WO2000055990A1

WO2000055990A1 - Transmission method with variable data rate in a random access channel of a radio communication system

Info

Publication number: WO2000055990A1
Application number: PCT/DE2000/000628
Authority: WO
Inventors: Jean-Michel Traynard; Christoph MECKLENBRÄUKER
Original assignee: Siemens Aktiengesellschaft
Priority date: 1999-03-16
Filing date: 2000-03-01
Publication date: 2000-09-21
Also published as: EP1159793A1; DE19911712A1

Abstract

According to the invention, radio blocks having different split coding are split in a channel formed by a random access time slot and can optionally be transmitted in a split manner. These measures help keep the collision probability low. In order to vary the data rate, one or two radio blocks can be transmitted in every time slot during a connection. Flexibility is further enhanced by transmitting simultaneously and in a split manner two radio blocks with different split coding, which have a comprehensible relation to each other on the receiver side. The invention shows that even in random access channels (RACH), limitation of capacity as a result of channel estimation does not entail limitation of transmission capacity.

Description

description

_Ü bertragungsverfahren variable data rate in a RACH channel of a radio communication system

The invention relates to a method and a base station for transmission with variable data rate in a channel with random access of a radio communication system.

In radio communication systems, information (for example voice, image information or other data) is transmitted with the aid of electromagnetic waves via a radio interface between the transmitting and receiving radio station (base station or subscriber station). The electromagnetic waves are emitted at carrier frequencies that lie in the frequency band provided for the respective system. For future mobile radio systems with CDMA or TD / CDMA transmission methods (CDMA Code Division Multiple Access, TD / CDMA Time Division CDMA) via the radio interface parts, for example UMTS (Universal Mobile

Telecommunication system) or other 3rd generation systems, frequencies in the frequency band of approx. 2000 MHz are provided.

In a radio communication system there is a need to transmit data for different applications and thus with a data rate that is as variable as possible. A channel with the corresponding data rate can be reserved beforehand. This reservation requires a certain amount of signaling and thus ties up transmission capacity. For services with short data packets to be transmitted intermittently, this means an unfavorable relationship between useful data and signaling capacity.

The signaling effort is avoided in channels with arbitrary access, since the transmitting radio stations can access them without a prior reservation. Through the However, random access leads to collisions that make it difficult or even impossible to detect the transmitted data.

Solutions from DE 198 17 771 and DE 199 04 108 are known for the variability of the data rate and for collision detection. Collisions are avoided by temporal orthogonality and the data rate can be varied by single or double radio blocks. However, the variability of the data rate is very limited.

The object of the invention is to further increase the flexibility in increasing the data rate, taking into account the probability of a collision. This object is achieved by the method with the features of claim 1 and the base station with the features of claim 12. Advantageous developments of the invention can be found in the subclaims.

According to the invention, radio blocks with spreading codes are transmitted spread in a channel formed by a time slot with random access. Furthermore, several radio blocks per time slot can be transmitted at different times, if necessary. The probability of a collision is kept low by these measures. The flexibility is further increased by the fact that within the connection to increase the data rate, two radio blocks with different spreading codes are transmitted simultaneously, which are in a comprehensible relationship to one another. Due to this ratio, which does not result from a previous assignment, a larger number of spreading codes can also be used in a channel with random access.

The receivers of radio stations are often limited in their ability to estimate channels, so that only a subset of the available spreading codes corresponding to the previously estimated channels can be used. If previously an assignment from spreading codes to connections, this disadvantage is insignificant since the other spreading codes can be assigned to the higher-rate connections.

In a channel with random access, this also meant, according to previous understanding, a limitation of the transmission capacity, since no coordination between the transmitting radio stations was given by a reservation. The invention shows that even in channels with arbitrary access, the capacity limitation by the channel estimation does not have to lead to a limitation of the transmission capacity.

According to an advantageous embodiment of the invention, the ratio of the spreading codes is specified such that the spreading codes are divided into at least two groups, a first group of spreading codes being provided for the use of different subscriber stations. A subscriber station therefore does not use two spreading codes from the first group. This does not increase the probability of a collision. However, a subscriber station can use at least one of the spreading codes from the first and one of the spreading codes from the second group at the same time. The spreading codes of the second group serve to increase the data rate.

