WO2003079590A2 - Method for the transmission of data in a radiocommunication system - Google Patents

Abstract

In order to transmit data between a base station and a transcoding unit of a radiocommunication system, a transmission capacity, the size of which is selected among a predefined quantity comprising at least two variables, is assigned to a user. The transmission capacity can be supplied in the form of time frames having different lengths. Said time frame can be configured as a chain of individual partial frames having a constant length. Time frames which have different lengths comprise a different number of partial frames. Additionally, access rights to common resources can be controlled by priorities that depend on the load or are given by radio conditions.

Description

description

Method for the transmission of data in a radio communication system

Radio communication systems are used to transmit information, voice or data using electromagnetic waves via a radio interface, also known as an air interface, between a transmitting and a receiving radio station. An example of a radio communication system is the known GSM mobile radio network, the architecture of which is described, for example, in B. Walke, Mobile Radio Networks and Their Protocols, Volume 1, Teubner-Verlag Stuttgart, 1998, pages 139 to 151 and pages 295 to 311. A channel formed by a narrowband frequency range and a time slot is provided for the transmission of a subscriber signal. Since a subscriber signal in a channel differs in frequency and time from the other subscriber signals, the receiving radio station can carry out a detection of the data of the subscriber signal. In newer radio communication systems, such as the UMTS system, the individual subscribers are also distinguished by different spreading codes.

A radio communication system, for example a GSM mobile radio network, comprises a multiplicity of mobile switching centers (MSC) which are networked with one another and which provide access to a fixed network. Furthermore, these mobile switching centers are connected to at least one base station controller (base station controller BSC). It is between the

Mobile switching center and the base station controller each provided a transcoding unit (Transcoding and Rate Adaptation Unit TRAU). The base station controller enables a connection to at least one base station (base transceiver station, BTS) and manages the radio resources of the connected base stations. Such a base station is a radio station that uses a radio interface can establish a communication connection to mobile stations.

With a communication link between a mobile station and a base station, digital, source-coded

Voice signals from the mobile station are coded in error protection and encrypted via the air interface. A time slot of a time frame is assigned to the message connection. Different communication links are transmitted in time division multiplex, with eight time slots forming a time frame.

When transmitting from a mobile station to a base station, the signals are decrypted in the base station and the error protection is removed. The transmission of the digital signals of a communication link, that is, of a subscriber, between the base station and the transcoding unit takes place in a time frame which is referred to as the TRAU frame or the TRAU time frame. A TRAU frame is permanently assigned to each participant. A TRAU frame is a time frame of a predetermined length, so that the transmission capacity is 16 kbit / s or 8 kbit / s. The length of a TRAU time frame is 20 ms.

In the transcoding unit, voice signals from connections to the fixed network are converted to the format of the fixed network, for example standard ISDN format. The 8 kbit / s or 16 kbit / s TRAU time frames are converted to 64 kbit / s ISDN time frames. This implementation, which is always associated with a loss of data quality, can be omitted for connections between two mobile stations. One then speaks of tandem free operation.

For the transmission of the data between the base station and the transcoding unit, each connection is therefore assigned a transmission capacity of a fixed size. The size of the transmission capacity must be such that the useful Data rate that is transmitted via the air interface in a time slot plus the necessary signaling information can be transmitted. The measurement of the size of the transmission capacity assigned to a subscriber is therefore based on the maximum data rate that can be transmitted for the subscriber in a time slot on the air interface. Due to the fixed assignment of the transmission rate on the air interface to the transmission capacity of a TRAU time frame, the possible useful data rate on the air interface is limited to a maximum of 16 kbit / s. The maximum data rate to be transmitted is further reduced by additional signaling.

The invention is therefore based on the problem of specifying a method for transmitting data in a radio communication system in which the transmission capacity between the base station and the transcoding unit can be adapted and used economically.

This problem is solved according to the invention by a method according to claim 1. Further refinements of the invention emerge from the remaining claims.

In the method for transmitting data in a radio communication system, a subscriber is assigned a transmission capacity for the transmission of the data between a base station and a transcoding unit of the radio communication system, the size of which is selected from a predetermined quantity with at least two sizes. By providing transmission capacity of different sizes, the transmission capacity assigned to the subscriber can be adapted to the actually available data rate. This makes better use of the transmission path between the base station and transcoding unit. It is within the scope of the invention to provide the transmission capacity assigned to a subscriber in the form of time frames of different frame lengths.

