WO2004088877A2 - Data transmission in a mobile radio system - Google Patents

Abstract

The invention relates to a method for transmitting data through a common radio channel established between a base station (BS) and a plurality of terminals (UE), respectively in a mobile radio system. According to said invention, data are successively transmitted and distributed towards the predefined time-slots of said radio channel, and one or several time-slots are assembled in the form of a transmission frame. The length of said transmission frame in the radio channel is equal to n time-slots in ascendant and descendent liaisons during the transmission between the terminal and the based station. The inventive method is characterised in that n is a natural number ranging from 1 to 5.

Description

description

Process for the transmission of data

The invention relates to a method for transmitting data on a common radio channel according to the preamble of claim 1.

If a connection between terminals and a base station is established in a communication system via shared resources, access collisions between different terminals can occur if several terminals access the same connection resource. Depending on the specific case, there are various solutions for this problem.

The problem is described below using an example from the UMTS system for packet data transmission. For possible explanations of terms or a more detailed description, please refer to the description of the figures.

The physical random access channel or "Physical Random Access Channel" PRACH is a so-called common channel or "common channel" on which in principle all terminals within a cell share for the transmission of

Can use signaling information as well as user data. Up to 16 different PRACHs are currently configured on a cell. The access of a terminal to the PRACH is regulated according to the random access procedure "Slotted ALOHA", in which each terminal is only allowed to send data to the randomly selected PRACH at the beginning of specified time intervals. Collisions can occur due to simultaneous sending terminals, i.e. their data packets interfere with each other, so that they are faulty in the terrestrial access network for UMTS or

"Universal Terrestrial Radio Access Network" UTRAN can be received. In the case of one to be confirmed Packet data transmission, which is requested via the PRACH, the sending terminal waits for a confirmation from the UTRAN via the secondary common control physical channel or "Secondary Common Control Physical Channel" S-CCPCH as a separate return channel. The UTRAN checks all received data packets for possible transmission errors and sends the respective test result to the terminal via the S-CCPCH, whereby a positive confirmation or ACK (acknowledgment) is transmitted for an error-free received data packet, or a negative confirmation for an incorrectly received data packet NACK (Negative Acknowledgment). If the terminal receives a message that a certain data packet was transmitted incorrectly, the terminal repeats the transmission for the incorrectly sent data packet on the PRACH after randomly selected waiting times. Randomness minimizes the risk of renewed access collisions. As long as the number of terminals accessing the same PRACH in a cell is moderate, the slotted ALOHA access method works well. But as soon as the number of

Terminals increases, the risk of an increasing collision risk increases with the traffic load in the cell, which is further increased by the retrans ission as a result of faulty data transmissions. This leads to a delay in data transmission or to a deterioration in data throughput and to additional interference in the uplink. In the worst case, only collided data packets are transmitted over the channel, so that the data throughput drops to zero.

Starting from this prior art, it is an object of the invention to increase the efficiency of packet data transmission for a shared radio channel even in the event of higher traffic loads. This object is achieved by a method according to the features of claim 1. Advantageous further developments can be found in the subclaims.

It is the essence of the invention in a method for

Data transmission to shorten transmission frames in a radio channel shared by a number of terminals to a base station compared to the hitherto customary ones, the length being in particular 1 to 5 time slots. The shortening takes place in particular already in the physical layer. This has the advantage that in the event of collisions or other transmission errors, fewer data bits have to be transmitted repeatedly.

This transmission frame length can be selected depending on the quality of the radio channel. Depending on the type of quality determination, for example, promptly or averaged, the radio operation can be optimized in a way adapted to the respective transmission conditions. So in the case of poor channel quality

Transmission frame length can be chosen shorter.

In particular, the efficiency of packet data transmission can be further increased by also using multicode transmission, i.e. the use of multiple spreading codes for

Transmission, on this shortened frame is provided.

This has the advantage, for example, that the amount of data in

Can be flexibly adjusted depending on the channel status.

The number of spreading codes can also be adapted to the channel quality in order to adapt to the transmission conditions.

Such a method is particularly suitable for packet-oriented transmission since the conditions can be reset for individual packets or parts of packets. In a packet data transmission it can be provided that a data part and a control part for control information are provided in a packet. Depending on the type of transmission or, for example, the proportion of control part or data part, a different or the same number of spreading codes can be provided for these parts.