There are different options for assigning the spreading codes of the second group to those of the first group. The assignment can be fixed and, for example, preset or updated using information from the organizational channel. This ensures high reliability. An alternative variant provides that the simultaneous use of spreading codes from both groups is recognized on the basis of the same propagation paths. No assignment has to be signaled for this, but the propagation paths should differ sufficiently. Furthermore, it is possible for m to be the same as the spread codes of the first group. spread radio blocks, the assignment of the spreading codes is signaled. A few bits can be used to signal which other spreading codes belong to the connection. This means that only a little transmission capacity is lost, and yet full flexibility is given.

The data rate can thus be made more flexible in channels in which the spread codes are selected without prior allocation of resources. The invention can be used particularly advantageously in the case of data transmission over a broadband radio interface between base stations and subscriber stations. The capacity of the radio interface is large, a limitation of the actually used capacity would mean extensive unused resources.

If a common detection is used for the detection of the radio blocks, the mutual influences of the signals sent in an uncoordinated manner are taken into account in the detection and the detection quality increases. However, the complexity of the detection also increases roughly with the number of connections. However, since the number of simultaneous connections according to the invention does not increase, but only a plurality of spreading codes are used to increase the data rate, the additional effort remains low.

The radio interface is advantageously organized according to a TDD partial separation method (Time Division Duplex), so that asymmetrical data services are also supported without wasting resources.

The invention is explained in more detail below with reference to exemplary embodiments with reference to drawings.

Show 1 is a block diagram of a mobile radio system,

2 shows a schematic representation of the frame structure of the TDD transmission method,

3 shows a schematic illustration of the use of spreading codes according to the prior art,

Fig. 4- ^• 6 is a schematic representation of the inventive use of spreading codes to increase the data rate, and Fig. 7 is a simplified block diagram of a base station.

The mobile radio system shown in FIG. 1 as an example of a radio communication system consists of a multiplicity of mobile switching centers MSC which are networked with one another or which provide access to a fixed network PSTN. Furthermore, these mobile switching centers MSC are each connected to at least one device RNM for allocating radio resources. Each of these devices RNM in turn enables a connection to at least one base station BS. Such a base station BS can connect via a radio interface to subscriber stations, e.g. Build mobile stations MS or other mobile and stationary devices. At least one radio cell Z is formed by each base station BS. In the case of sectorization or hierarchical cell structures, several radio cells Z are also supplied per base station BS.

1 shows, by way of example, connections VI, V2, V3 for the transmission of useful information and signaling information between mobile stations MS and a base station BS, the sending of organizational information in an organizational channel BCCH in the sense of a point-to-multipoint connection from the base station to the Mobile stations MS and an access channel RÄCH (Random Access Channel) shown. The access channel RÄCH, shown in the exemplary embodiment only in the upward direction, is a channel which the mobile stations MS can access arbitrarily without reservation. An operations and maintenance center OMC implements control and maintenance functions for the mobile radio system or for parts thereof. The functionality of this structure can be transferred to other radio communication systems in which the invention can be used, in particular for subscriber access networks with a wireless subscriber line.

The frame structure of the radio transmission is shown in FIG. 2. According to a TDMA component, a division of a broadband frequency range, for example the bandwidth B = 5 MHz, into a plurality of time slots ts of the same duration, for example 16 time slots ts0 to tsl5, is provided. A frequency band extends over a frequency range B. Some of the time slots ts0 to ts8 are used in the downward direction DL and some of the time slots ts9 to tsl5 are used in the upward direction UL. In between is a switch point SP. In this TDD transmission method, the frequency band for the upward direction UL corresponds to the frequency band for the downward direction DL. The same is repeated for other carrier frequencies.

Information of several connections is transmitted in radio blocks within the time slots that can be used for the transmission of user data with previous allocation of resources. These radio blocks for. User data transmission consist of sections with data d, in which training sequences tseql to tseqn known at the receiving end are embedded for channel estimation. The data d are spread individually for each connection with a fine structure, a spreading code c, so that, for example, n connections can be separated at the receiving end by this CDMA component. A channel is formed by a frequency band B, a time slot ts and a spread code c.

