WO2008023002A1 - Method for operation of a first receiving station, and method for operation of a transmitting station as well as a receiving station, a transmitting station and radio communication system - Google Patents

Abstract

In the method according to the invention for operation of a first receiving station (MS1) in a radio communication system, in which data (D) of a service comprising a first transmission signal (S1) is sent from a transmitting station (BS1) in a first radio cell (FZ1) via an air interface to the first receiving station (MS1) and to at least one second receiving station (MS2) at the same time, with the maximum usable transmission power being preset for the transmission of the first transmission signal (S1) by the transmitting station (BS1), the first receiving station (MS1) receives from the transmitting station (BS1) transmission power information (S1) from which it is possible to determine whether a transmission power limit value has already been reached, or will be exceeded by increasing the transmission power of the first transmission signal (S1).

Description

 description

METHOD FOR OPERATING A FIRST RECEIVING STATION AND METHOD FOR OPERATING A SENDING STATION IN A MULTICAST RADIO COMMUNICATION SYSTEM, AND RECEIVING STATION, SENDING STATION AND RADIO COMMUNICATION SYSTEM

The invention relates to a method for operating a first receiving station and a method for operating a transmitting station and a corresponding receiving station, a corresponding transmitting station and a corresponding radio communication system.

Point-to-multipoint connections play in radio communication systems an increasingly important role, as well as classical broadcasting services increasingly offered for mobile devices ^¬ to. This is not just about the broadcasting application (broadcasting), but also the sending of identical content to a group of users (multicasting). Radio communication systems have been optimized in the past for multiple access and thus for individual data traffic. An increase of the total capacity on the air interface is achieved by the individual control of the individual connections (eg by transmission power control). For point-to-multipoint connections in a radio cell, extended methods are needed to minimize the capacity requirements (eg transmission power) for these connections. Particularly in the case of CDMA systems (Code Division Multiple Access) is, for example, for a 95% From ^¬ cover in a radio cell for the transmission of broadcast signals, a large portion of the available transmission power of a radio station (eg, base station) is required. The use of a large amount of transmission power is only justified if a large number of Teilnehmerstatio ^¬ nen is interested in receiving the broadcast signals in fact, since in this case little capacity (power) for other services remains. Therefore, the specification of MBMS (Multimedia Broadcast / Multicast Services) in the 3GPP Third Generation Partnership Project (Universal Mobile Telecommunication System) standard, 3GPP TS 22.246 V6.2.0, and 3GPP TS 25.346 V6.6.0 is included Arrangements have been made to control the transmission of point-to-multipoint signals as needed. For multicast services, the individual participants ^¬ stations must be registered if they are interested in receiving a particular service or unsubscribe if they no longer wish to receive a service. On the network side, the subscriber stations ready to receive as a whole and also per radio cell can be counted in order to achieve an optimized transmission which is adapted to the requirements. Thus, for MBMS according to the 3GPP standard, two types of emissions are defined on the air interface:

a) Point-to-Point (P-T-P) and b) Point-to-Multipoint (P-T-M).

PTP connections essentially do not differ from other individual connections for data transmission (dedicated links). Here (data of a service) is provided on each allocated in ^¬ dividual resources (such as time, frequency and / or code) available to the individual subscriber stations of the same content, that is, the same content is sent multiple times. This procedure is justified in particular if only a few subscriber stations want to receive this service. PTP connections have the advantage of an individual connection control (link control), eg an individual transmission power control or a transmission of data of the service comprising transmission signals directed to the respective subscriber station.

The 3GPP standard provides that at elevated number of to-listening party of on the PTM operating vice scarf ^¬ tet can be. In the PTM mode, a data of the service is complete transmission signal with fixed transmission power and with mög ^¬ lichst large coverage, ie high power sent. This has the advantage that no radio resources for Übertra ^¬ conditions in the upward direction are needed (from a subscriber station to a network radio station). Thus theoretically an infinite number of subscriber stations can be served.