A base station or a terminal which is suitable for carrying out the method described above or an embodiment thereof has, in addition to one

Transceiver device on a suitably set up processor unit.

A communication network in which one of the methods described above can be carried out comprises at least one such terminal and one such base station.

Preferred embodiments of the invention are described below with reference to figures.

Show it:

1 shows a schematic sequence of a data transmission on the PRACH, in particular in the UMTS-FDD mode;

Figure 2 shows a frame structure for the PRACH message part according to the prior art; Figure 3 shows a frame structure for the S-CCPCH according to the prior art; Figure 4 shows a subframe structure with a

Transmission time length TTI from a time slot; FIG. 5 shows a subframe structure with a transmission time length TTI of two time slots; FIG. 6 shows a subframe structure with transmission time length TTI of three time slots; FIG. 7 shows a subframe structure with transmission time length TTI of four time slots; Figure 8 with a subframe structure

Transmission time length TTI of five time slots;

FIG. 9 shows a subframe structure for the PRACH

Message part in the case of a single code transmission; FIG. 10 shows a subframe structure for the PRACH

Message part in the case of a multicode transmission;

FIG. 11 shows a subframe structure for the S-CCPCH in the

In case of multicode transmission;

FIG. 12 shows a subframe structure in the case of a single code transmission on the PRACH message part;

Figure 13 shows a subframe structure in the case of a

Single code transmission on the S-CCPCH;

FIG. 14 shows a subframe structure in the case of a

Multicode transmission on the PRACH message part; 15 shows a subframe structure in the case of a

Multicode transmission on the S-CCPCH.

The figures are summarized in groups, of which Figure 1 shows a schematic diagram of a transmission, Figures 2 and 3, the frame structure for the PRACH message part and the S-CCPCH. Figures 4 to 8 show subframe structures with different transmission time lengths. Figures 9 to 11 relate to the subframe structure with regard to single code or multicode transmissions. FIGS. 12 to 15 again show the subframe structures with regard to single or multicode transmissions, but for selected codes.

First, the following explanations of terms are to be given to explain the background of the invention.

1. Definitions

A communication system or communication network is a structure for exchanging data. This can be, for example, a cellular mobile radio network, such as the GSM network (Global System of Mobile Communications) or the UMTS network (Universal Mobile Telecommunications System). Terminals and base stations are generally provided in a communication system and connect to one another via a radio interface. In UMTS that points out

Communication system or radio transmission network at least base stations, here also called NodeB, and radio network control units or radio network controller (RNC) for connecting the individual base stations. The terrestrial radio access network or "Universal Terrestrial Radio Access Network" UTRAN is the radio-technical part of a UMTS network in which, for example, the radio interface is also made available. A radio interface is always standardized and defines the entirety of the physical and protocol specifications for data exchange, for example the modulation method, the bandwidth, the frequency swing, access methods, security procedures or switching techniques. The UTRAN thus comprises at least base stations and at least one RNC.

In cellular mobile radio systems, various radio transmission technologies can be provided which define how the physical connection resources are divided. In the case of UMTS, a frequency multiple access mode or Frequency Division Duplex (FDD) mode is currently provided, as well as different time multiple access modes or Time Division Duplex (TDD) modes. In the FDD mode, the data transmission of so-called “up-” and “downlink” connections on different frequencies takes place by frequency multiplex, while in the two TDD modes the data transmission of up- and downlink on the same frequency takes place by time multiplexing.

A base station is a central unit in a communication network, which in the case of a cellular

Mobile radio network Terminals or communication terminals within a cell of the mobile radio network via or operated several radio channels. The base station provides the air interface between the base station and the terminal. It handles the handling of radio operations with the mobile participants and monitors the physical radio connection. In addition, it transmits the user and status messages to the terminals. The base station has no switching function, only one

Supply function. A base station comprises at least one transmitting / receiving unit.

A terminal can be any communication terminal via which a user communicates in a communication system. For example, mobile terminals such as mobile phones or portable computers with a radio module are included. A terminal is often also referred to as a "mobile station" (MS) or in UMTS "user equipment" (UE).