The time frames preferably comprise at least one subframe of constant length, with differently long time frames having different numbers of subframes, each of the same length. When the method is used in a GSM-like mobile radio network, this procedure has the advantage that the known TRAU time frames can be used as subframes and that in this way a seamless conversion to ISDN format can be implemented.

According to one embodiment of the invention, the first subframe of a time frame contains signaling information for data transmission in addition to useful data. If the time frame has further subframes, the further subframes contain, in addition to useful data, an identifier of the subframe and an identifier of the time frame. The first subframe and the further subframes are thereby logically linked. This has the advantage that the subframes that together form a time frame do not necessarily have to be transmitted one after the other. For example, after the first subframe of a first time frame, a first subframe of a second time frame can be transmitted and then further subframes of the first time frame. This enables the real-time requirements of different participants to be better taken into account. At the same time, unnecessary overhead is avoided by the fact that the signaling information is only contained in the first subframe and the further subframes only contain an identifier of the subframe and an identifier of the time frame, which are required for assembling the subframes into the time frame.

The subframes preferably contain information for controlling the temporal position on an interface between the base station and the transcoding unit, with which the the arrival of the subframes in the base station is controlled. For psycho-acoustic reasons, very high demands are placed on the delay times for the transmission of voice data. According to this embodiment of the invention, these requirements can be met by using a mechanism for time synchronization of the subframes of a time frame. The temporal relationship between the subframes is established and additional delay times are avoided.

This method can also be used for enhanced circuit switched data (ECSD) for data transmission in a GERAN system (GSM EDGE Radio Access Network). ECSD is a connection-switched data transmission method, the data of which is transmitted on the air interface with eight PSK modulated.

In order to be able to efficiently transmit the high data rate per time slot on the air interface given by ECSD also on the terrestrial connections, time frames of different lengths are dynamically allocated according to this invention and their length is controlled by priorities.

The method is also suitable for the transmission of data between the base station and the transcoding unit according to an Internet Protocol (IP) method or an ATM method. In this case, the data transmission between the base station and the transcoding unit takes place in the form of data packets. The individual participants are assigned differently sized transmission capacities.

The utilization of the transmission path between the base station and the transcoding unit can be further improved by assigning the transmission capacity dynamically. In this case, a larger or smaller transmission capacity is allocated to the respective subscriber on the basis of a prioritization assigned to the respective subscriber and on the basis of the radio conditions determined for the respective subscriber when the load on the transmission link changes. grasslands. This ensures that, on the one hand, as many participants as possible are served and, on the other hand, as many participants as possible receive optimal quality.

It is within the scope of the invention to cause a subscriber to whom a larger or smaller transmission capacity is assigned to change the speech coding or the modulation method or the cell.

The application of the method in an adaptive multi rate (AMR) method is particularly advantageous. In an AMR process, various coding processes are available that are assigned to a subscriber connection depending on the transmission conditions. Since the coding methods used in AMR methods are in contrast to the GSM full rate, GSM half rate and GSM enhanced fill rate methods, in which a rigid division of the total bit rate into a fixed channel coding component and a fixed speech coding component If a variable change is made between coding methods with different channel coding components or voice coding components, AMR methods are able to adapt the coding method used adaptively to the transmission conditions of the air interface. As a result, the coding method that is best suited for the current transmission condition can be selected and continuously adapted when the transmission conditions change, and the voice quality in the mobile radio network can thus be significantly improved.

Coding methods with a source bit rate between 6.60 kbit / s and 23.85 kbit / s have been standardized for the so-called AMR wide band method. This useful bit rate is transmitted for a subscriber via the time slot assigned to him via the air interface. These bit rates must be transmitted in a time frame between the base station and the transcoding unit. By using the method according to the invention, the size of the time frame used after the measured present bit rate. If bottlenecks occur on the transmission link between the base station and the transcoding unit, subscribers of lower priority are only initiated coding processes with a low bit rate, and the subscriber is assigned a smaller time frame. If the radio conditions deteriorate significantly for a subscriber, a change in the group of possible coding methods to a group with coding methods with low bit rates and thus greater robustness on the air interface is likewise initiated for him and a smaller time frame is assigned to him. If, on the other hand, the load in the network drops, a switch to a group of coding methods with a higher bit rate is initiated for a subscriber of higher priority and a larger transmission capacity, ie a larger time frame, is allocated to it. If the radio conditions for a subscriber improve and the utilization of the system permits, a change in the group of coding methods to higher useful bit rates is initiated for this subscriber and the subscriber is assigned a larger time frame.