However, as already mentioned above, the P-T-M operation has the disadvantage that in order to achieve a high coverage, a service with a high transmission power has to be transmitted in a radio cell. This is the capacity expressed in the

Number of different services offered, not very high in PTM operation. In order to increase the capacity, ie to manage within a radio cell with low transmission power, a selective combination (soft combining) of PTM transmission signals of neighboring radio cells was introduced (3GPP TS 25.346 V6.6.0). For this purpose, selbstver ^¬ understandable necessary that in adjacent radio cells, the same service is transmitted in the PTM mode.

Another way to reduce the transmission power used within a radio cell in the PTM mode to a minimum is, for example, from EP 1,388,956 be ^¬ known, in the suggested in PTM mode subscriber stations when receiving data of a service enable broadcast signals in a radio cell to regulate the transmission power of the transmission signals by sending corresponding control signals in the upward direction. A subscriber station with poor reception quality (for example, a signal-to-noise ratio ^¬ is smaller than a predetermined threshold value) sends, evt. repeatedly, control signals to a radio station, the data of a service broadens transmitting signals in a radio cell. The radio station increases its transmission power upon receipt of a corresponding control signal until a maximum value of the transmission power is reached or until no corresponding control signals arrive. In this way, the transmission power used always corresponds to the demand that has the subscriber station with the worst reception quality within the radio cell. Will after receiving a control signal within a predetermined time Inter ^¬ Valls not receive a control signal from the radio station, the radio station decreases its transmit power successively until a control signal is received. It can thus be achieved that no more transmission power is used as needed. If, however, the maximum value of the transmission power is reached, a subscriber station, which still has a poor reception quality, either has to expect to stop receiving the data of the service or to endeavor to receive the data of the service in an adjacent radio cell. For this purpose, the subscriber station changes into an adjacent radio cell offering the service or requests the service for the neighboring radio cell if its reception quality does not improve despite repeated transmission of control signals. However, this often leads to the fact that a change takes place only when the transmission of data the service has been interrupted since particularly the An ^¬ request the transfer of data of a service in an adjacent radio cell in which the service's data is not transferred be needed, time.

It is an object of the present invention to provide methods and corresponding devices by means of which the reception of data of a service in the context of a multicast operation is alternatively or additionally provided for receiving in a first radio cell in a second radio cell, while simultaneously ^¬ a probability is reduced for the interrup ^¬ monitoring the reception of the data of the service over known methods.

This object is achieved by a method of operating a first receiving station and a method of operating a transmitting station as well as a receiving station, a transmitting station and a radio communication system according to the independent claims.

Advantageous embodiments and further developments are the subject of dependent claims. In the method according to the invention for operating a first receiving station in a radio communication system, in which a data of a service comprehensive first transmission signal from a transmitting station in a first radio cell via an air interface simultaneously to the first receiving station and at least one second receiving station gesen ^¬ det , wherein the transmitting station for transmitting the first transmission signal, a maximum usable transmission power is vorgege ^¬ ben, receives the first receiving station from the transmitting station transmission power information that can be deduced whether a threshold value of the transmission power has already been wur ^¬ de or by a Increasing the transmission power of the first transmission signal is exceeded.

The transmission power information makes it possible for the first receiving station to recognize whether it can successfully request a further increase in the transmission power of the transmitting station in the event of a reception ^quality that is too low. This is the first receiving station the opportunity before there is an interruption of receiving the data of the service due to low quality of reception of the f ^¬ th transmission signal to take action to get the data of the service continues with a reception quality are received, ^¬ gen, which enables decoding of the first transmission signal.

Advantageously, the first receiving station of the sending station to increase the transmit power used for the first transmission signal indicates if a detected by the first receiving station reception quality of the first transmitter is designals smaller than a minimum value of the reception quality ^¬ ty, and if the limit value of the transmission power even was not reached or is not exceeded by increasing the transmission power.

For signaling the increase in the transmission power of the first transmission signal, a shared Ka ^¬ nal (uplink shared channel), for example comparable by both the first receiving station as well as from other receiving stations applies. In this way, by the receiving stations that the first transmit signal, ie data of the service are received, ^¬ gen, a single radio resource shared.