In mobile communications, a distinction is made between two connection directions. The downlink or "downlink" (DL) denotes the direction of transmission from the base station to the terminal. The uplink or "uplink" (UL) denotes the opposite direction of transmission from the terminal to the base station.

In broadband transmission systems, such as a UMTS mobile radio network, a channel is a sub-area of an available total transmission capacity. In the context of this application, a wireless communication path is referred to as a radio channel.

In a mobile radio system, for example UMTS, there are two types of physical channels for the transmission of data: permanently assigned channels or "dedicated channels" and shared or "common channels". With dedicated channels, a physical resource is only used for

Transfer of information reserved for a specific terminal. Common channels can provide information transmitted, which are intended for all terminals, for example the primary common physical control channel or "Primary Common Control Physical Channel" (P-CCPCH) in the downlink, or all terminals share a physical resource by each terminal only for a short time may use. This is the case, for example, with the physical random access channel or "physical random access channel" (PRACH) in the uplink.

In the case of transmission via a common or dedicated channel, in addition to bandwidth spreading by means of a spreading code or "channelization code" for more robust transmission, the data is also subjected to a scrambling or "scrambling" procedure to identify a specific connection. Depending on the direction of transmission, the type of channel and the radio transmission technology, different types of scrambling codes or "scrambling codes" are used. While a bit from a data sequence is usually referred to as a symbol, a bit of a bandwidth-spread sequence is referred to as a chip.

In mobile radio systems such as UMTS, in addition to circuit-switched or "circuit switched" services, packet-oriented or "packet switched" services are also provided.

In particular in mobile radio systems of the 2nd or 3rd generation, such as the GSM or UMTS, the data transmission via the radio channel generally takes place in a predetermined time structure, the transmission frame, which is often also referred to as a frame. A transmission frame thus represents the periodic basic time structure with which data is physically transmitted. In UMTS, a frame is 10 ms. To perform certain functions, such as channel estimation and performance control, a frame is divided into time slots, for example in UMTS in 15 time slots. A time slot is therefore a fixed time segment within a transmission frame.

On the basis of the temporal structure, consisting of frames and time slots, further temporal substructures, for example subframes or "subframes", can be defined. For example, one could define a subframe in UMTS, which should include three time slots, so that a frame is then composed of 5 subframes.

A transmission frame length or a

Transmission time interval (TTI) denotes the length of time over which data that were encoded together due to a scrambling, e.g. a so-called "scrambling" or "interleaving", spread out over time. For example, a TTI can be specified in relation to time slots. In particular, the transmission time interval in which data from the medium access layer or medium access layer (MAC) (OSI layer 2, OSI: Open System Interconnection) to the physical layer (OSI layer 1) in the form of so-called transport blocks ( = Combination of data packets of fixed length) are transmitted. Furthermore, the transmission time interval in which the data are then physically transmitted via the air interface can be designated, for example.

For example, in the case where TTI = 40 ms applies, data is sent every 40 ms from the MAC layer to the physical layer. On the other hand, this data is then transmitted by the physical layer within 4 frames.

2. Problems in the prior art

It has now been found that random collisions on common channels can occur when terminals are transmitting to a base station at the same time. This is what follows using a common channel, the Physical Random Access Channel PRACH in the UMTS system:

According to the current UMTS standard Release 5, the PRACH and the S-CCPCH in FDD mode are specified as follows: The PRACH is specified for the uplink transmission of burst-like data traffic up to 120 kbps (kilobits per second) as a gross data rate. The PRACH consists of a preamble part and a message part, via which the useful information or "pay load" is transmitted. In principle, all terminals within a UMTS cell can use the PRACH together to transmit signaling information and user data. The access of the terminals to the PRACH is regulated according to the random procedure "Slotted ALOHA", in which each

Terminal is only allowed to send data on the PRACH at the beginning of specified time intervals. The random access transmission consists of one or more preambles with a length of 4096 chips and the actual message in the message section.

