EP1266532A1 - Method for allocating resources in a radio communications system - Google Patents

Abstract

The invention relates to a method for allocating resources in a radio communications system, especially a mobile radio telephone system, according to which the resources are made available for multiple access and are different with regard to time slot and signal shape thereof. Additional data transmissions are effected during pauses in data transmissions for which dedicated channels are reserved. According to the invention, resources which are not already allocated as dedicated channels are allocated to other data sources in an uplink direction.

Description

description

Process for resource allocation in a radio communication system

The invention relates to a method for resource allocation in a radio communication system, in particular a mobile radio system, and a radio communication system designed in this way, resources of the radio interface being formed by channels which are used by the network for several connections of and to subscriber stations are made available and differ in the time position and their signal form only in a given frequency scan, and in which pauses in data transmissions further data transmissions are carried out.

Radio communication systems enable communication connections to be established between mobile or fixed subscriber stations and a base station in the network by sending data in both directions over the radio interface. For an undisturbed bidirectional connection from a subscriber station to its base station (Uplmk) and vice versa (Downlmk), frequency division duplexers (Frequency Division Duplex FDD) and time division duplex (Time Division Duplex TDD) are used. Multiple access methods are used to distinguish between several simultaneous connections between individual subscribers If several subscribers on the same carrier frequency are separated on the radio interface by different time slots, a time division multiplex procedure (Tiiτe Division Multiple

Access TDMA). In addition to time-division multiplexing, other methods for separating subscribers can be used on the radio interface, such as code division multiplex (Code Division Multiple Access CDMA), in which the signal signals are used for the purpose of unambiguously assigning clean separation spread different orthogonal code sequences over the entire bandwidth AVAILABLE under coding gain ^¬ to.

In the future Universal Mocile Telecommunication System UMTS nybride multiplexing sin .alpha provided on the basis of frequenzge ^¬ teiltem code division multiple access (Wideband Code Division Multiple Access -CDMA) and zeitgeteiltem code division multiple access (Time Division-Code Division Multiple Access TD-CDMA). The latter method is a combination of the multiple access components FDMA, TDMA and CDMA, characterized by the degrees of freedom frequency, time slot and code, the transmission in the TDD mode in the upward direction and in the downward direction taking place in a common frequency area. A variant of the TD-CDMA-Ver nrens is the Time Division-Synchron Code Division Multiple Access (TD-SCDMA " ¹ method, which, like the TD-CDMA method, can serve as an example for the use of the invention without the generality of the The TD-SCDMA method differs from the pure TD-CDMA method, inter alia, by using a precise synchronization of the received signals in the uplink, which improves the detection properties of the received signals.

The proportion of non-real-time data transmissions will increase significantly in future generations of mobile radio systems. Such non-real-time data transmissions are, for example, typical Internet traffic such as WWW (World Wide Web), FTP (File Transfer Protocol), e-mail or SMS (Short Message Service). They are based on a packet-oriented transmission of data, which is also subdivided on the time axis, but not primarily in fixed time slots, but in addressed data packets of variable length. The transmission of such data packets and the signaling of the application layer contained therein can be carried out on the radio interface effectively be realized by short, the respective data packet size at ^¬ fitted resource assignments because supply breaks-acres each data packets generally longer Ubertra- occur. Longer delays, for example, 400 ms to several seconds, for example, by non Availability at and the consequent delay in the ^¬ transmission of data packets due are in Xicht-Ecr.t- time data is unkntiscn.

Real-time Datenubertragungen, however, such as language and Videoubertragungen, are usually realized by ln ^¬ gere exclusive allocation of a resource per connection, although with them Ubertragungspa sen by however much k rzerer time, for example as a result of using egg nes VAD (Voice actvity Detector) for switching off the transmitter during pauses or fluctuations in the data rate. The reason for this resource allocation are the strict delay requirements of, for example, less than 40 ms. / Oak from the usual resource allocation methods, which cannot always be met after a short pause in transmission.

