DE10057497A1 - Method for signaling the temporal positioning of one or more broadcast channels in a UMTS radio communication system according to the 1.28 Mcps TDD mode and associated UMTS radio communication system - Google Patents

Abstract

According to the inventive method for signalling the time positioning of one or more broadcast channels (BCH1) within a number of successive frames (FRi, FRi+1), the time slot structure of an air transmission interface (FU) between at least one base station (BS1) and at least one user terminal (UE1) of an UMTS radiocommunications system in the 1.28 Mcps-TDD-mode, downlink synchronisation bursts (BU2) are modulated in at least four successive sub-frames (SFi, SFi+1, SFi+2, SFi+3) of the time slot structure QPSK.

Description

The invention relates to a method for signaling the temporal positioning of one or more broadcast channels within a variety of consecutive times Frames of the time slot structure of an air cut transmission place between at least one base station and at least one a subscriber device of a UMTS radio communication system in 1.28 Mcps TDD mode.

In a cellular radio communication system such as for example according to the GSM (= Global System for Mobile Commu nications) or UMTS standard (= Universal Mobile Telecommu nications system) is the respective subscriber device in ner momentary radio cell by means of the state there base station via at least one so-called Broadcast channel, d. H. Broadcast channel, their air section place systemically relevant information transmitted. Such sy stem-relevant information can, for example, informa functions for power regulation of the respective subscriber device, especially mobile devices or via available CDMA codes (= Code Division Multiple Access) in the current stay Halt radio cell of this subscriber device. Generally serves such a broadcast channel for transmitting so-called called cell-specific information from a base station to all participants in their radio cell mer devices, especially mobile devices. The respective Broadcast channel is a so-called common channel trained by all the mobile devices that are in the respective radio cell, constantly or in certain Intervals are intercepted. In particular, the Broadcast channel for the transmission of so-called cell-specific  Information such as Cell-Id's, etc. order for a perfect radio connection between the respective Ba sisstation and the respective subscriber device in its mo Everyone therefore hears to provide a mental radio cell Subscriber devices in this radio cell have at least one Broadcast channel at least from time to time.

The object of the invention is to find a way show how in UMTS Broadcast-Chan's 1.28 Mcps TDD mode nel information from the respective subscriber device in its current radio cell in simple and reliable ger way can be received. This task is with a Method of the type mentioned solved in that Downlink synchronization bursts in at least four the following subframes of the time slot structure QPSK (Quater nary phase shift keying), and that by this QPSK modulation the temporal position assignment for one or more broadcast channels to the successive frames and / or subframes of the Time slot structure is made.

Because the respective subscriber device through the QPSK Modulation (quaternary phase shift keying) by downlink syn chronization bursts in at least four consecutive Subframes now one or more temporal positioning subsequent broadcast channel is communicated, it is enabled for all subscriber devices in the respective radio cell light, the information about this broadcast channel in eavesdropping easier and more reliable.

The invention further relates to a UMTS Radio communication system in 1.28 Mcps TDD mode, which is used for Si Signaling the temporal positioning of one or more Broadcast channels coincide within a variety of times successive frames of the time slot structure of an air interface between at least one base station)  and at least one subscriber device after the inventions is designed according to the method.

Other developments of the inventions are in the Unteran sayings reproduced.

The inventions and their developments are as follows explained in more detail with reference to drawings.

Show it:

Fig. 1 sisstation schematic representation of the structure of a so-called Multifra mes in signal transmission on the air interface between a Ba and a subscriber unit of a radio communication system in 1.28 Mcps TDD mode of UMTS, for implementing the method according to the invention,

Fig. 2 shows a schematic representation of the temporal structure of a normal burst during a time slot, the time slot structure of FIG. 1,

Figure 3 is a schematic representation of the temporal structure of the downlink -.. The so-called synchronization bursts in the downlink pilot time slot, the time slot structure of FIG 1,

Fig. 4, the temporal structure of the so-called uplink synchronization burst time in a schematic representation on the uplink pilot slot the time slot structure of FIG. 1

Fig. 5 is a schematic representation of a Ba of the different phases as well as the associated Komple xen pointer sisbanddarstellung summarized for a QPSK and π / 4-QPSK modulation,

To Figure 6 a schematic representation of phase sequences. For four consecutive de downlink synchronization burst signal to the π / 4-QPSK encoding to each user equipment those time slots of the time frame structure of FIG. 1, the broadcast for the transfer of parts Channels are turned off, and

Fig. 7 with 10 different variants of the QPSK modulation of four consecutive downlink Synchronisati onsbursts for performing the inventive method.