The ers ^¬ te receiving station can prevent the interruption of the reception of the data of the service, when the first receiving station checks whether in a second radio cell, the same data of the service comprehensive second transmission signal is sent, if a determined by the first receiving station reception quality of the first transmission signal is less than a minimum value of the reception quality and if the limit value of the transmission power has been reached or by increasing the transmission power is exceeded.

A further development of the invention provides that the first receiving station sends a message to the radio communication system ^¬ means of which the transmission of the data of the diene ^¬ tes comprehensive second transmission signal is requested in the second radio cell. In this manner, the first receiving station may cause the transmission of the data of the service by the second transmission signal will be ^¬ begun in the second radio cell before the first receiving station no longer decode the first transmission signal in the ers ^¬ th radio cell due to lack of reception quality can.

Even with a reception quality of the first transmission signal, which is no longer sufficient to to the first transmit signal to decode ^¬ decode, may be the first receiving station advantageously receive the first transmission signal from the first wireless cell and the second transmission signal from the second radio cell and both transmitting signals before or combine after their decoding to detect the data of the service. Thereby, a decoding of the undecoded combined signal can be made possible on the one hand, or the error may be compensated based on the decoding of the second transmission signal and subsequent combination of the incorrectly decoded first transmission signal and the decoding ^¬ th second transmission signal at a faulty decoding of the first transmission signal. Advantageously, the first receiving station to Emp changes ^¬ catch of the second transmission signal from the first radio cell in the second radio cell, if or as soon as the second transmission signal is transmitted in the second radio cell. For example, the reception of the first transmission signal in the first radio cell may deteriorate such that a combination of the first and second reception signals does not result in improved reception compared to the sole reception of the second transmission signal. In this case, the first receiving station can do without the reception of the first transmission signal and switch to the second radio cell.

Advantageously, the transmission power information, a currently used transmission power and / or utilization of the transmission power with respect to the maximum usable transmission power can be removed.

For example, the first receiving station is aware of the maximum usable transmit power or a threshold below the maximum usable transmit power. In this case, the first receiving station can determine on the basis of ak ^¬ TULLE used transmission power, whether the threshold or the maximum usable transmission power has been reached or exceeded by increasing the transmit power. The transmit power information may also include a relative indication of the currently used transmit power. For example, the transmission power information can either specify explicitly or it can be inferred to what percentage the currently used transmission power utilizes the maximum usable transmission power. The receiving station can then check whether the percentage utilization of the maximum transmission power has already reached a limit value set for the percentage utilization or whether this limit value is exceeded by a further increase in the transmission power.

It is therefore advantageous if as limit the transmission Leis ^¬ processing a limit value for a currently used transmission power or a threshold value of utilization of the transmission power with respect to the maximum usable transmission power is used.

Of course, an utilization of the transmission power in terms of the maximum usable transmission power can be expressed in dB (decibels). The decibel specification is based on the maximum transmission power. Contains the signaling information for example, is set to 0 dB or the indication removably 0 dB of the signaling information, it means that the first transmission signal is transmitted with the maximum transmit power ^¬. The specification -30 dB means that the transmit power used is one-thousandth of the maximum usable transmit power.

Of course, instead of a currently used transmission power or an utilization of the transmission power with regard to the maximum usable transmission power, the transmission power information may also contain an indication which explicitly indicates that the limit value of the transmission power has been reached or the limit value of the transmission power has not been reached. In this case, the first receiving station can directly utilize this ^information without itself carrying out a comparison with the limit value, since the transmission power information already indicates the result of the comparison.

The transmission power information may be transmitted, for example, via a control channel or a paging channel, i. for example, via the MCCH (Multicast Control Channel) or the MICH (Multicast Indicator Channel), see 3GPP TS 25.346 V6.6.0.

It is particularly advantageous if the first transmit signal to ^¬ additionally comprises the transmission power information. The first transmission signal is in each case received by the first receiving station in order to decode the data of the service, so that in this way a listening of a control channel or a paging channel during the reception of the data of the service tes to receive the transmission power information is not required.