However, an efficient use of the valuable resources on the radio interface would just require "filling" the transmission pauses of the real-time connections with data from other transmissions. This applies in particular to a TD-CDMA system or a comparable system.

In a TD-CDMA method, the same basic structure is used along the time axis for each carrier frequency as the GSM (Global System for Mobile Communications) that has been introduced for some time. Due to the large bandwidth, however, up to 8 of 16 possible spreading codes can be accommodated per time slot, each of which defines a physical channel. In the following, the term resource is to be understood as the transmission capacity which is necessary for a verbmαmg is required in general m UMTS by the triple

Frequency, time slot and code is characterized. For voice transmission m UMTS is needed, for example, only ei ^¬ nen physical channel, ie, a time slot and a spreading code within a frequency band. For a 128 kbit / s data service, on the other hand, you need eight physical channels, i.e. a time slot with eight spreading codes. The ^resource can also be divided into several time slots, for example it can be divided into two for a 64 kbit / s data service for which four physical channels are required

Spreading codes can be distributed on αem one and two spreading codes on another time slot. The pooling of several individual resources into one larger transmission resource is called channel pooling. Each time slot can be assigned to the Uplmk or Downlmk.

Due to the existence of time slots, the statistical properties of the real-time connections do not permit an interference situation that is reasonably constant over time. The number of simultaneous connections per time slot, each of which e.g. B. has a duration of 625 μs, therefore results from the maximum permissible intersymbol and multiple access interference and leads to a system that is not optimally utilized most of the time.

In addition to interference (soft blockmg), a radio communication system can also be limited by the number of allocated resources. This applies, for example, to subscribers who are integrated in Circuit Switched (CS) applications. The network exclusively assigns as many dedicated channels (DCH) to each connection as is required for the transmission of the peak value of the data rate of real-time services. Allocating fixed resources is optimal if the real-time application uses the available bandwidth at all times. at c

Applications, however, where non-continuous data ge ^¬ sends its data rate but very quickly up to the maximum required data rate increase, as Sprachuber- transmission, which has an activity of 50 to 60, is reached very quickly the Svstemkapazitat and there is to the so-called Hard Blockmg.

For a better utilization of the scarce resources, a strategy has already become known which consists in the statistical multiplexing of data from different connections on one channel. The resource that becomes free during a pause in a real-time connection is allocated to another subscriber and is only to be returned to the actual owner or a resource belonging to the same channel pool as soon as it becomes active again. The data streams of different connections to be transmitted are divided into m short data blocks (bursts) of fixed length and coded and transmitted in a time-interleaved manner via a resource in accordance with the order of their arrival. Depending on their data rate, the connections are assigned a different amount of transmission capacity dynamically. However, this system places very high demands on the contemporary behavior and the reliability of the multiple access system. If the system cannot release a resource immediately, for example because the resource request is not received or because the allocation message is faulty, a collision occurs during the data transmission or data of the real-time application is lost.

In order to keep the collisions or the loss of user data to an acceptable minimum, the multiple access scheme must be designed with a lot of redundancy and security. In a TD-CDMA system this means, for example, that although 16 codes are available per time slot, only a maximum of 8 of these codes at the same time can be awarded. If more codes were assigned, this would lead to an unacceptable increase in interference in the case of voice connections in the times when all transmissions happen to be active at the same time. However, due to pauses in speech, not all 8 codes are used most of the time. This and the maximum number of codes used simultaneously for dedicated channels for this "worst case" result in unused resources. This effect of soft capacity limitation described here and its consequences can also be observed in other CDMA systems.

The invention is based on the object of specifying a method according to which, in times of non-optimal utilization of a TD-CDMA system or a comparable radio communication system, by data polling via dedicated channels, additional data from other applications are transmitted with a low signaling effort and possible mutual disturbances and the transmission capacity of the radio interface can be optimally used.

The object is achieved by the features specified in claim 1. A device for this is specified in claim 20.