Elements with the same function and mode of operation are hen in FIG. 1 with 10 each with the same reference numerals.

Fig. 1 shows a schematic and simplified presen- tation of the time frame structure in the radio transmission over an air interface FU between a base station BS1 and a subscriber device UE1 in their radio cell for a cellular radio communication system MCS. The user equipment UE1 represents a large number of user equipment that are simultaneously in the same radio cell of the base station BS1. These have been omitted here for the sake of clarity in the exemplary embodiment. Due to its cellular division, the radio communication system MCS has, in addition to the base station BS1, a multiplicity of further base stations with whose radio cells a predetermined coverage area can be largely completely covered. These white base stations have also been omitted here for the sake of clarity.

The respective base station of each radio cell is preferred by at least one radio transmitter and at least one radio recipient formed. It preferably has at least one Transmitting antenna and / or receiving antenna. In addition or regardless of their function, a radio connection to participants to provide devices of the MCS radio communication system, can the respective base station for the data / after direct transmission to an existing landline sor gene.

Mobile telephones are preferred as subscriber devices, In particular so-called cell phones or cellular telephones hen. In addition, other subscribers can also use other devices straightening and / or data transmission devices such as Internet terminals, computers, televisions, notebooks, fax devices, etc. with assigned radio unit for communication traffic "on air", that means over at least one air cut be provided and components of radio communication network. The subscriber devices can both stationary, that is to say stationary in the radio network, as well as being mobile or portable in changing locations hold.

In the cellular radio communication system MCS radio signals such as. B. messages and / or data signals via the at least one predefined air interface FU between at least at least one subscriber device such as UE1, in particular re mobile device and at least one base station such as BS1 preferably transmitted according to a time division multiple access transmission method. This is illustrated in FIG. 1 in that the time frame structure, ie the time division into a plurality of successive time slots, of a signal transmission over the air interface FU is additionally drawn in between the base station BS1 and the user equipment UE1. The radio communication system MCS is preferably designed according to the UMTS standard (= Universal Mobile Telecommunications System). In such a radio communication system according to the UMTS standard, radio signals for at least one air interface between the respective subscriber device, in particular a mobile radio device and at least one base station in at least one radio cell of the communication system, in particular according to a combined TDMA / CDMA multiple access transmission method (TDMA = Time Division Multiple Access; CDMA = Code Division Multiple Access). In this case, in the radio transmission over the air interface between the respective subscriber device and the respectively assigned base station (and vice versa), the radio signals are divided into a plurality of successive time slots with a definable time period and with a predefinable frame structure. Several participants who communicate with the base station in the same radio cell at the same time are expediently combined in combination with time division multiplexing by orthogonal codes, in particular according to the CDMA principle (Code Division Multiple Access), with regard to their message / data connections , In particular, the radio communication system is operated in the so-called TDD mode (TDD = Time Division Duplex). In TDD mode, separate signal transmission in the uplink and downlink direction (uplink = signal transmission from the respective mobile radio device to the assigned base station; downlink = signal transmission from the respectively assigned base station to the mobile radio device) by means of a corresponding separate assignment of time slots by means of a time-division multiplex method reached. In this case, only a single carrier frequency is used for signal transmission in the uplink and downlink direction between the respective subscriber device and the respectively assigned base station.

For the further development of the UMTS standard, the 1.28 Mcps (= Mega Chips) variant in TDD mode in addition to the 3.84 Mcps TDD mode and FDD mode already specified will be of interest in the future. The 1.28 Mcps TDD mode from UMTS essentially relates to the Chinese mobile radio system TD-SCDMA (Time Division Synchronous CDMA), which, like the 3.84 Mcps TDD mode, combines the techniques TDMA and CDMA. In the 1.28 Mcps TDD, data transmission from uplink and downlink is carried out on a single frequency by time division multiplexing (uplink: transmission of data from the mobile station (cell phone or similar) to the base station (= NodeB); downlink: transmission of data from the base station to mobile station). The channels are preferably separated using orthogonal codes.

