DE10025286B4 - Signaling method in a radio communication system and base station in a radio communication system - Google Patents

Abstract

method for signaling in a radio communication system, wherein the radio communication system is a CDMA subscriber separation method support characterized in that from a base station (NB) of the radio communication system a current number (n) of those in a radio cell (Z) of the base station (NB) allocated spreading codes (c) coded by a selection and / or Number of channel measurement sequences (tseq) to a subscriber station (UE) is signaled.

Description

The The invention relates to a method for signaling subscriber-specific Information, e.g. an allocation of spreading codes in a radio communication system, in particular in a radio communication system with a CDMA subscriber separation method and a base station in a radio communication system. The invention is especially for use in a mobile radio or wireless subscriber line system suitable.

In Radio communication systems, for example the European mobile radio system the second generation GSM (Global System for Mobile Communications), information (e.g. language, image information or other data) with the help of electromagnetic waves over a Transmit radio interface. The radio interface refers to a connection between a base station and subscriber stations, the subscriber stations Mobile stations or fixed radio stations can be. The The electromagnetic waves are emitted at carrier frequencies, the one for the respective system provided frequency band. For future radio communication systems, for example the UMTS (Universal Mobile Telecommunication System) or other 3rd generation systems are frequencies in the frequency band of approximately 2000 MHz. For the third mobile radio generation, two modes are provided, whereby one mode an FDD operation (frequency division duplex) and the another mode is called TDD (time division duplex) operation. These modes can be found in different frequency bands Application. Support both modes a so-called CDMA subscriber separation procedure (Code Division Multiple access).

The radiated electromagnetic waves are due to losses dampened by reflection, diffraction and the like. As a result, the sinks Receive power, which at the receiving subscriber station disposal stands. This damping is location dependent and also time-dependent for moving subscriber stations. at a multipath propagation, several signal components come differently delayed at the receiving radio station. Describe the influences described the connection-specific transmission channel.

Out WO 99/08401 A1 is known as a channel estimation based on the evaluation of transmitted and in the receiver previously known channel measurement sequences determines the properties of the connection-specific transmission channel. This is done by comparing the previously known stored ones channel measurement sequence and the received, through the transmission channel distorted channel measurement sequence. The result of the channel estimate is a channel impulse response.

Out the article by J. Mayer, J. Schlee, T. Weber "Protocol and Signaling Aspects of Joint Detection CDMA ", PIMRC'97, Helsinki, 1997, pages 867-871, is known, inter alia, that in one Radio station on the receiving side for the detection of signals of a communication link not just a spread code assigned to your own communication link, but additionally spread codes assigned to parallel communication connections are used become. Here, the receiving radio station is advantageously known the spread codes currently assigned to prevent deterioration of the reception quality based on detection of currently non-existent signals or unallocated spreading codes to avoid.

The Basis for discussion 3GPP TSG-RAN Working Group 1, Meeting # 12, Seoul, Korea, April 08- April 13, 2000 describes a method for signaling a number active spreading codes by assigning several values to the number active spreading codes for a combination of channel measurement sequences.

The WO 98/57441 A2 shows that two radio blocks are in one channel different training sequences simultaneously be the radio blocks can be distinguished on the reception side by means of the training sequences can.

The The invention has for its object to provide a method that simple signaling of subscriber-specific information allows.

This object is achieved by the method having the features of claim 1 and by the base station of claim 15 for carrying out the method. Advantageous developments of the invention can be found in the subclaims.

According to the invention in a radio communication system using a CDMA subscriber separation method support from a base station a current number of in a radio cell spreading codes allocated to the base station coded by a selection and / or number of channel measurement sequences signaled to a subscriber station.

By the method according to the invention, which combinations of channel measurement sequences for signaling used, can information from a transmitting station, for example a base station at transmitting stations, e.g. Subscriber stations, are transmitted without therefor additional Data bits on specific signaling channels would be required.

The Design according to the invention allows signaling to the subscriber station in a simple manner, how many spreading codes are currently allocated. Because the signaling by means of a selection and / or number of available channel measuring sequences are no additional Signaling on specific signaling channels or Adjustments or changes on the channel measurement sequences required. By means of the possible channel measurement sequences known to her per se the subscriber station can transmit those currently sent by the base station channel measuring sequences and by their respective invention Number or combination of coding implies the current number Determine the spread codes assigned in order to subsequently find an optimal one To perform detection.

To An advantageous further development of the invention has the participant-specific Information such as the number of in a radio cell of the base station allocated spread codes, different values and there are each a selection and / or number of channel measurement sequences one or more Values of the participant-specific information are assigned and are signaled to the subscriber station.

On this can be done even with an insufficient number of channel measurement sequences signaling takes place, e.g. the possible number of active spreading codes significantly restricted. The assignment can also be made in such a way that the difference the values of the assigned subscriber-specific information is maximum and / or constant, so that detection errors are less are likely.

To an advantageous development of the invention, the amount of channel measuring sequences by cyclically deriving one or more basic sequences educated. This makes, among other things, a simultaneous common channel estimation possible for several transmission channels if their channel measurement sequences derived from the same basic sequence.

The inventive method is according to one Another development of the invention is particularly advantageous in radio communication systems carried out using a joint detection method described.

one According to a further development of the invention, the number of channel measurement sequences minimized to signal the number of allocated spreading codes. The number of channel measurement sequences used is advantageous selected according to the maximum number of spread codes that can be allocated. So can be, for example, by combinations of four channel measurement sequences fifteen define different amounts of spread codes allocated.