Thereafter, in an introductory radio communication system m pauses in data transmissions on dedicated channels, further data transmissions are carried out in such a way that resources that are not already assigned to data sources as dedicated channels are assigned by these networks in the waiting direction. These further data transfers are preferably non-real-time data transfers, but in principle they can also be real-time data transfers. For this sends a dedicated channels-use Datenquel_e to _j eder Ubertragungspause within a data transmission, a resource request (Request) to an instance of Res ^¬ source management (Radio Resource Management) of the network 5 to which the instance mr the exclusive reserved resource allocating again.

According to another embodiment, a data source using an allocated channel indicates the end of the transmission break after each transmission break mC within a data transmission of the resource management of the network and then accesses its dedicated channel without delay. 5 A reduction in the complexity of the signaling is achieved by not using the unused resources of the data sources using data channels, but instead not using them as dedicated channels ^ er-C due to the soft capacity limitation to other data sources willing to send from the network Resources are allocated. As a result, the resources already allocated as dedicated channels remain exclusively allocated to these data sources. This means that when this activity resumes, there will be no collision with other data sources on this pessource. For this purpose, at least as many additional resources can be located as there are simultaneous data sources using inactive, dedicated channels. The number of additional resources required is only limited by the maximum number of different codes. For example, given an average 60% activity of data sources using dedicated channels, it is likely that only during 60 ** 3 = 21.6% of the time, all of these data sources are active at the same time. With a soft capacity limit of max. 8 codes non-real-time data 5 during ^ 8, 4 ^ of the time over a selection from up to more 5 unused (out of a total of 16 available) codes are transmitted.

Advantageously, thereby drove transmission errors in the resources of the access scheme not to NEN hard Kollisio ^¬ and possibly data loss, but have a maximum as a short-term interference peaks, which stem from the radio ^τ Kommunikationss are much easier to handle. This in turn can significantly reduce the demands on the performance load of the access system.

The due before. Data sources using inactive dedicated channels and additionally allocated resources are combined in a shared resource, for example the so-called Uplmk Shared Channel USCH.

Resources on this USCH are assigned to the other data sources willing to send, the assignment to the USCH preferably using one. Signaling channel, for example the so-called Uplmk Control Channel UCCH, takes place by means of a status indicator, a so-called Upmk State Flag USF.

In a further training, an assignment of the USFs to the physical USCH is carried out for each transmission period

(PUSCH) resources are sent, which are valid for the next transmission period. The necessary addressing of the PUSCH resources is communicated to the additional data sources willing to send by suitable signaling. As soon as a data source in the UCCH that is willing to send has received its USF in connection with one or more PUSCH resources, it is allowed to use this / these PUSCH resources during the next transmission period. 'send. Another embodiment provides for the number of PU3CH

Will be arranged for each welcne Ubertragungspeπode USFs in UCCH to ^¬ resources, from the network according to the activities of the data sources the dedicated channels and / or in accordance with the interference level meters to set the cell.

In an advantageous embodiment, the beginning of transmission pauses in data transmissions using dedicated channels can be transmitted to the network as inband signaling from the data sources using the dedicated channels.

In contrast, in an advantageous embodiment, the ends of transmission pauses using data channels using dedicated channels can be signaled to the network on a separate signaling channel, such as the Fast Uplmk Access Channel FUACH, by the data channels using dedicated channels.

According to a further embodiment, the beginning and end of the transmission pauses in data transmissions in the dedicated channels in front of the network are additionally or exclusively detected on the basis of interference measurements in the radio cell. In a further embodiment, a (first) interference level can be defined as a threshold for radio cells, the undershoot of which pauses in data transmissions into the dedicated channel. signals that are assigned by the network for other data transmissions.

Also, an interference level lower than the first interference level can be defined as the threshold value for radio cells, if the threshold is undershot for a certain period of time, the network assigns further (P) USCH resources to other data transmissions without signaling via the beginning of a transmission break of a data transmission in the dedicated channels.

