving devices E * in the overlapping areas Ü12 and Ü13 at the time of the transmission, then the transponders for the user areas N1, N2 and N3 are very busy, a desired data transmission to the receiving device via the transponder of the user area N4 is performed to have the highest possible bandwidth available for transmission.

Finally, FIG. 3 shows a hybrid network which consists of at least two radio systems: a terrestrial transmission antenna A 1, A 2 and A 3 set up in an irregular triangle and circular user areas N 1 to N 3 and a cellular radio system, as shown in FIG Data from a (not shown) satellite from in rectangular user areas N4 to N7 are fed. Here, the transmission of data can be passed not only between user areas within a radio system, but also between different radio systems.

If, for example, the user of a mobile telephone moves as a receiving device from El in the overlapping area Ü126 to E2 in the overlapping area Ü1256 to E3 in the overlap area Ü156, he could, for example, be continuously supplied with data by the transponder of the satellite responsible for the user area N6 or also via the transmission antenna A1 , However, if this transponder or transmitting antenna Al is very overloaded, then the receiving device can be supplied at the location El and also at the location E2 by transmitting antenna A2, at the location E3 by the transponder of the satellite responsible for the user area N5. In order to achieve the highest possible bandwidth or the highest possible redundancy in the data transmission, the receiving device can also be sent data from all transmitting devices in an overlapping region that reach the receiving device. If the receiving device El is therefore in the overlapping area Ü126, then both the transmitting antennas A1 and A2 and the transponder of the user area N6 will at the same time transmit data, in the overlapping area Ü1256 the transponder of the utilization area N5, etc.

The quality sequences can be sent as a training sequence at regular intervals of all or a local limited selection of stations with an ID identifier of each transmitter and be answered by the receiving device, for example via the IP network as a control signal to the server. In particular, a quality sequence of a transmitter is then answered by all receiving devices that are located in the transmission area of the respective transmitter. As a result, the server receives at regular time intervals information about the transmission quality to one or all receiving devices of the hybrid network.

Alternatively, a quality sequence can only be sent by a plurality of transmitters specifically to a receiving device if transmission errors or an increase in the bit error rate are registered. Thus, the server receives new transmission quality information via the corresponding control signals of the receiving device only if the quality of a reachability variant changes.

Alone in this relatively simple example arise combinatorial already a large number of possible stations and thus accessibility variants for a position of

Receiving device. The server S can now either the Select a transmission path and thus the reachability variant that promises the widest bandwidth, or choose a transmission path that ensures a sufficient transmission quality. The selection of the reachability variant is thus determined by a transmission property contained in the quality sequence and performed automatically by the server. However, in this example, the user of the receiving device can still select whether he would prefer to have a cost-effective connection or a connection with as high a bandwidth as possible. However, the actual connection and thus the actually used reachability variant is selected by the server, taking into account the user's request.

Claims

claims

1. Method for data transmission between a server

(S) in or on a hybrid network and receiving means (E; E *; E1; E2; E3) of the hybrid network, with the following

Method steps: a) Identification of a receiving device (E, E *, E **, El, E2, E3) of the hybrid network with which a user transmits data between the server (S) and the receiving device (E; E *; E * *; El; E2; E3) wishes; b) Identification of accessibility variants of the hybrid network for realizing the desired data transmission with the receiving device (E; E *; E **, E1; E2; E3) and c) Sending a quality test sequence for at least one accessibility variant by the server (S) ; d) generating a quality feedback associated with the received quality test sequence by the receiving device (E; E *; E **; El; E2; E3) and e) transmitting the associated quality feedback by the receiving device (E; E *; E **; El; E2; E3) to the server (S).

2. The method of claim 1, wherein in the

Identification of the receiving device (E; E *; E **;

El; E2; E3) from the server (S) at the same time information

, be determined via the position of the receiving device.