The spreading of individual symbols of the data d has the effect that within the symbol duration T _S ym Q chips of the duration T _ch i _p will wear. The Q chips form the connection-specific spreading code c. The spreading code c can also result from a superimposition of several codes. Furthermore, a protection time gp is provided within the time slot ts to compensate for different signal propagation times of the connections.

Within a broadband frequency range B, the successive time slots ts are structured according to a frame structure. So 16 time slots ts are combined into a frame for.

The parameters of the radio interface used are advantageously: Chip rate: 4096 Mcps

Frame duration: 10 ms

Number of time slots: 16

Duration of a time slot: 625 μs

Spread factor: 16 Modulation type: QPSK

Bandwidth: 5 MHz

Repeat frequency value: 1

These parameters enable the best possible harmonization with an FDD mode (frequency division duplex) for the 3rd generation of mobile communications.

In the RÄCH channel with random access, two radio blocks FBI, FB2, each filling only less than half of the time slot ts, are available for a transmitting mobile station MS. The mobile station MS can also use both radio blocks FBI, FB2 and thus double the data rate. 16 spreading codes c are still available per time slot and are divided into two groups. A first group with the spreading codes cO to c7 corresponds to the eight channel estimates, which can be carried out simultaneously on the receiving side. A transmitting mobile station MS arbitrarily selects one the spreading codes cO to c7 of the first group. This situation according to the prior art is shown in FIG. 3.

In order to further increase the data rate of the transmission in this time slot, the mobile station MS can additionally select one or more further spreading codes c8 to cl5 which belong to a second group which does not overlap with the first group. A mobile station MS therefore sends two or more radio blocks FBI at the same time, but these are spread with different spreading codes c. The affiliation of the spreading codes cO to cl5 to the groups is predetermined or will be announced in the organizational channel BCCH. The size of the group can also be smaller than eight. In the exemplary embodiment, eight is the maximum number of channel estimates that can be carried out simultaneously.

According to FIG. 4, there is the possibility that each spread code cO to c7 of the first group is assigned a spread code c8 to cl5 of the second group. This means that the data rate can be quadrupled to a maximum. Other groupings, such as cO to c3 m of the first group, each with three assigned feed codes, e.g. c4 to c5 for cO are also possible.

5 shows a case in which two spreading codes c8 and c9 of the second group are assigned to a spreading code cO of the first group. The solutions according to FIGS. 4 and 5 do not increase the likelihood of a collision as long as all mobile stations MS observe the assignment. A mobile station MS, which uses the spreading code cl, was unable to access the feed codes c8 or c9 assigned to the spreading code cO. However, the data rate can also be increased beyond this limit if a mobile station MS uses several spreading codes cO and cl, see FIG. 6, from the first group. In this case, however, the probability of a collision also increases. Remedial measures can, however, be provided by evaluation and collision detection according to DE 199 04 108. The fixed assignment limits the flexibility somewhat, but can allow the connections in the channel with random access RÄCH without a previous allocation of resources a corresponding variety of data rates. The assignment rule can be optimized separately for the individual radio cells by signaling in the organization channel BCCH.

Instead of or in addition to the fixed assignment, two further methods are proposed which allow the assignment of spreading codes c to connections without a reservation. The radio blocks FBI, FB2 can thus contain pointers to further spreading codes c, which enable the receiver to assign the data to the individual connections after evaluating the pointers. With just a few additional bits, the existing resources of the second group of

Spreading codes c can be freely selected by the transmitting side. If MS rules are observed by the mobile stations, the probability of a collision increases only slightly. An assignment of spreading codes c to connections can be reconstructed by the receiving side without any signaling on the basis of the propagation paths.

If, for example, a channel estimation for the spreading codes c of the first group is carried out in a first reception-side evaluation step, an assignment can be made for all 16 spreading codes based on the probability of individual metric paths of the Viterbi decoding in the detection according to the joint detection principle according to DE 41 21 356 to the channel estimation results and thus to the propagation paths and connections.