Another embodiment provides that the USCH primarily uses the dedicated channels unused by the applications

Resources are allocated and, after these resources have been exhausted, the resources of the currently inactive applications are allocated on the dedicated channels.

In the following, the invention is explained in more detail using an exemplary embodiment with reference to graphic representations.

Show it:

1 em block diagram of a radio communication system, in particular a mobile radio system,

Fig. 2 is a schematic representation of the radio interface between subscriber stations and base stations of the

Radio communication network,

3 shows a schematic illustration of transmission resources allocated according to the invention in the upward direction, viewed over several time slots within a TDMA frame, and

4 shows a schematic representation of resources allocated according to the invention within a time slot, viewed over several TDMA frames.

The radio communication system shown in FIG. 1 and exemplarily configured as a mobile radio network consists of interlinked mobile switching devices MSC / SGSN, which at the same time have access to fixed networks such as PSTN, ISDN and IP network produce. You are at least with one facility each

RNC connected, each access to at least one of Ba ^¬ sisstation Node _B. manufactures and shear for allocating resources funktechni ^¬ is responsible.

Each base station Node B can establish connections V from unα to a large number of subscriber stations UE via a radio interface, some of which are shown as examples. Each base station node B_ forms at least one radio cell Z, which is combined with other radio cells to form a logical group of radio cells within the cellular mobile radio system.

A number of logical channels are defined for each frequency, time and spreading code selective physical channel, which are mapped onto the physical channels. They are identified by a specific parameter group. User information such as voice and data are sent for circuit-switched and packet-oriented applications via log_- see user channels (Traffic Channel TCH). Signaling information is transmitted via logical signaling channels (Control Channel CCH. The signaling channels are also used for bit and TDMA frame synchronization and possibly for packet-oriented data transmissions such as short message services (SMS, CBS).

For time-critical (Real Time RT) data transmissions, such as voice, exclusively dedicated (dedicated) logical user channels ICH are set up in the known manner for undelayed transmission. In Fig. 1, the subscriber station UE of the radio cell Z sends RT data in the upward direction to the base station Node B. The subscriber station UE. can be characterized as an RT source in this case. Em logical user channel DCH can consist of one or more physical individual resources and is very variable for the maximum values. data rates. In this mgische Nutzkanal

The transmission of time-critical data is not delayed by a transmission of non-time-critical iNon Real Time NRT) data or time-critical data from other data sources (UE UE.).

The beginning and end of pauses within RT data transmissions are signaled with suitable means "on the RT source UE of the base station Node B.

For example, the pause beginning curch be a Indand-Si- gnalisierung communicated in the assigned logical N _^ tzkanal DCH.

For this purpose, m the data blocks (bursts, m the information to be transmitted are classified after pretreatment to increase transmission security, special signaling information on the source side m the signaling component S (see FIG. 2) of a data block and received on the receiving side from the signaling component read.

The signaling for the end of the break can, according to a further embodiment of the invention, as symbolically represented in FIG. 1, by means of the subscriber-specific, dedicated

Signaling channel Fast Uplink Access Channel FUACH take place.

In addition or exclusively, a base station Node B can also determine the beginning and end of the break at the measured interference level m of the radio cell Z.

The statements made above apply mutatis mutandis to an NRT data source UE. _F or other data transmissions, preferably NRT Datenubertragungen, but also possibly RT Datenubertragungen data sources ^¬ UE UE, the invention can also be used resources that are not loading after an advantageous form already on dedicated Nutzkanalen DCH other Data sources have been assigned. According to the invention, these resources form the logical user channel Uplmk Shared Channel USCH. The referral to ^¬ a connection to the physical resource USCH-cen PUSCH is performed m one embodiment of the invention via a further signaling channel, the control channel Uplmk UCCH means of a Uplmk State Flags USF. Flags carry signaling information in a known manner within a data block to distinguish between voice and data transmissions. They will continue to be used to transfer control information to packet-oriented data services.