The invention is explained in more detail below on the basis of exemplary embodiments which are illustrated in the figures.

FIG. 1 shows a section of a radio communication system in which the method according to the invention can be used

Figure 2 shows some time frames.

FIG. 3 shows a flow chart for assigning time frames.

FIG. 4 shows a flow chart for determining the radio conditions.

Figure 5 shows the creation of assignment lists. A radio communication system comprises a plurality of base stations BTS1, BTS2, BTS3, via which a radio connection to a mobile station MS can be established (see FIG. 1). Each of the base stations BTS is assigned to a base station controller BSC. The interface between the base station BTS and base station controller BSC is referred to as the A _to interface.

The base station controller BSC is connected via a transcoding unit TRAU to a mobile switching center MSC, which represents the interface to other networks. The interface between the base station controller BSC and the transcoding unit TRAU is called the A _sub interface, the interface between the transcoding unit TRAU and the mobile switching center MSC is called the A interface.

Each subscriber is assigned a time frame ZR1, ZR2, ZR3 on the transmission link between a base station and a transcoding unit of a radio communication system (see FIG. 2). The time frames ZR1, ZR2, ZR3 have different lengths. Each time frame ZR1, ZR2, ZR3 contains at least a first subframe TR11, TR21, TR31. The longer time frames ZR1, ZR3 also have a further subframe TR12, TR32. The first subframes TR11, TR21, TR31 and the further subframes TR12, TR32 have the same, constant length. The first subframes TR11, TR21, TR31 and the further subframes TR12, TR32 have such a length that they have a transmission capacity of 16 kbit / s on the given transmission path. They have a length of 40 octets = 320 bits.

In addition to user data, the first subframes TR11, TR21, TR31 also contain signaling information for data transmission, such as information on power control, via U link measurements of the base station (for example RXLEV, RXQUAL), down link signaling from the base station to the mobile station, and redundancy information such as CRC (Cyclic Redundancy Check).

The further subframes TR12, TR32 contain, in addition to user data, additional information which is used for logical chaining with the respective first subframe TR11, TR31, such as, for example, the specification of how many subframes of the time frame to be transmitted is the present and an identifier of the time frame, to which the respective subframe belongs. This identifier can be implemented as a shortened time frame number.

With regard to downward compatibility, it is advantageous to additionally provide an identifier for the type of time frame used in the first subframe TR11, TR21, TR31.

All subframes preferably contain information for controlling the temporal position on the Abis interface. Each subframe can thus be shifted in time independently of all other subframes that belong to a time frame. As a result, the subframes can take different paths when switching the 16 kbit / s channels. The time shift can ensure that all subframes belonging to a specific frame arrive at the base station at the same time. This is important because the subframes have to be reassembled in the base station before they can be sent on the air interface. The subframes are shifted in time by adding and omitting additional bits at the end of each subframe. The number of bits left out or appended determines the time of the shift (4 bits = 250 microseconds). This means that influences during Abis transmission in 16 kbit / s channels can be compensated. In the transmission direction from the mobile station to the base station, that is to say in the up link direction, the base station must break down the time frame received via the air interface into the required subframes.

In the transmission direction from the base station to the mobile station, that is to say in the downlink direction, the base station extracts the data and the signaling information. In the downlink direction, the BTS removes and checks the redundancy information CRC for each subframe. The user data is then composed of all associated subframes for the entire time frame.

So that all subframes arrive at a certain time, the base station calculates and controls the required time of arrival separately for each subframe with the aid of the transcoding unit. The time at which a single subframe arrives in the downlink direction and the time at which the composite frame has to be sent on the air interface are used for the calculation. Any deviations are communicated to the transcoding unit in the signaling information of the associated subframe in the up link direction. The transcoding unit then supplements or omits a certain number of bits in the downlink direction. As a result, all subframes belonging to a frame arrive at the same time and can be sent without buffering. This is particularly important because of the real-time requirements for voice connections.

The data is then transmitted via the air interface. For this purpose, the entire time frame is encoded according to the selected coding method and transmitted using the corresponding modulation method.