The reliability of the assignment can be checked on the basis of transmitted test bits, which each apply to several radio blocks FBI, FB2 and spreading codes c of the connection. This can also be used to check whether a correct assignment was made at the receiving end. Due to the variability of the data rate, a large number of different services (telemetry services, short message services, very time-variant but easily scalable data rate) can be supported in the RÄCH channel with arbitrary access, and resource requests can also be sent with a low probability of collision. This makes this channel much more attractive.

The access blocks are evaluated in a base station BS according to FIG. 7. This consists of a broadcast /

Receiving device TX / RX, which converts received signals from the frequency range of the data transmission into the baseband, converts them analog / digital, and amplifies the received signals. Digital signal processing takes place in a signal processing device DSP. A channel estimation is carried out and the transmitted data symbols are detected.

A signal evaluation device SA extracts the data components of the radio blocks FBI, FB2 on the basis of the temporal orthogonality and the spreading codes c. The signal evaluation device SA takes the requirements for resource allocation and the data to be forwarded from the content of the data components.

The resource allocation itself is carried out in the facility RNM for allocating radio resources and signaled back to the base station BS. A control device SE then assigns a channel for data transmission to the mobile stations MS by compiling a corresponding signaling block and transmitting this block by the transmitting / receiving device TX / RX.

The interaction of the components is also controlled by the control device SE. The data and the assignment rules for the spreading codes c are stored in a memory device MEM.

Claims

claims

1. Method for data transmission in a radio communication system in which radio blocks (FBI, FB2) can be transmitted in a channel (RÄCH) formed by a time slot (ts) with random access, with overlapping radio blocks (FBI, FB2) using a spreading code (c) are separable, characterized in that two radio blocks (FBI, FB2) with different spreading codes (c) are transmitted simultaneously within a connection to increase the data rate, the spreading codes (c) selected on the transmission side being in a traceable relationship on the receiving side.

2. The method according to claim 1, characterized in that the data transmission takes place via a broadband radio interface between base stations (BS) and subscriber stations (MS).

3. The method according to any one of the preceding claims, characterized in that radio blocks (FBI, FB2) can be transmitted separately in time and within the connection one or two radio blocks (FBI, FB2) are sent per time slot in order to achieve a variable data rate.

4. The method according to any one of the preceding claims, characterized in that the selection of the spreading codes (c) is carried out without prior allocation of resources.

5. The method according to any one of the preceding claims, characterized in that a common detection is used for the detection of the radio blocks (FBI, FB2).

6. The method according to any one of the preceding claims, characterized in that a division of the spreading codes (c) is announced in at least two groups, one the first group of spreading codes (c) is provided for the use of different subscriber stations (MS), at least one spreading code (c) from the first and second group is used simultaneously by one subscriber station (MS).

7. The method according to claim 6, characterized in that a fixed assignment between the spreading codes (c) of the first and second groups is predetermined.

8. The method according to claim 6, characterized in that the simultaneous use of spreading codes (c) is recognized from both groups on the basis of the same propagation paths.

9. The method according to claim 6, characterized in that in the spreading codes (c) of the first group spread radio blocks (FBI, FB2) the assignment of the spreading codes (c) is signaled.

10. The method according to any one of the preceding claims, characterized in that the channel relates to the upward direction (UL) of the transmission.

11. The method according to any one of the preceding claims, characterized in that the data transmission by means of a

TDD participant separation procedure is carried out.

12. Base station (BS) for a radio communication system which enables data transmission via a channel (RÄCH) with random access from and to subscriber stations (MS) by means of radio connections, with a transmitting / receiving device (TX / RX), which has a partial subscriber separation according to time slots (ts), with a signal processing device (DSP) which evaluates several radio blocks (FBI, FB2) transmitted in one time slot (ts), - The radio blocks (FBI, FB2) of the time slot (ts) are spread with different spreading codes (c), with a signal evaluation device (SA) that separates radio blocks (FBI, FB2) based on the spreading codes (c) and for a subscriber station (MS ) simultaneously evaluates two radio blocks (FBI, FB2) with different spreading codes (c) that are understandable in order to increase the data rate.