In the UCCH, assignments between PUSCH resources and USFs are sent per transmission period, which corresponds to the rule of the scrambling duration for real-time connections, ie 20 ms, which are valid for the next transmission period. The data sources UE UE according to FIG. 1 know the necessary addressing of the PUSCH resources for this by suitable means. For example, these are specified in the standard or are continuously "broadcast" by the base station Node B. In a further embodiment, the addressing of the PUSCH reserves can also take place when the USCH mode is transferred to the data sources UE, UE. be communicated. As soon as, for example, the NRT data source UE finds its USF in the UCCH with a connection to one or more PUSCH resources, it knows that it can send m this and only this PUSCH resource / s during the next transmission period , If your USF is not included, you may not send. The number of PUSCH resource for which per Ubertragungs ^¬ period USFs are assigned in UCCH, is determined by the base station Node-B. It depends on the one hand on the activities of the data sources on the dedicated channels, which is known to the base station Node B via the corresponding in and outband signaling, and on the other hand according to the interference level m of the radio cell Z measured by the base station Node B. That tends if the interference level m of the radio cell Z becomes too high, the base station Node B. must assume that e.g. B. some outband signaling of a data source sending on a dedicated channel regarding the "end of a transmission pause" was not received, these data sources UE started to send again and thus fewer PUSCH resources are available.

An exemplary frame structure of the radio interface of a TDD transmission operator is shown in FIG. 2. After that, a total transmission bandwidth of z. B. 20 MHz m 4 sub-frequency band Bl .. B4 divided with a bandwidth of 5 MHz. Some or all sub-frequency bands B are appropriately assigned to each radio cell. This is the FDMA component of the hybrid multiple access procedure TD-CDMA. Within each sub-frequency band B there is also a division of the time axis m TDMA frame Tr according to a TDMA component. _r3r _ constant length, for example 10 ms, instead, which in turn is divided into, for example, 16 time slots TS1 to TS16 of likewise the same length of time, for example 625 μs, with increasing numbers. The numbering is repeated in each TDMA frame. For the duration of a data transmission, e and the same time slot number TS1 to TS16 can be assigned to a subscriber station periodically in the TDMA frame interval of 10 ms. There is also the possibility of periodically changing the time slots TS according to a certain scheme (time slot hop). Each radio cell has several Ze_.t- slots allocated TS. Part of these time slots TS is used for the downlink DL from a base station to a subscriber station and part for the uplink UL. In between is a switchover point SP, which can be variably administered between the various asymmetrical distribution of the transmission resources. With Channel Poolmg a communication link are each assigned one or meh ^¬ eral individual resources dynamically, in order to realize connections with different data rates or sev- eral services to operate in parallel on a link. In ^¬ nerhalb of the time slots TS data blocks _^ bursts) are transmitted, containing in the case of normal bursts for Nutzkanale a data part D, a signaling component S and a training sequence T for channel estimation.

According to the CDMA component, the information of several connections is transmitted in a time slot TS, in that each time slot TS is spread again with a subscriber code sequence for each connection. The spreading of individual data symbols of the data D to be transmitted, in which training sequences T known at the receiving end are embedded, has the effect that within the symbol duration T- - Q data chips D chips of the duration T. be transmitted. The Q data chips form the connection-specific subscriber code. 16 spreading cooes C1 to C16 are available for each time slot TS (full slot).

The combination of a sub-frequency band B, a time slot TS and a spreading code C defines an Emzel resource as the smallest unit for the transmission of useful and signaling information.

An allocation of pesources to time slots and codes within a TDMA frame is shown as an example in FIG. 3. For this purpose, a TDMA frame n + 1 is selected. fen. According to the IC. Slitting time slot of its total of 16 time is the switching point SP between the Abwarts ^¬ distance DL and UL Aufwartsstrecke adopted. Due to the CDMA component, each time slot can be occupied by up to 8 out of 16 individual resources (codes) at the same time.