Transmission time lengths of 10 or 20 ms Transmission Time Interval (TTI) are defined for the PRACH message part. In the optimal case, the message on the PRACH message part only has to be transmitted once, namely when the data transmission procedure described in FIG. 1 does not experience the described detection difficulties. After the spreading with the spreading code, the PRACH message part is scrambled or "scrambled" for identification with a specific scrambling code with a length of 38400 chips, which corresponds to a length of 10 ms. The scrambling or "scrambling" is used to identify the data so that different connections or data transmissions can be separated.

FIG. 1 schematically shows a sequence of a random access data transmission to be confirmed between a terminal UE and the UTRAN comprising at least one base station shown. This process can run simultaneously for several UE terminals. The data can be a message, for example. The arrows from the UE terminal to the UTRAN indicate a transmission on the PRACH, the arrows from the UTRAN to the UE terminal indicate a transmission on the S-CCPCH or AICH. On the S-CCPCH, data, i.e. signaling information or user data, is sent to the terminal via the air interface. Transmission times of 10, 20, 40 or 80 ms are also defined as TTI for the S-CCPCH. The S-CCPCH is also scrambled after the spread, this time with a line-specific first or "primary" or a second scrambling code or "secondary scrambling code" with a length of 38400 chips, which in turn corresponds to a time of 10 ms. A second scramble code is required if the number of first scramble codes is insufficient for the number of connections in the cell.

In terms of protocol, the data from higher protocol layers is transmitted via transport channels, for example the

Forward access channel FACH and / or the paging channel PCH are transmitted to the physical layer, where they are then mapped or mapped onto the physical channel S-CCPCH.

In the case of a packet data transmission to be confirmed, i.e. that the receipt of a packet is confirmed by the recipient is sent by the UTRAN via the forward access channel FACH

Confirmation message to the UE terminal.

The random access data transmission method shown in Figure 1 now includes the following steps:

1. Before the actual data transmission, for example message transmission, begins, the terminal UE sends a randomly selected preamble of 4096 chips in length to the UTRAN. If the UTRAN can correctly detect the preamble, it sends a positive confirmation (ACK) on the access indicator channel or "acquisition indicator" Channel "(AICH) to the UE terminal. If the UTRAN cannot correctly detect the preamble, it sends a negative confirmation (NACK) on the AICH to the UE terminal. It is now assumed that the UTRAN does not correctly match the preamble sent by the UE terminal can detect.

2. A NACK on the AICH is thus sent back to the UE terminal.

3. After a randomly selected waiting time, the terminal UE sends a new, randomly selected preamble to the UTRAN. This preamble is now a little higher

Power sent than when the first preamble was sent.

4. This time it should be assumed that the UTRAN correctly detected the preamble sent by the UE terminal. An ACK is thus sent back to the UE on the AICH.

5. The transmission power for the following PRACH message part is set on the basis of the transmission power of the successfully sent preamble. The terminal UE sends the message on the PRACH message part to the UTRAN as soon as possible and waits for a confirmation via the S-CCPCH.

6. In the event that the UTRAN was able to receive the message sent by the UE on the PRACH message part without errors, an ACK is sent back via the S-CCPCH, which ends the random access transmission.

On the PRACH message part, a message, for example signaling information or user data, is sent to the UTRAN via the air interface. In terms of protocol, the message is transmitted from higher protocol layers via the RACH transport channel to the physical layer, where it is then mapped or mapped onto the physical PRACH message part.

FIG. 2 shows the frame structure for the PRACH message part as it is in the prior art is used. The radio frame or radio frame of the message part comprises a time of 10 ms. This radio frame is divided into 15 time slots S # 0 to S # 14. Each time slot contains a data part D and a control part C. The control part is in turn divided into a pilot section P and a transport format combination indicator section TFCI. Only specific control information of the physical layer is sent on the control part, such as “pilot bits” for channel estimation and “TFCI bits” as a transport format combination indicator for the data part. The actual message is sent from the RACH transport channel on the data part. The number of data bits transmitted on the control and data part per frame or time slot Npiio, N _TF cι, N _Da ta results from the spreading factor (SF) of the OVSF spreading code used (OVSF Orthogonal Variable Spreading Factor) and the im Uplink used modulation type BPSK (Binary Phase Shift Keying). The control part is always spread with a spreading code with a spreading factor of 256, so that 10 bits in one

Time slot of length 2560 chips are transmitted. Spreading codes with a spreading factor of 32, 64, 128 or 256 are possible for the data part. This means that at least 10 bits with a spreading factor of 256 to a maximum of 80 bits with a spreading factor of 32 can be transmitted per time slot with a length of 2560 chips. This is also shown in Table 1 below.