In the method according to the invention for operating a transmitting station in a radio communication system, a data of a service comprehensive first transmission signal from the transmitting ^¬ the station via an air interface in a first radio cell simultaneously to a first receiving station and at least one second receiving station ^¬ sent , wherein the transmitting station for transmitting the first transmission signal, a maximum usable transmission power is predetermined. Inventive ^¬ according to the sending station sends a transmission power Informa ^¬ tion to the first receiving station and the second are received, ^¬ constricting station, which can be removed if a limit value of the transmission power has already been reached or exceeded by increasing the transmission power of the first transmission signal.

In advantageous embodiments of the method for operating a transmitting station, the transmitting station performs those steps which are necessary for operating a first receiving station on the transmitter side to perform the process steps or variants of the method erfindungsge ^¬ MAESSEN method.

The receiving station according to the invention has all the features that are needed to carry out the method according to the invention. In particular, corresponding means for carrying out the individual method steps or method variants can be provided.

The transmitting station according to the invention has all the features that are needed to carry out the method according to the invention. In particular, corresponding means for carrying out the individual method steps or method variants can be provided. In the radio communication system according to the invention, at least one receiving station according to the invention and one transmitting station according to the invention are operated.

The invention will be explained in more detail below with reference to an embodiment shown in the figure.

A receiving station, for example, a subscriber station ^¬ a radio communication system.

A subscriber station is for example a Mobilfunkendge- advises, in particular a mobile phone or a ortsbe ^¬ wegliche or stationary device for transmitting BiId- and / or sound data, for fax, short message service SMS, multimetal TIMEDIA Messaging Service MMS and / or e-mail and / or internet access.

A transmitting station is for example a base station.

A base station is a network-based radio station that receives user and / or signaling data from a subscriber station and / or transmits useful and / or signaling data to the subscriber station. A base station is connected via network-side devices to a core network, via which connections in other radio communication systems, or in particular to ^¬ data networks. By a data network, for example, the Internet or a landline with, for example, circuit-switched or packet-switched connections for example language and / or data to understand.

Subsequently, as a receiving station, a ^subscriber station and considered sending station, a base station, without however thereby to express that the invention be limited thereto.

The invention can be advantageously used in any Funkkommunikati ^¬ onssystemen. Under Funkkommunikationssyste ^¬ men systems are to understand where a data transfer between radio stations via an air interface. The data transmission can be bidirectional as well as unidirectional. Radio communication systems are in particular ^¬ special any mobile radio systems, for example, according to the GSM (Global System for Mobile Communications) or the UMTS (Universal Mobile Telecommunications System) standard. Future mobile radio systems, for example, the fourth gene ^¬ ration, as well as ad-hoc networks are to be understood as radio communication systems ^¬. Radio communication systems are also, for example, wireless local area networks (WLANs) according to the standards IEEE (Institute of Electrical and Electronics Engineers) 802.11ai, HiperLAN1 and HiperLAN2 (HiperLAN: high performance radio local area network) as well as Bluetooth networks and broadband networks wireless access, for example, in accordance with IEEE 802.16.

The invention is described using the example of a Funkkommu ^¬ nikationssystems according to the UMTS standard, without wishing per ^¬ but to express the fact that the invention be limited thereto.

The figure shows schematically a radio communication system of which a first base station BS1, a second base station BS2, a first subscriber station MS1 and a second subscriber station MS2 are shown by way of example. Other base ^¬ stations and subscriber stations as well as the art-known line-side components of the radio communication system are not shown for clarity.

The base stations BS1, BS2 and the subscriber stations

MSl, MS2 each have a control device Pl, P2, P3, P4 by means of which control the base stations or the Teilnehmersta ^¬ functions its transmission and reception operation. In particular, the control devices also serve to encode signals to be transmitted and to decode received signals.