In the following, only the management of user channels on the uplink UL will be dealt with.

The RT data source UE from FIG. 1 sends real-time data

Form of speech to their base station node B. For this purpose, the code 4 in time slot 11 of the TDMA frame structure is assigned exclusively by the base station Neue B as a resource. The transmission takes place on the logical user channel DCH. The resource remains reserved for the RT data source UE even during pauses in speech. A further data source UE_ receives a transmission resource on the DCH from the base station Node B, for the transmission thereof, in the example in the time slot 13 the codes 1 to 4 and in the time slot 14 the codes 1, 3, 5 and 8. Apparently it is an NRT data transmission in the 128 kbit / s data service. The resource for the further data source UE thus lies on freely available codes and does not access the code 4 in the time slot 11 that is exclusively assigned to the RT data source UE even during transmission pauses of the RT application of UE. This is also the case if other codes and / or time slots are assigned to the further data source UE _^ by the resource management in the course of the NRT transmission.

The further data source UE_ could of course also be an RT data source and could manage with one or two codes - depending on the quality of the connection - in a time slot. In addition, in the example according to FIG. 1, an NRT data source UE requests a connection from the base station Node B1. Your ^¬ pursuant to another aspect of the invention PUSCH Res ^¬ resources allocated on the USCH. In the example, the "unused" codes 15 and 16 m are assigned to time slots 13 and 15, with which a 64 kbit / s data service can be implemented. In this way are collisions with eg the RT data ^¬ closed source UE and the NRT data source UE effectively out ^¬. This would not be reliably the case if the NRT data source UE were assigned codes 1 to 4 on the time slot 11 for the time of the transmission pauses from the RT data source UE, for example using a method according to the prior art. In addition, another NRT data source are UE. the codes 13 and 14 assigned to the time slot 13.

4 schematically shows the allocation of resources within an exemplary time slot TS13 over several TDMA frames n, n + 1, .... n + 3 to the data sources UE _, UE, UE and UE. shown.

It is shown that the number of resources available in the Uplmk Shared Channel USCH directly from the number of resources active as dedicated channels DCH per TDMA frame, or also a group of TDMA frames, e.g. B. depends on two or four TDMA frames. The maximum permitted number of resources used per time slot TS13 is assumed to be 8 in the example. The case is further shown that the data sources UE, UE using the dedicated channels DCH wait until the corresponding number of uplink shared channel (USCH) resources is no longer used. Therefore, no more than 8 resources are used at the same time. If the data sources UE, UE, which use the dedicated channels DCH, were not maintained, under certain circumstances more than 8 resources could be used simultaneously during the allocation period. For example, this could be the case when moving from TDMA frame n + 2 on the TDMA frame n + 3, provided that the data source UE_ is already sending in the TDMA frame n + 2 instead of waiting until the TDMA frame n + 3.

The Uplmk Shared Channel USCH thus contains all resources that are not used as dedicated channels DCHs. The number of resources actually used for the USCH transmission results from the transmission pauses on the dedicated channels DCHs.

Claims

claims

1. A process for Ressourcenzuteiiung m a radio Kommunι .-: a- tion systems where resources of the radio interface are formed by physical channels, which are for several Verbin ^¬ applications to and from subscriber stations (UE) in multiple access made available and m the Distinguish timing and their signal form within a predetermined frequency band, and wherein m pauses in data transmissions for which dedicated channels (DCH) are reserved, further data transmissions are carried out, characterized in that other data sources m upward direction (UL) are allocated such resources by the network which data sources are not already assigned as dedicated channels (DCHs).

2. The method according to claim 1, which also means that a data source using a dedicated channel (DCH) addresses a resource request to an instance of the resource management of the network after each transmission pause within a data transmission and this instance reassigns the exclusively reserved resource to it.