The main differences from 1.28 Mcps TDD to 3.84 Mcps TDD from UMTS are the chip frequency which is one third lower and a changed frame structure. In 1.28 Mcps TDD, ten time slots (= time slots) are combined to form a subframe (= subframe) and two subframes each to form a frame (= frame). Fig. 1 shows a schematic representation of the associated respective time frame structure. There are 24 TDMA frames each, such as FRi, FRi + 1,. , .FRi + 23 combined into a so-called control multiframe such as MF1. A TDMA time frame is divided into two so-called sub-time frames (subframes). For example, the TDMA time frame (frame) FRi is subdivided into the two subframes SFi, SFi + 1. The following subframes SFi + 2, SFi + 3 are combined to form the subsequent time frame (frame) FRi + 1. Each subframe such as SFi is composed of a large number of successive time slots (time slots) such as TS0, DwPTS, GP, UpPTS, TS1 with TS6. At least one of the time slots of the respective subframe is allocated for the so-called downlink pilot channel for the transmission of at least one downlink synchronization burst or signal. The time slot DwPTS for the downlink pilot channel DwPCH1 is switched off in the 1.28 Mcps TDD mode of the UMTS. In a corresponding manner, the time slot UpPTS for at least one uplink pilot channel for the transmission of an uplink synchronization burst is reserved for the uplink direction. Between the downlink pilot time slot DwPTS and the uplink pilot time slot UpPTS, a time slot GP is provided as a so-called guard period, i.e. as a dead time, during which no transmission takes place in the uplink and downlink direction, in order to prevent mutual interference between the two transmission channels avoid the uplink and downlink synchronization bursts in the same subframe.

At least one of the remaining time slots TS0, TS1 with TS6 within the respective subframe is turned off for the so-called broadcast channel (= broadcast channel), on which radio-specific information is sent to all mobile stations in the respective radio cell from the base station serving them. In the time frame structure of FIG. 1, for example, the first time slot TS0 of each subframe such as e.g. B. SFi for the broadcast channel BCH1 fourth.

Each frame preferably has a temporal length that means duration FP of about 10 msec; a subframe is like that with in particular about 5 msec long.

In summary, the time slots of each subframe, such as SFi, for example, are used to transmit any data to be transmitted in a predefined structure, the so-called bursts. In particular, there are three types of time slots with corresponding bursts:
The so-called "normal burst" is used in the time slots TS0 with TS6 of each subframe such as SFi. In FIG. 2 schematically shows the temporal structure, or the temporal structure, ie, the time-division of a time slot, such as TS1 normal for such a burst as shown, for example, BU1. The normal burst BU1 has four time segments or time sections DA1, MA, DA2, GP1, which are reserved for the transmission of different groups of radio signal types. The first time period DA1 is allocated for the transmission of user data or user messages, so-called data symbols. After that, so-called midambels are transmitted in the second, subsequent period or block MA. These are signals for the channel estimation of the respective subscriber device and / or the respective base station. On the basis of these channel estimation parameters, channel equalization is advantageously carried out in the respective subscriber device, in particular in the respective mobile station, and / or the respective base station. After this time block MA there is again a time period DA2 for a further transmission of useful data or useful signals. The fact that the midambels for the channel estimation between the two blocks DA1, DA2 are transmitted with the useful data or useful signals largely ensures that the respective radio channel can be optimally equalized over time. Finally, during the fourth, last time period GP1 of the burst BU1, no signal transmission is carried out, that is to say this so-called guard period is unoccupied in order to avoid a security gap or dead time between the individual time slots Ts0, DwPTS1, DP To provide UPTS1, Ts1 with TS6. As a result, interfering signal overlays or interference of signals from successive slots, which could possibly occur due to differences in signal propagation time such as, for example, multipath propagation, are largely avoided. In this way, a flawless signal transmission via the air interface FU is largely ensured.