The first base station BS1 supplies subscriber stations which are located in a first radio cell FZ1. In the first Radio cell FZ transmits the first base station BSl means of broadcast data D of a service that are modulated onto a first transmission ^¬ signal SL and is sent via a first multi-cast channel MTCHl in the first radio cell FZ to all registered for those sen service subscriber stations. The data of the service are thus gesen ^¬ det in a multicast operation by means of a point-to-multipoint transmission. Such sent services are also referred to as multiplex services. The first transmission signal S1, which comprises the data D of the service, is received by the first subscriber station MS1 and by the second subscriber station MS2. The first subscriber station MS1 and the second subscriber station MS2 respectively decode the first transmit signal S1 and thus obtain the data D of the service. In the first transmission signal Sl included (ie, for example, at the receiving end known

Position inserted into the data D of the service) is a transmission ^¬ power information SI, which indicates for example in decibels rela ^¬ tive to a maximum transmission power, which transmission power is currently used for transmitting the first transmission signal Sl. The first base station BS1 is a maximum usable transmission power, for example, on the network vorge ^¬ ben. For example, an operator of the likely Funkkommunikati ^¬ onssystems determined for base stations, which transmission power is allowed to use a base station for transmitted in a multicast mode, via a point-to-multipoint transmission data of a service. The maximum usable transmit power can be set individually for each multicast service or receive the same value for all multicast services. An individual determination makes it possible to prioritize certain multicast services, for example, depending on the type of data transmitted. Of course, the maximum usable transmission power can be set and a maximum attainable by Sen ^¬ signaling device of the first base station BSl transmission power.

The first subscriber station MS1 and the second subscriber station MS2 are each aware of a limit value of the transmission power for the first base station BS1. The limit of transmission performance, for example, the maximum usable power transmission ^¬ the first base station BSl, or a value corresponding to a utilization of the maximum usable transmission power of for example 90%.

The first subscriber station MSl and the second ^subscriber station MS2 determine for each of the received first Sendesig ^¬ nal Sl a reception quality. When the reception quality han ^¬ delt it, for example, a respective signal-to-noise ratio or bit error or frame a respective ^¬ error rate (BER: bit error rate or FER: frame error rate). Comparing the reception quality detected the first part ^¬ subscriber station MSl and the second subscriber station MS2, respectively, with a minimum value of the reception quality. The minimum values of the respective reception quality can be the same or different. If the reception quality under the respective minimum value of the reception quality, the first subscriber station MSl and the second part ^¬ subscriber station each transmit a control signal TPC, TPC, beispiels-, via a two subscriber stations MSl, MS2 standing for this purpose available transmission channel to the first base station BSl , The control signals TPC, TPC only send the subscriber stations MS1, MS2 if they were able to determine from the transmission power information SI that the limit value of the transmission power has not yet been reached or an increase in the transmission power of the first base station BS1 on the basis of the respective control signals TPC, TPC does not lead to exceeding the limit value of the transmission power. After receiving a corresponding control signal TPC, TPC, the first base station BS1 increases the transmission power at ^{¬, for} example, by a fixed predetermined step size. Is maximum but until the maximum usable transmission power he ^¬ enough.

In the embodiment shown in the figure, the first subscriber station MSl determines in the course of the continuous reception of the first transmission signal Sl that its reception ^¬ quality is below a minimum value of the reception quality, and that the transmission power information SI can be simultaneously extracted, that the limit value of the transmission power will be exceeded by sending a further control signal TPC. The first subscriber station MS1 has thus established, for example, that a further increase in transmission power will exceed, for example, the limit value of 90% utilization of the first base station, and therefore further increase of the transmission power of the first base station BS1 only up to the maximum usable transmission power possible will be. Since the first subscriber station MS1 has determined a reception quality which is below a minimum value of the reception quality, and it is not clear whether the present reception quality will be sufficient for decoding the data D of the service even if the maximum usable transmission power is reached first parti ^¬ merstation MSl multicast channels and / or broadcast channels be ^¬ nachbarter radio cells from in particular a second radio cell FZ2, which is spanned by the second base station BS2 to determine whether there are also the data D of the service to be sent.