Table 1: Number of bits per frame or time slot in

The data part and the control part are transmitted via a so-called IQ code multiplexing, ie the data part D is transmitted to the I branch (real branch) and the control part C to the Q branch (imaginary branch), which are each out of phase with one another are. Since the imaginary branch and the real branch do not interfere with each other, the values can be sent in parallel.

FIG. 3 shows the corresponding frame structure of a radio frame of the S-CCPCH as used in the prior art. The length of the radio frame is designated Tf and is 10ms. The radio frame is composed of 15 time slots S # 0 to S # 14. Each time slot has a duration of 10/15 ms. The following information is sent in each time slot of length 2560 chip: a) the TFCI bits as a transport format combination indicator for the actual data bits, which represent specific control information of the physical layer. b) the pilot bits for channel estimation; and c) the data bits of the forward access channel FACH or paging channel PCH transport channels. The number of bits transmitted on the S-CCPCH per frame or time slot results from the spreading factor of the OVSF spreading code used and the modulation type QPSK (Quarternary Phase Shift Keying) used in the downlink. Spreading codes with a spreading factor SF of 4, 8, 16, 32, 64, 128 or 256 are possible for the S-CCPCH. This means that at least 20 bits with a spreading factor of 256 to a maximum of 1280 bits with a spreading factor of 4 can be transmitted per time slot with a length of 2560 chips. These combinations are listed in Table 2 below.

Table 2: Number of bits per frame or time slot depending on the stimulus factor on the S-CCPCH

3. Preferred embodiments of the invention

As mentioned, it has been found that conventional methods, such as, for example, higher-quality coding, solve the problem of access collisions when multiple terminals simultaneously access a shared resource, e.g. a shared radio channel to a base station, and the resulting retransmissions, which lead to at least reduced data throughput, cannot be solved.

It is therefore proposed to take a fundamentally different approach, in which the frame formats with regard to the transmission frames - on the physical layer (i.e. not in higher layers) are shortened compared to those previously used.

In the event of an access collision, smaller, shorter time frames can thus be transmitted repeatedly, as a result of which fewer data bits have to be transmitted again from the transmitter (terminal). This reduces traffic, which means that the resource, i.e. the radio channel, can be used more efficiently. This means that more terminals can reliably communicate with the base station.

Energy can also be saved at the terminal if shorter frames are sent and if there are fewer retransmissions. In particular, with the frame formats shortened in this way, a transmission frame length of 1 to 5 time slots has proven to be advantageous.

It has been found here that the efficiency of the transmission can be increased by using several codes on such a shortened frame.

Various configurations are described below.

a) Exemplary embodiments for shortening the frame (FIGS. 4 to 8 in conjunction with FIGS. 9, 12 to 13)

4 to 8

Embodiments described, in which the frame has been shortened compared to the frame format used previously. The examples initially relate to a single code transmission, but can also be used for a multicode transmission.

4 to 8 show a subframe structure or subframe structure with a transmission time length or transmission time interval TTI of one, two, three, four or five time slots. The length of the

Time slot T _s iot is always 2560 chips, in which N _D ata user data bits are transmitted in each case.

While the time distribution is shown in FIGS. 4 to 8, the code is shown in FIGS. 12 and 13

Distribution for the subframe or subframe for the PRACH message part or the S-CCPCH shown.

FIG. 9 shows the subframe structure for the PRACH message part in the case of a single code transmission. The message part contains a data part D and a control part C. The data part D is by means of a OVSF spreading codes, which are denoted by C _d , sF, ι, spread. The control part C is also spread by means of a spreading code, which is designated _C , SF, I in the drawing. Both codes are transferred from the terminal to the UTRAN using I / Q code multiplexing.