3. The method of claim 2, wherein the at least one network system as a unidirectional digital radio system is trained.

4. The method of claim 3, wherein one of the unidirectional digital radio systems as a DVB-T system with a plurality of transmitting devices (Al, A2, A3) is formed, wherein geographically defined, at least partially spatially different user areas (Nl, N2, N3 , N4, N5, N6, N7) are covered by the respectively assigned transmitting devices.

5. The method of claim 3 or 4, wherein one of the unidirectional digital radio systems is satellite-based and has a geographically defined transmission range, the transmission range geographically defined, at least partially spatially different, user areas (Nl, N2, N3, N4), the be covered by different transmission facilities of the satellite.

6. The method according to any one of the preceding claims, wherein at least one network system is formed as a cellular network.

7. The method according to any one of the preceding claims, wherein together with the quality sequence of a reachability variant, an explicit and / or implicit identifier of the sender, which is associated with the reachability variant, is shipped.

8. The method according to any one of claims 3 to I ₁ with the following method steps: a) determining position data, the

Information about a current location of the receiving device (E; E *; E **; El; E2; E3), b) determining the user areas (N1-N7) of the unidirectional digital radio system available to the user at the location of the receiving device (E; E *; E1; E2; E3) for data transmission, c) selecting at least a user-preferred range (Nl to N7) and its associated transmitting device (Al, A2, A3) based on user criteria and d) transmitting user desired data exclusively over a subset of all transmitting devices (Al, A2, A3) of the unidirectional digital radio system comprising at least assigned

Transmitting device (Al, A2, A3) of the preferred user area (Nl to N7).

9. The method according to claim 8, wherein prior to the step of determining the positional data, first of all, desired data is transmitted to the receiving device via all transmitting devices (A1, A2, A3) of a unidirectional digital radio system (E; E *; E **; E1; E2; E3) of the user are sent while a response is requested with respect to the location of the receiving device.

10. Method according to claim 8, wherein after the step of selecting at least one preferred user area (N1 to N7) the data transmission to a receiving device (E; E *; E *; E1; E2; E3) of at least one further user the reception device thereof in an overlapping region (Ü12, Ü13, Ü23, Ü14, Ü34, Ü26, Ü123, Ü126, Ü156, Ü1256, Ü1234) of the preferred user area (s) with adjacent user areas of the unidirectional digital one Radio system and / or another digital unidirectional or bidirectional radio system is arranged, is transmitted by roaming processes on the transmitting devices () Al, A2, A3) of the adjacent user areas.

11. The method according to any one of the preceding claims 8 to 10, wherein the hybrid network in addition to a unidirectional digital radio system comprises a cellular digital radio system and in the transmission of the desired data, a roaming process is performed between the two radio systems.

12. The method of claim 2, wherein determining from information about the position of

Receiving means (E; E *; E **; El; E2; E3) by receiving the quality test sequence for the at least one reachability variant and returning the quality feedback to the server (S).

13. The method according to claim 1, wherein the quality feedback contains at least: the quality test sequence and information for identifying the receiving device (E; E *; E **;

El; E2; E3).

14. The method of claim 13, wherein the quality feedback further includes information about the signal strength and / or the required signal bandwidth and / or the desired signal duration and / or a time delay of the signal transmission and / or a bit error rate and / or other properties of the signal transmission.

15. The method according to claim 13 or 14, wherein information for identifying the Receiving device (E; E *; E **; El; E2; E3) comprise an IP address or a MAC address of the receiving device.

16. Method according to one of the preceding claims, wherein at least two reachability variants differ from one another in that they are assigned to two different transmitters (Al, A2, A3).

17. Method according to one of the preceding claims, wherein two reachability variants differ from one another in that a transmitter (A1, A2, A3) sends two signals with different physical signal properties.

18. The method according to any one of the preceding claims, wherein the server in the presence of multiple reachability variants automatically and depending on a determined signal quality selects a reachability for a data transfer.