In this embodiment, the first ^subscriber station MSl determines for example that the data of the service D are not transmitted in the second radio cell FZ2. Therefore, the first subscriber station MS1 sends a message NA to the first base station BS1 in order to request that the data D of the service also be transmitted in the second radio cell FZ2. Due to the message NA the first Basissta ^¬ tion BS sends to a network-side device, including network controller a radio, directly or indirectly to the second base station, BS2, a service request is effected by the, in that subsequently the second base station BS2 through a second multicast channel MTCH2 a second Transmit signal S2 sends, which also includes the data D of the service. Contained in the second transmission signal S2 is also a further transmission power ^¬ information SI ', by means of which an exploitation of the transmission power used for the second transmission signal S2 with respect to a maximum available transmission power of the second basic Station BS2 is signaled. In this way, the transmission power of the second transmission signal S2 in the second radio cell FZ2 can be controlled in the same manner as described above for the transmission power of the first transmission signal in the first radio cell FZ2.

The first subscriber station is now either informed by the first base station BS1 or the second base station BS2 that the data D of the service is transmitted by means of the second transmission signal S2 in the second radio cell FZ2, or the subscriber station MS1 provides the transmission of the data D of the service by means of the second transmission signal S2 itself by listening to multicast channels of the second radio cell FZ2 fixed. The first subscriber station MSl subsequently receives the DA th D of the service both by means of the first transmission signal Sl in the first radio cell FZ and by means of the second Sig ^¬ Nals S2 in the second radio cell FZ2, the first and second transmission signal combined Sl, S2 and decodes the data D of the service based on the combined transmission signal. The transmission power of the first transmission signal Sl can not be further increased in the first radio cell, the first subscriber station MSl may send corresponding control signals TPC also in the second radio ^¬ cell FZ2 to the second base station BS2, so that the transmission power of the second transmission signal S2 is increased.

The first subscriber station MSl stops receiving the first transmission signal Sl in the first radio cell FZ2 beispielswei ^¬ se, when a combination of the first transmission signal Sl and the second transmission signal S2 over a sole reception of the second transmission signal S2 in the second radio cell FZ2 kei ^¬ ne improving Reception quality or the error rate in the decoding brings. In this case, the first subscriber station MSl changes from the first radio cell FZ1 into the second radio cell FZ2 and receives the data D of the service only by means of the second transmission signal S2.

The transmission power control of a base station can advantageously be designed such that a base station BSl, BS2 its transmission power successively, for example, in fixed predetermined steps, as long as it does not receive control signals from subscriber stations that require increasing the transmission power. It can also be provided that the transmission of data of a service is set by means of a transmission signal when no control signals for increasing the transmission power are received over a predetermined period of time.

Have the base stations BSl, BS2 via directional antennas, the data D of the service can also be radiated selectively in the direction of the subscriber stations MSl, MS2, by are used, the directions from which each control signal TPC, TPC are received, ^¬ gene are the emission directions for the transmission of the first transmission signal Sl and the second transmission ^¬ signal S2 set. Since it may happen that not all subscriber stations continuously transmit corresponding control signals, it is advantageous if the beam shaping of a base station only changes slowly with time, ie ^¬ signals or to perform the reception directions of advantage, time averaging of received control.

By using a transmission power control in a point-to-multipoint multicast mode when transferring DA of a service th (multicast service) and by the troduction ^¬ ren a limit value which, when reached or exceeded a subscriber station the alternative or additional receiving Performing data of a service received in the first radio cell in the second radio cell or first requesting the transmission of the data of the service in the second radio cell, it is achieved that data of a service in the second radio cell can be received before there is an interruption of the reception due to lack of reception quality ^¬ ty comes in the first radio cell.

The use of point-to-point connections for transmitting data of a service, which are intended for a plurality of subscriber stations, is no longer necessary, since the Here described radio communication system in point-to-multipoint operation with a minimum required ^{Sendeleis ¬} tion manages and a radio cell change is possible without interruption. Multicast services that are intended for reception by a plurality of subscriber stations can therefore, in principle, be transported at the protocol level, for example in an IP multicast mode (IP: Internet Protocol), and processed in such a way that the data of the services is transmitted in point-to-point manner. Multipoint multicast operation can be broadcast. Thus, in such a radio communication system, multicast services occupy only one radio resource and the downlink transmission signals are identical for all subscriber stations.