Single code transmission with T _f = 1 time slot (cf. FIG. 4 in connection with FIG. 12)

- The transmission time length for the PRACH message part and S-CCPCH is T _f = 1 time slot or "ti e slot" S

- The following data are to be transmitted on the PRACH message part per subframe UR: - Number of control information bits of the physical layer = 40 bits

- Number of data bits from the RACH transport channel = 80

- The following data are to be transmitted on the S-CCPCH per subframe UR: - Number of control information bits of the physical layer = 40 bits

- Number of data bits from the FACH transport channel = 40

Figure 12 shows the subframe structure on the PRACH message part. An OVSF spreading code with SF = 64, ie C _c , 6 ₄ , ι, is sufficient to transmit the data on the control part. An OVSF spreading code with a spreading factor of SF = 32, ie Cd, 32.1, is sufficient for the data part.

The first letter in the indexing of the codes indicates whether it is used for data D or control information C, the second number denotes the spreading factor and the third number the number of the spreading code used in the OVSF code tree. Both codes are transmitted from the UE terminal to the UTRAN using I / Q code multiplexing. Figure 13 shows the subframe structure on the S-CCPCH. An OVSF spreading code with SF = 64, ie C _C , 64, ι • is sufficient to transmit the data

b) Design examples for multi-code transmission (Figures 10, 11, 14, 15)

The UMTS standard currently does not support multicode transmission for the control and data parts of the PRACH. A multicode transmission is a transmission in which individual data packets or subsets of the data are assigned different spreading factors. The UMTS standard does not currently allow multicode transmission for the S-CCPCH either.

As already mentioned, a higher throughput can be achieved by multicode transmission to the shortened frame.

Multicode transmission with T _f = 1 time slot

- The transmission time length for the PRACH message part and S-CCPCH is TTI = 1 time slot

- The following data should be transmitted on the PRACH message section for each subframe:

- Number of control information bits of the physical layer = 80 bits

- Number of data bits from the RACH transport channel = 160

- The following data should be transmitted on the S-CCPCH for each subframe:

- Number of control information bits of the physical layer = 40 bits

- Number of data bits from the FACH transport channel = 80

Figure 14 shows the subframe structure on the PRACH message part. Two OVSF spreading codes with SF = 64 are used to transmit the data on the control part required, ie C _c , 64, ι and C _c , 64.2 • Two OVSF spreading codes with SF = 32 are also required for the data part, ie Cd, 32.1 and C _d , 32.2. All four codes are transmitted by I / Q code multiplexing from the UE to the UTRAN. Figure 15 shows the subframe structure on the S-CCPCH. Three OVSF spreading codes with SF = 128 are required to transmit the data, ie

Cc, 128.1, C _C h, 128.2 and Cch, 128.3.

FIG. 10 shows the subframe structure for the PRACH message part in the case of a multicode transmission. In this case it is now possible to use several OVSF spread codes for both the data part and the control part. For the data part, up to N codes of the same spreading factor, which are denoted in the drawing by C _d , sF, ι to C _C , _SF , _N , can be used, where N denotes a natural number. For the control part, up to M codes of the same spreading factor, which are denoted in the drawing by C _C , SF, _I to C _C , _SF , _M , can also be used, where M denotes a natural number. Optionally, the number of codes M may or may not be the number of codes N. All M + N codes for the PRACH message part are transmitted from the terminal to the UTRAN using I / Q code multiplexing. The advantage of a multicode transmission is that, for example, several codes can be assigned to a terminal, which increases the amount of data to be transmitted for the terminal.

FIG. 11 shows the subframe structure for the S-CCPCH in the case of a multicode transmission. In total, up to L codes with the same spreading factor, which is _denoted in the drawing by C _CΓI , S _F , _I to C _C h, sF, L, can be used, L also being a natural number. In the case of a single code transmission, only a single code C _CΓI , _SF , _{I is} used. The advantage of a multicode transmission on the PRACH message part or the S-CCPCH is that the amount of data can be flexibly adjusted depending on the channel status. This means for example, that fewer codes are used in a bad channel condition, which means that fewer data are affected by transmission errors. If the channel is in good condition, however, many codes can be used.