Overall, the radio transmission of a so-called normal burst (data bundle), which contains a temporal division into symbols (chips) for the first group of user data, the midambels, the second group of user data, and the guard period, can thus be considered during the respective time slot , respectively. In the 1.28 Mcps TDD mode from UMTS, the normal burst BU1 has a total length of 864 chips, which corresponds to a total duration of 675 µsec with a chip duration of Tc = 781.25 nsec. Each data block DA1 or DA2 of the burst BU1 preferably consists of 352 chips. The midambel section MA has a length of 144 chips; the guard period GP1 is 16 chips long. With the chip frequency defined in 1.28 Mcps TDD (corresponds to a chip duration of Tc = 781.25 nsec), the normal burst BU1 has a length of 675 µsec. Up to 16 bursts can be accommodated at the same time in the normal time slots TS0 with TS6, which differ in their spreading codes. Depending on the spreading factor, a different number of data can be transmitted per burst.

Fig. 3 shows schematically the time division or structure of a downlink synchronization burst BU2, which is sent during the downlink pilot time slot DwPTS of the respective subframe, such as SFi. It has a guard period, ie dead time GP2, during a first time period. This is followed by a so-called synchronization block SYNC1 as the second section section. In UMTS 1.28 Mcps TDD mode, the guard period GP2 of the downlink synchronization burst BU2 is selected to be approximately 32 chips long. A length of 64 chips is preferably selected for the synchronization block SYNC1. In this way, the down link synchronization burst in the 1.28 Mcps TDD mode has a total length of 96 chips, which corresponds to a time period of 96 Tc = 75 μsec, where Tc indicates the chip time Tc = 781.25 nsec. The respective downlink synchronization burst is always transmitted in the same pre-reserved downlink pilot time slot as DwPCH1, i.e. there is a preselected fixed assignment to the time slots of each subframe.

In a corresponding manner, the so-called uplink synchronization burst is only transmitted in a dedicated uplink pilot time slot, such as UpPTS. This uplink synchronization burst is drawn schematically with respect to its temporal structure in FIG. 4. As the first time section, it has a synchronization block SYNC2, which is followed by a guard period GP3, that is, its temporal structure is reversed from the sequence of the time sections of the downlink synchronization burst from FIG. 3. In the 1.28 Mcps TDD mode of UMTS, the synchronization block SYNC2 of Uplink syn chronization bursts are preferably approximately equal to 128 chips, and the length of the guard period is in particular approximately equal to 32 chips. The uplink synchronization burst thus preferably has a total time length of 160 Tc = 125 µsec.

Between the uplink and downlink synchronization bursts, a time slot GP is provided in the chronological sequence of time slots of the respective subframe according to FIG. 1 as an additional guard period, that is to say dead time, in order to avoid mutual interference. The length of this additional guard period GP is selected in the 1.28 Mcps mode of UMTS preferably approximately equal to 96 chips.

Two digital modulation methods are defined for the current 1.28 Mcps TDD mode: QPSK (Quaternary Phase Shift Keying) and π / 4-QSPK. Modulation here means changing the high-frequency carrier signal as a function of the data to be transmitted. QPSK is used to transfer the data in normal burst data blocks. For this purpose, two data bits are combined to form a data symbol. These then modulate the carrier signal, for example with the phase 0 °, 90 °, 180 ° or 270 °. In contrast, π / 4-QPSK is used for the transmission of the data in the synchronization block of the downlink synchronization burst. π / 4-QPSK is a 45 ° shifted version of QPSK, so that in this case the phase of the carrier signal is modulated, for example, at 45 °, 135 °, 225 ° or 315 °. These different phases PH in the baseband can be in a mathematically advantageous way as shown in FIG. 5 complex pointer KZ with real and / or imaginary assign. In particular, e.g. B. the phase 0 ° of the complex pointer KZ = 1, the phase PH = 45 ° of the complex pointer KZ = 1 + j, etc. assigned.

The downlink pilot time slot such as B. DwPTS of the respective subframe such. B. SFi is for the transmission of the downlink pilot channel such as B. DwPCH1 turned off. The downlink synchronization code C _{DL, sync} modulated with π / 4-QPSK is transmitted to this downlink synchronization channel. In the 1.28 Mcps TDD system, a total of 32 different downlink synchronization codes are preferably defined, with which the individual radio cells of the radio communication system can be distinguished. The respective base station sends its synchronization code in its radio cell on the downlink pilot channel, such as DwPCH1. This enables a mobile station in the radio cell of this base station to synchronize itself with respect to the time clock of this base station, that is to say to adapt to the time frame sequence and time slot structure of the air interface transmission point specified by the base station. Furthermore, with the π / 4-QPSK modulation of the respective synchronization code, the respective subscriber device in the radio cell of the respective base station receives the temporal position of the broadcast channel such as BCH1 within the time frame structure, in particular within the respective control multiframe such as MF1 signaled.