Claims

claims

A method of operating a first receiving station

(MSl) in a radio communication system in which a data (D) of a service comprises a first transmission signal (S1) from a transmitting station (BS1) in a first radio cell (FZ1) via an air interface simultaneously to the first receiving station (MS1) and at least one second receiving station (MS2) is sent, WO at the transmitting station (BS) for transmitting the first transmission signal (SI) a maximum usable transmission Leis ^¬ tung is predetermined, characterized in that the first receiving station (MSl) of the transmitting station (BSl) receives a transmission power information (SI), which can be deduced whether a threshold of Sen ^¬ performance has already been reached or is exceeded by increasing the transmission power of the first transmission signal (Sl).

2. Method according to Claim 1, characterized in that the first receiving station (MS1) signals to the transmitting station (BS1) (TPC) to increase the transmission power used for the first signaling designate (S1) if one of the first receiving stations (MS1) determined reception quality of the first transmission signal (Sl) is less than a minimum value of the reception quality and if the limit value of the transmission power has not yet been reached or is not exceeded by increasing the transmission power.

3. The method according to claim 1 or 2, characterized in that the first receiving station (MSl) checks whether in a second radio cell (FZ2) the same data (D) of the service comprehensive second transmission signal (S2) is sent, if one from the first receiving Station (MSI) detected reception quality of the first transmission signal (Sl) is less than a minimum value of the reception quality and if the limit of the transmission ^¬ tion was reached or exceeded by increasing the transmission power.

4. The method according to claim 3, characterized in that the first receiving station (MSl) sends a message (NA) to the radio communication system, by means of which the transmission of the data (D) of the service comprising the second transmission signal (S2) in the second radio cell ( FZ2) is requested.

5. Method according to one of claims 3 or 4, characterized in that the first receiving station (MSl) receives the first Sen ^¬ designal (Sl) from the first radio cell (FZL) and the second transmission signal (S2) from the second radio cell (FZ2) and both transmit signals (Sl, S2) combined before or after their decoding for the detection of the data (D) of the service.

6. The method according to any one of claims 3 or 4, characterized in that the first receiving station (MSL) for receiving the second transmission signal (S2) from the first radio cell (FZL) in the second radio cell (FZ2) changes, if or so ^¬ soon the second transmission signal (S2) in the second Funkzel- Ie (FZ2) is sent.

7. The method according to any one of the preceding claims, characterized in that the transmission power information (SI) a currently used transmission power and / or utilization of the transmission power with respect to the maximum usable transmission power can be removed.

8th . Method according to one of the preceding claims, characterized in that a limit value for a currently used transmission power or a limit value of utilization of the transmission power with regard to the maximum usable transmission power is used as the limit value of the transmission power.

9. The method according to any one of the preceding claims, characterized in that the first transmission signal (Sl) additionally comprises the transmission ^¬ power ^information (SI).

10. A method for operating a transmitting station (BSl) in a radio communication system, wherein a data (D) of a service comprehensive first transmission signal (Sl) from the transmitting station (BSl) via an air interface in a first radio cell (FZL) simultaneously to a first transmitting station (MSl) and at least one second receiving station (MS2) are sent, wherein the transmitting station (BSl) for transmitting the first transmission signal (Sl) is given a maximum usable transmission power, characterized in that the transmitting station (Sl) a Sendeleistungsinfor- mation (SI) to the first receiving station (MSl) and the second receiving station (MS2) sends, which is ent ^¬ detachable, if a limit value of the transmission power has already been reached or exceeded by increasing the transmission power of the first transmission signal ,

11. Receiving station (MSl) for a Funkkommunikationssys ^¬ system, comprising means for performing the method according to any one of claims 1 to 9.

12. transmitting station (BSI) for a radio communication system, with means for carrying out the method according to claim 10.

13. A radio communication system with at least one receiving station (MSI) and a transmitting station (BSI) according to claims 11 and 12.