When using the method according to the invention in an AMR wide band method, the time frame can be assigned with of the adjusted length for a subscriber, it can be used that in AMR procedures the available coding procedures are divided into groups with a maximum of four coding procedures. The possible coding methods are divided into four groups, for example, which are referred to as Active Codec Set (ACS), each with a maximum of four coding methods. A time frame length is specified for each of the groups ACS1, ACS2, ACS3, ACS4.

For example, the group ACS1 for AMR narrow band, which contains coding methods with transmission rates of 12.2 kbit / s, 7.95 kbit / s, 5.9 kbit / s, and 4.75 kbit / s, is provided with a time frame assigned to only one subframe. The same applies to the ACS2 group for AMR wide band, which for example has coding methods with transmission rates of 6.60, 8.85 and 12.65 kbit / s. The groups ACS3 for AMR wide band, which contain coding methods with transmission rates of 23.85, 15.85, 12.65 and 6.60 kbit / s, and the groups ACS4 for AMR wide band, the coding methods with transmission rates of 15 , 85 kbit / s, 12.65 kbit / s, 8.85 kbit / s and 6.60 kbit / s, a time frame with a first subframe and a further subframe is assigned. The decision as to which time frame is assigned to a connection is made on the basis of the group coding method ACSi, i = 1 to 4, and the corresponding time frame length is then selected. The selection of the

A group that is assigned to a connection takes place on the one hand according to traffic load-related criteria and on the other hand according to radio conditions, whereby for example the level during call setup, which is determined by the RXLEV value of the SDCCH, is evaluated.

The assigned ACS group can be changed by a handover, eg intracell handover and assignment of a new ACS group, or by exchanging the coding process contained in an ACS during the connection. In order to achieve optimum utilization of the transmission link between the base station and the transcoding unit, the transmission capacities assigned to the respective connection are dynamically adapted (see FIG. 3). For this purpose, three limit values are defined in an exemplary embodiment. If the current load exceeds a first limit value, new connections are only assigned a time frame with only one subframe. If the current load exceeds a second limit value, then selected connections that previously had a time frame with several subframes are assigned a time frame with only one subframe. This usually requires a change in the ACS group. The possible coding methods can be changed by assigning a new ACS group that only occupies one time frame with only one subframe.

If the current load falls below a third limit value, which is calculated as the difference between the second limit values and a hysteresis value, then selected connections, which could previously use a time frame with only one subframe, are assigned a time frame with several subframes.

If the current load decreases below the first limit value, new connections can also be assigned a time frame according to the given requirements.

The current load of the system is determined, for example, by considering all the relevant factors. This includes the interface A _bis between the base station and the base station controller, and the interface A _sub between the base station controller and the transcoding unit, and the base station controller and the transcoding unit.

The selection of the connections to which a different time frame is assigned due to the current load takes place on the one hand according to a list of priorities and on the other hand according to the given radio conditions. The C / I value, which represents the ratio of useful signal to interference, is a suitable parameter for assessing the radio conditions. For example, two thresholds are defined. If the C / I value exceeds a first threshold C / I threshold, the connection can be assigned an ACS group with high-rate coding methods for good radio conditions. If the C / I value falls below a second threshold C / I threshold 2, which is smaller than the first threshold C / I threshold, the connection is assigned an ACS group with more robust and possibly lower-rate coding methods for poor radio conditions (see Figure 4). The composition of the coding method for the different ACS groups can be selected in such a way that time frames of different sizes are required for the terrestrial data transmission.

For the assignment of a larger time frame or a smaller time frame for a given connection due to the current load of the system (see FIG. 3), lists Z _λ and Z _{2 are} created which contain the participants in the order in which they are used by another Time frame should be assigned (see Figure 5). The list Z _x for the allocation of a smaller time frame and the list Z ₂ for the allocation of a larger time frame are generated on the basis of a priority list P and a radio conditions list F. The priority list P contains a priority for each participant, which is assigned to him on the basis of the information available to the operator, for example contract terms or the like. The list of radio conditions F contains the distance of the current C / I value to the first threshold C / I threshold and to the second threshold C / I threshold 2 for each subscriber. Lists Z ₁₇ Z ₂ are generated on the basis of lists P and F. The list Z _x , of the participants to whom a smaller time frame is to be assigned, only contains participants who have currently assigned a larger time frame. The list Z _{2 of} the participants who have a longer time frame to be assigned contains only participants who are currently assigned a smaller time frame. The topmost participant of the lists Z _lf Z is the one whose assigned time frame is changed the next time the corresponding threshold is exceeded or undershot (see FIG. 3).