Multiframes are organizational structures of time frames, with which it is determined at what intervals, in what frames and / or how often the physical channels be sent. For example, in 1.28 Mcps TDD mode for the Primary Common Control Physical Channel P-CCPCH a so-called named control multiframe with 24 TDMA frames defined that  is called in 24 consecutive TDMA frames ne certain number of P-CCPCH (Primary Common Control Phy sical channel) with a definable interleaving Period, here of about 20 msec in the downlink direction. This interleaving period of 20 msec corresponds to 1.28 Mcps TDD mode preferably the duration of 2 frames or 4 subframes. The interleaving period gives that temporal spread of the data transmitted on the P-CCPCH on. The reason for this time spread lies in particular re in that the capacity of a single burt is not sufficient to broadcast all broadcast information within one to transmit subframes.

The Primary Common Control Physical Channel P-CCPCH on phy The broadcast channel BCH is on the physical level Assigned transport level.

Since system-relevant information of the respective radio cell, such as information on power control or available CDMA codes, is transmitted from the respective base station to the mobile stations in this radio cell via the broadcast channel, it is desirable that all subscriber devices located in a radio cell , especially mobile stations, can receive this broadcast channel largely perfectly. Therefore, the base station responsible for the respective radio cell expediently sends this broadcast channel from time to time, preferably at periodic intervals in the form of the control multiframes. To receive this broadcast information, all subscriber devices in this radio cell listen to this broadcast channel from time to time, in particular periodically. In order to be able to correctly detect the broadcast information that the respective base station sends into its radio cell from the subscriber device present there, it is advantageous to provide the respective subscriber device with information about when, where and how often the broadcast channels are sent within a control multiframe by the responsible base station. Because of the interleaving period, i.e. the temporal spread of the physical primary control physical channels P-CCPCH assigned to the respective broadcast channel (here of about 20 msec), it is expedient to have downlink synchronization bursts in at least 4 successive ones To modulate subframes such as SFi, SFi + 1, SFi + 2, SFi + 3 (see FIG. 1) QPSK and thereby assign these 4 subframes a specific phase sequence for coding the temporal position of the broadcast channel in the multiframe. The respective subscriber device can then use QPSK demodulation of the downlink synchronization bursts that arrive at the subscriber device in at least four consecutive subframes during the downlink pilot time slot DwPTS to assign a position in time for one or more subsequent broadcast channels to the successive frames and / or make subframes of the time slot structure. Because of the interleaving period of the broadcast channel or the corresponding primary communication control physical channel, it is expedient for the respective subscriber device to determine the position in time, that is to say to listen to the broadcast channels correctly within the multiframe time frame structure, a sequence of evaluate at least 4 phases, which can be achieved by demodulating downlink synchronization bursts from at least 4 consecutive downlink pilot channels. Because the duration of a subframe is a quarter of the interleaving period of 20 msec.

Fig. 6 shows a schematic representation of phase sequences for 4 consecutive downlink synchronization burst. The respective phase sequence of 4 individual phase values is designated with PS each. The respective phase sequence is uniquely assigned system frame numbers based on the mathematical relationship (SFN / 2) mod 8. Each of the 8 different phase sequences thus corresponds uniquely to a system frame number SFN. For example, the start of an interleaving period with a phase of 45 ° is indicated for the table according to FIG. 6. The numbering of the frames within the multiframe runs from 0 to 23. The current position in the multiframe is displayed with the counter ZSFN (System Frame Number Counter). For example, the phase sequence 45 °, 225 °, 225 °, 225 ° signals that the broadcast channel is sent in frames 0, 1, 16 and 17. In these cases (SFN / 2) mod 8 = 0. The phase sequence 45 °, 225 °, 225 °, 315 ° signals that the broadcast channel is being sent in frames 14 and 15 . In these cases, (SFN / 2) mod 8 = 7. If the subscriber device cannot detect any of the phase sequences defined in the table in FIG. 6, it advantageously repeats the process for determining the position at the next possible time, that is to say when the next downlink synchronization bursts. This is because, at the same time, the time slot structure according to FIG. 1 is also determined for the respective subscriber device.