3. The method according to claim 1 or 2, characterized in that a data source using a dedicated channel (DCH) indicates the end of the transmission pause after each transmission pause within a data transmission of the resource management of the network and thereafter without delay on its dedicated channel (DCH) assigned to it accesses again.

4. The method according to any preceding claim, characterized in that that data sources sen the beginnings and ends of their Ubertragungspau ^¬ within data transmissions of a signal instance to manage resources of the network and from this punching In ^¬ determines the free resources and assigns to one or more data sources in not deduced channels.

5. The method according to the preceding claim, that a d u r c h g e k e n n z e i c h n e t that the other, non-dedicated channels using. Data sources resources are assigned to a shared resource (USCH) or a comparable user channel.

6. The method according to any preceding claim, that the assignment of other data sources to the shared resource (USCH) is carried out by the network via a signaling channel (UCCH).

7. The method according to the preceding claim, d a d u r c h g e k e n n z e i c r. It is not necessary for the network to assign other data sources to the shared resource (USCH) by means of inband signaling in the signaling channel (UCCHi).

8. The method according to any preceding claim, that the transmission of an assignment of the physical shared resource (PUSCH) and status indicators (USFs) is sent for each transmission period, which are valid for the next transmission period.

9. The method according to any preceding claim, characterized in that that the number of physical shared resources (PUSCH) for which status indicators (USFs) are assigned in the signaling channel (UCCH) for each transmission period is determined by the network according to the activities of the data sources on the dedicated channels (DCHs and / or the interference level m der Radio cell can be determined.

10. The method according to any preceding claim, d a d u r c h g e k e n n z e i c h n e t that the beginning of transmission pauses m data transmissions from the data sources are communicated to the network as inband signaling.

11. The method according to any preceding claim, that the ends of transmission pauses m data transmissions from the data sources are signaled to the network on a second signaling channel (FUACH).

12. The method according to a previous claim that the beginning and end of the transmission pauses of data transmissions on dedicated channels (DCH »are determined by the network on the basis of interference measurements in the radio cell).

13. The method according to any preceding claim, d a d u r c h g e k e n n z e i c h n e t that a first threshold value is determined with respect to the interference m of the respective radio cell, the undershoot signals pauses m data transmissions on dedicated channels (DCHs), which are assigned by the network for other data transmissions.

14. The method according to any preceding claim, characterized in that em is set lower than the first threshold, the second threshold below which the network allocates other physical shared resources (PUSCH) to other data transmissions without signaling the beginning of a transmission pause to a dedicated channel (DCH ^ using data transmission is ^¬ .

15. The method according to any preceding claim, so that unused resources are additionally allocated by the applications on the dedicated channels (DCHs) to at least one shared resource (USCH).

16. The method according to the preceding claim, characterized in that m of the shared resource (USCH) primarily from the applications on the dedicated channels (DCHs unused resources are allocated and after exhausting these resources, the resources of the currently inactive applications on the dedicated channels (DCHs ) can be allocated.

17. The method according to any preceding claim, that a resource consists of one or more codes C) on one or more time slots (TS).

18. The method according to any preceding claim, characterized in that the resources not used in dedicated channels (DCHs) are combined in a shared resource (USCH) and in that the allocation of these resources to data sources which use non-dedicated channels via one Signaling channel (UCCH) takes place.

19. The method according to any one of the preceding claims, characterized in that the other data sources which are not already assigned resources used as dedicated channels (DCHs ¹⁾ are non-real-time data sources.

20. Radio communication system, resources of the radio interface being formed by physical channels that are irrelevant for several connections from and to subscriber stations

Multiple access are made available and the time position and their signal form differ within a predetermined frequency band, and further data transmissions are carried out during breaks in data transmissions for which dedicated channels (DCH) are reserved, characterized in that other data sources in the upward direction (UL) The same resources are assigned by the network that are not already assigned to the data sources as dedicated channels (DCH).

21. Radio communication system according to claim 20, which is designed as an e mobile radio system.