When determining the current load, all services that use the corresponding resources would have to be considered. The A _to interface between the base station and base station controller is used, for example, not only by voice subscribers, but also by packet-switched data services. To determine the utilization of individual components, counters can be implemented, for example, which count the utilization of all components.

In the case of a connection between two mobile stations in which there is no conversion to the ISDN format in the transcoding unit, i.e. in tandem free operation, it is advantageous when assessing the system load, both mobile stations and the assigned base stations, base station controls and transcoding units, and the associated A _bis and A _sub interfaces. Only if a time frame with several subframes is available for the connection for both base station systems, does it make sense to assign such time frames for the connection.

To set up a new conversation between a subscriber 1 and a subscriber priority 1, the RXLEV level of the SDCCH is first measured. The level is used to determine, for example, that the radio conditions are good enough to use an ACS group with coding methods of high-rate source bit rates. This requires a time frame with several subframes.

The next step is to check whether the current traffic load is less than the first limit (see figure 3). This is the case, for example. A time frame with a first subframe and a further subframe is thus assigned to the connection. The network thus offers the connection optimal quality.

Now the load on the A _to interface increases and the first limit value is exceeded. At this time, a request from another subscriber 2 who also wants to set up a conversation is received. The subscriber 2 has a subscriber priority 2 that is greater than the subscriber priority 1. The measurement of the RXLEV level of the SDCCH shows that the radio conditions are suitable for assigning an ACS group with a high-rate coding method. However, since the current load is higher than the first limit value, the connection is assigned a group ACS, which only contains low-rate coding methods, for which a time frame with only a first subframe is sufficient.

The current load is now higher than the third limit, so that larger connections cannot be assigned to existing connections.

If the load now falls below the third limit value, larger time frames can be assigned. Due to the good radio conditions, subscriber 2 is entered in list Z ₂ (see FIG. 5) for the assignment of a larger time frame. Since additional resources are now available due to the fact that the current load falls below the third limit, and no subscriber with higher priority is included in the list Z ₂ , subscriber 2 becomes the ACS group and thus the one for this connection The available coding method is assigned a time frame with a first subframe and a further subframe. With the assignment of another ACS group and the possibility of using higher-rate coding methods, the speech quality of the connection of subscriber 2 is increased. If the instantaneous load rises again and exceeds the second limit value, subscriber 1, who is in first place in list Z, but which has the same radio conditions as subscriber 2 but a lower subscriber priority, is assigned a smaller time frame with only a first subframe. At the same time, subscriber 1 is deleted from list Z _x and, due to the good radio conditions, added to list Z ₂ .

Claims

claims

1. Method for the transmission of data in a radio communication system,

in which a subscriber is assigned a transmission capacity for the transmission of data between a base station and a transcoding unit, the size of which is selected from a predetermined quantity with at least two sizes.

2. The method according to claim 1,

- in which the transmission capacity is provided in the form of time frames of different frame lengths.

3. The method according to claim 2,

- In which the time frames comprise at least one subframe of constant length, with differently long time frames having different numbers of subframes.

4. The method according to claim 3, in which the first subframe of a time frame contains signaling information for the data transmission,

- In which if the time frame has further subframes, the further subframes contain an identifier of the subframe and an identifier of the time frame, and the first subframe and the further subframes are logically linked.

5. The method according to claim 3 or 4, wherein the subframes contain information for controlling the temporal position on an interface between the base station and the transcoding unit, with which the arrival of the subframes in the base station is controlled.

6. The method according to claim 1, in which the transmission of data between the base station and the transcoding unit takes place according to an Internet protocol (IP) method, an ATM method or a PCM method.

7. The method according to any one of claims 1 to 6, wherein the transmission capacity is allocated dynamically, a larger or smaller transmission capacity being assigned to the respective participant on the basis of a prioritization assigned to the respective subscriber and on the basis of the radio conditions determined for the respective subscriber.

8. The method according to claim 7, - in which a change in the speech coding or the modulation method or the cell is initiated for a subscriber to whom a larger or smaller transmission capacity is assigned.

9. Application of a method according to one of claims 1 to 8 in an adaptive multi rate speech codec (AMR method for wide-band or narrow-band applications) in a GERAN mobile radio transmission system.

10. Application of a method according to one of claims 1 to 8 in an enhanced circuit switched method (ECSD) for data transmission in a GERAN system