The table according to FIG. 6 corresponds to the situation with a π / 4-QPSK modulation of the downlink synchronization bursts. By subtracting 45 ° at the specified phase sequences, you get the conditions for the QPSK modulation of the downlink synchronization bursts.

In summary, the invention is considered Process the temporal positioning of one or more Broadcast channels are timed within a variety of times successive frames of the time slot structure of an air interface to the respective subscriber device signals that downlink synchronization bursts in at least 4 consecutive subframes of the time slot structure QPSK can be modulated. Through this QPSK modulation can then the time position assignment for one or several broadcast channels following in time at the time consecutive frames and / or subframes of time slit structure can be made. By simply a single common type of modulation for both the data  in the normal bursts as well as in the downlink synchronisa is used, the implementation is reduced demodulation in the receiver of a participant devices compared to the previous implementation two different types of modulation (QPSK and π / 4-QPSK). because through both the signal processing and the hard would be simplified. Two different modulation methods for the data of the normal bursts and for the downlink syn Chronization bursts would be particularly in the downlink transfer lead to too much effort because in the downlink resources are scarcer than in the uplink. Because the respective Subscriber devices usually load a larger data stream from the base station when it is in the uplink direction to Base station sends. By the method according to the invention unnecessary complexity is avoided. simultaneously will be a harmonization with the other two UMTS modes brought about, which also use only QPSK.

The Fig. 7 with 10 illustrate by way of four Tabel len four variants to the QPSK modulation of downlink bursts Synchro tion. In the left column of each table, a sequence of frame numbers is coded in each case unambiguously by the mathematical formula (SFN / 2) mod 8. Sequences of system frame numbers SFN are uniquely assigned to these frame code numbers 0 to 7 in accordance with the table in FIG. 6. These frame number sequences each indicate the frames over which the respective broadcast information is transmitted in a time-distributed manner. These sen code numbers 0 with 7 are each assigned a phase sequence of four phases in complex notation, with which the downlink synchronization bursts of 4 consecutive subframes SFi, SFi + 1, SFi + 2, SFi + 3 are each QPSK-modulated. The phase sequences according to the table in FIG. 7 are chosen offset by -45 ° with respect to the phase sequences in FIG. 6. The phase sequences according to the table of FIG. 8 are offset by + 45 ° with respect to the phase sequences of the table of FIG. 6. The phase sequences corresponding to the tables in FIGS . 9 and 10 are finally rotated by + 135 ° and -135 ° compared to the phase sequences in the table of FIG. 6.

The table according to FIG. 7 shows the QPSK modulation of the downlink synchronization bursts of four successive downlink pilot channels for signaling the positions of the broadcast channels in the 24th control multiframe. The QPSK modulation is represented by the multiplication of the down link synchronization bursts with the corresponding complex pointers according to the table in FIG. 6 minus the phase of 45 °. The start of the interleaving period is indicated by the phase 0 ° or the factor 1. For example, the phase sequence 0 °, 180 °, 180 °, 180 ° (corresponds to the sequence C _{DL, sync} , -C _{DL, sync} , C _{DL, sync} , -C _{DL, sync} signals that the broadcast Channel is sent in frames 0, 1, 16 and 17. C _{DL, sync} represents the respective downlink synchronization burst, which represents a specific synchronization code.

The table corresponding to FIG. 8 shows the QPSK modulation of the downlink synchronization bursts of four successive downlink pilot channels. The start of the interleaving period is indicated by the phase 90 ° or by the factor + j. For example, the phase sequence 90 °, 270 °, 270 °, 270 ° (corresponds to the sequence + j C _{DL, sync} , -j C _{DL, sync} , _- j C _{DL, sync} , _- j C _{DL, sync} ) that the broadcast channel is sent in frames 0, 1, 16 and 17.

The table according to FIG. 9 shows the QPSK modulation of the downlink synchronization bursts of four successive downlink pilot channels in accordance with a third variant. The start of the interleaving period is indicated by the phase 180 ° or by the factor -1. For example, the phase sequence 180 °, 0 °, 0 ° / 0 ° (corresponds to the sequence -C _{DL, sync} , C _{DL, sync} , C _{DL, sync} , C _{DL, sync} ) signals that the broadcast channel is in frames 0, 1, 16 and 17 are sent.