FIGS. 12 to 15 show the subframe structures for the PRACH or the S-CCPCH in the case of a single code transmission. In the case of PRACH, a specific spreading code C _D , 32, 1 is selected for a subframe of length T _f for the data part or “data part” D. The D stands for the data part, 32 represents the spreading factor SF and 1 the number of the spreading code used in the OVSF code tree. Likewise, a specific code C _c , 6 ₄ , ι was selected for the control part, where C stands for control, 64 represents the spreading factor and 1 the number of the spreading code used. Analogously, it can be seen in FIG. 13 for the S-CCPCH subframe of length T _f that the data is spread with a code C _C h, 64, ι, the Ch standing for channelization code, ie spreading code, 64, the spreading factor designated and 1 in turn the number of the spreading or channelization code used.

FIG. 14 shows a special case of FIG. 10, in which spread codes for the data part and the control part (data part or control part) were selected for a multicode transmission on the PRACH message part, the number N being equal the number M is and is 2.

FIG. 15 shows the special case of FIG. 11, in which three different spreading codes were selected for a multicode transmission on the S-CCPCH.

Other advantageous configurations provide that the

Transmission frame length or / and the number of spreading codes used correlated with the quality of the radio channel. This means that the transmission can be adapted to the transmission conditions. The quality of a radio channel is influenced, for example, by the following factors: - a movement of the mobile radio subscribers - a multipath propagation of the data signal - the number of active subscribers in a radio cell - the base stations of neighboring radio cells.

Even if the problem was explained on the basis of a specific example from the UMTS system, the invention can be used in various configurations in wide areas, as can also be seen from the clarification of the terms.

Abbreviations and reference symbols

ACK Acknowledgment

AICH Acquisition Indicator Channel

FACH Forward Access Channel

FDD Frequency Division Duplex kbps kilo bits per second

Mcps mega chips per second

NACK Negative Acknowledgment

OVSF Orthogonal Variable Spreading Factor

PCH paging channel

PRACH Physical Random Access Channel

RÄCH Random Access Channel

RNC Radio Network Controller

S-CCPCH Secondary Common Control Physical Channel

SF spreading factor

TDD Time Division Duplex

TFCI Transport Format Combination Indicator

TTI transmission time interval

UE user equipment

UMTS Universal Mobile Telecommunications System

UTRAN UMTS Terrestrial Radio Access Network

D: Data

C: Control

P: pilot

UR: Subframe

SF: spreading factor

S: time slot

Tsiot. "Duration of a time slot

TRACH: Duration of a RACH frame

T _f : duration of a transmission frame

N _D at _a : Number of (useful) data bits

Claims

claims

1. Method for transmitting data on a common radio channel, which is provided in each case between a base station (BS) and a multiplicity of terminals (UE) in a mobile radio system,

the data are transmitted successively in time and are thereby divided into predefined time slots of the radio channel and one or more time slots are combined to form a transmission frame,

- The length of the transmission frame on the radio channel in the transmission between the terminal and base station in the uplink and in the downlink is n time slots, characterized in that

- n represents a natural number between 1 and 5.

2. The method of claim 1, wherein the transmission frame length is selected depending on the quality of the radio channel.

3. The method according to claim 1 or 2, in which a spreading code is used for spreading the bandwidth and the data is optionally spread on the transmission frame with one or more spreading codes.

4. The method according to any one of the preceding claims, wherein the number of spreading codes to be used for a transmission frame is set as a function of the quality of the radio channel.

5. The method according to any one of the preceding claims, wherein the radio channel for the transmission of packet-oriented

Services is designed.

6. The method according to any one of the preceding claims, in which control data and useful data are transmitted in a transmission frame.

7. The method according to any one of the preceding claims 3 to 6, in which a number M of spreading codes is assigned to the control data in a transmission frame and a number N of spreading codes to the useful data, the M and N representing integers

8. The method according to claim 7, in which either M is N or M is not N.

9. The method according to any one of the preceding claims, wherein the mobile radio system is a UMTS FDD system and a time slot has a duration of 10/15 ms.

10. The method according to any one of the preceding claims, wherein the radio channel in the uplink connection is the PRACH and the downlink connection is the S-CCPCH.

11. Terminal with a processor unit, which is set up in such a way that the method according to one of the

Claims 1 to 10 is feasible.

12. Base station with a processor unit which is set up in such a way that the method according to one of the

Claims 1 to 10 is feasible.

13. Communication system with a base station according to claim 12 and a terminal according to claim 11.