According to the fourth variant according to the table in FIG. 10, the start of the interleaving period is indicated by the phase 270 ° or by the factor -j. For example, the phase sequence is 270 °, 90 °, 90 °, 90 ° (corresponds to the sequence -j C _{DL, sync} , + j C _{DL, sync} , + j C _{DL, sync} , + j C _{DL, sync} ) that the broadcast channel is sent in frames 0, 1, 16 and 17.

An advantageous exemplary embodiment according to the first variant can in particular be carried out as follows:
Based on the frame structure according to FIG. 1, the broadcast channel P-CCPCH is sent in time slot TS0 and the down link synchronization channel DwPCH1 in DwPTS. Furthermore, a 24-channel control multiframe is defined in the radio cell, which sends the broadcast channels in frames 0, 1, 16 and 17 in the downlink direction. Accordingly, the base station in the respective frames will modulate the downlink synchronization bursts or synchronization codes C _{DL, sync} with the factors +1, -1, -1 and -1, which are transmitted to the DwPCH to determine the position of the broadcast Display channels in the multiframe to the respective subscriber device, in particular the respective mobile station. The start of the interleaving period is identified by the phase 0 ° or the factor 1. All the subscriber devices in the radio cell now listen to the downlink synchronization channel. If the subscriber devices can detect the phase sequence 0 °, 180 °, 180 °, 180 ° (corresponds to the sequence C _{DL, sync} , -C _{DL, sync} , C _{DL, sync} , -C _{DL, sync} ), they know in which frames / time slots the broadcast channels are sent within the control multiframe, and can in future specifically, periodically, listen to the broadcast channels at these positions.

Analogously to this exemplary embodiment, 4 can also be used for the remaining variants 2 above.

Claims (10)

1. Method for signaling the temporal positioning of one or more broadcast channels (BCH1) within a multiplicity of frames (FRi, FRi + 1) of the time slot structure of an air interface transmission point (FU) between at least one base station (BS1) and at least one subscriber device (UE1) ) a UMTS radio communication system in 1.28 Mcps TDD mode, characterized in that
that downlink synchronization bursts (BU2) are modulated in at least four successive subframes (SFi, SFi + 1, SFi + 2, SFi + 3) of the time slot structure QPSK (quaternary phase shift keying),
and that this QPSK modulation is used to assign the position in time for one or more consecutive broadcast channels to the consecutive frames and / or subframes of the time slot structure. 2. The method according to claim 1, characterized, that as a subscriber device, a mobile radio device (UE1), in particular mobile phone is used. 3. The method according to any one of the preceding claims, characterized, that the downlink synchronization bursts (BU2) in sequence of at least four subframes by QPSK modulation specific phase frequency is assigned by which the Numbers (SFN) of those frames and / or subframes communicated in which parts of the respective broadcast channel (BCH1) be be provided. 4. The method according to any one of the preceding claims, characterized, that for the message signals and / or data signals that via the air cut transmission point (FU) from the respective  Base station (BS1) to the respective subscriber device (UE1) in their radio cell are also sent, the QPSK Modulation is used for coding. 5. The method according to any one of the preceding claims, characterized, that each 24 frames of the time slot structure to a Kon troll multiframe (MF1) can be summarized. 6. The method according to any one of the preceding claims, characterized, that a broadcast channel (BCH1) on at least four Subframes (SFi, SFi + 1, SFi + 2, SFi + 3) are distributed over time is spread. 7. The method according to any one of the preceding claims, characterized, that the respective broadcast channel (BCH1) on the physical P-CCPCH (primary common control phy sical channel) is transmitted. 8. The method according to any one of the preceding claims, characterized, that the respective downlink synchronization burst (BU2) the physical transmission channel DwPCH (Downlink Pilot Channel) is transmitted. 9. The method according to any one of the preceding claims, characterized, that the start time of the interleaving period of the respective broadcast channel (BCH1) in the same radio cell through the same, predefined phase of the received downlink Synchronization bursts (BU2) is displayed. 10. UMTS radio communication system in 1.28 Mcps TDD mode for signaling the temporal positioning a or multiple broadcast channels (BCH1) within a variety of  successive frames (FRi, FRi + 1) of time slot structure of an air cut transmission point (FU) between at least one base station (BS1) and at least one nem subscriber device (UE1) according to one of the preceding An is trained.