Especially The method according to the invention described is advantageous in a as a Mobile radio system or wireless subscriber line system realized radio communication system used.

embodiments the invention will be explained in more detail with reference to the accompanying drawings.

there demonstrate

1 2 shows a block diagram of a radio communication system,

2 a schematic representation of the frame structure of a radio interface with a TD / CDMA subscriber separation method, and

3 a table with a number of allocated spreading codes coded by selection and combinations of training sequences.

The 1 shows a part of a mobile radio system as an example of the structure of a radio communication system. A mobile radio system consists in each case of a multiplicity of mobile switching centers MSC which belong to a switching network (SSS - Switching Subsystem) and which are networked with one another or which provide access to a fixed network, and one or more base station systems BSS (BSS) connected to these mobile switching centers MSC - Base station subsystem). A base station system BSS in turn has at least one device RNC (RNC - Radio Network Controller) for assigning radio resources and at least one base station NB (NB - Node B) connected to it.

A Base station NB can over a radio interface connections to subscriber stations UE (UE - User Equipment) build up. Each base station NB has at least one radio cell Z formed. The size of the radio cell Z is usually determined by the range of an organizational channel (BCCH - broadcast Control Channel) by the base stations NB with one each maximum and constant transmission power is determined. With sectorization or with hierarchical cell structures can Several radio cells Z are also supplied per base station NB. The functionality this structure is transferable to other radio communication systems, in which the invention can be used.

The example of 1 shows two subscriber stations UE, which are located in the radio cell Z of the base station NB. The mobile stations UE each have a communication link to the base station NB, on which a signal transmission of a selected service takes place in the upward UL and downward direction DL. The communication links are separated by the different spreading codes c1, c2, c3 assigned to the subscriber stations UE, the subscriber stations UE each using all currently assigned spreading codes c1, c2, c3 for receiving the signals of the own communication link in accordance with the joint detection method described. During the connection, the subscriber stations UE and the base station NB continue to periodically evaluate the transmission properties of the radio interface using channel estimation DE 197 34 936 out.

The frame structure of the radio transmission in the TDD mode of the UMTS mobile radio system, in which the method according to the invention can advantageously be used, is from the 2 seen. According to a TDMA component, a division of a broadband frequency range into several time slots ts of the same time duration, for example 15 time slots ts0 to ts14, is provided, which form a time frame fr. A time slot ts is allocated for a channel RACH with random multiple access.

On Frequency band B extends over a certain frequency range. Part of the time slots will for the signal transmission in the downward direction DL and part of the time slots used in the upward direction UL. exemplary is an asymmetry ratio 3: 1 in favor of the downward direction DL shown. With this TDD transmission method corresponds to frequency band B for the upward direction UL the frequency band B for the downward direction DL. The same is repeated for further carrier frequencies. Through the variable assignment of the time slots ts for opening or downward direction UL, DL can diverse asymmetrical resource allocations are made.

Information of several connections is transmitted in radio blocks within the time slots ts. 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 (code division multiple access). The spreading of individual symbols of the data d causes T _sym Q chips of the duration T _chip to be transmitted within the symbol duration. The Q chips form the connection-specific spreading code c. A channel measurement sequence tseq is also arranged in the radio blocks and serves, as described, for channel estimation.

The parameters of the radio interface used for both transmission modes are advantageously: Chip rate: 3.84 mcps Frame duration: 10 ms Number of time slots: 15 Duration of a time slot: 666 µs spreading: variable modulation: QPSK bandwidth: 5 MHz Frequency reuse value: 1

This Enable parameters the best possible Harmonization for TDD and FDD mode (FDD frequency division duplex) for the 3rd Generation mobile communications.

In the 3 A table is shown which exemplifies the signaling according to the invention of the current number n of allocated spreading codes c by means of a selection and / or number of channel measurement sequences tseq. When using four channel measurement sequences tseq1 ... tseq4, 15 different amounts of allocated spreading codes c can be represented. In the example given, 15 spreading codes c1 ... c15 are available, the spreading codes c being assigned successively to communication links. In the manner of a binary coding, different channel measuring sequences tseq and combinations of several channel measuring sequences tseq are used to represent a certain number n of currently assigned spreading codes c. After that in the 1 The example shown is based on the table 3 the first tseq1 and the second channel measurement sequence tseq2 are sent by the base station NB, since this combination represents the current allocation of the spreading codes c1, c2 and c3 in the radio cell Z of the base station NB. The subscriber stations UE permanently evaluate the currently transmitted channel measurement sequences tseq, since they are per se aware of the number and content of the channel measurement sequences tseq. In this way, you can easily detect which channel measurement sequences tseq are currently being transmitted by the base station NB and, as described, use this to draw conclusions about the current number of allocated spreading codes c. The parameters of the number of possible channel measurement sequences and their content can differ from radio cell to radio cell of the radio communication system and are generally signaled to the subscriber stations.

Next the signaling of the current number n already described allocated spreading codes c can any other subscriber-specific information a combination of different channel measurement sequences tseq of the subscriber station UE are signaled. It leaves the different subscriber stations UE, for example assign an individual subscriber identification TI, which consists of a combination of different channel measurement sequences tseq is formed. For efficient packet-oriented data transmission in mobile radio networks can for example so-called "shared channels "is used become. Different subscriber stations UE depending on these channels Allocated needs. This constantly changing Allocation must be as possible done quickly (best in the physical layer), so that there is an efficient utilization of resources.

different User stations UE get different when configuring the "shared channel" Combinations of channel measurement sequences tseq assigned as individual subscriber identification TI (via signaling methods in higher Layers). In the operation of the "shared channels "will then each the combination of channel measurement sequences tseq, i.e. the individual Subscriber identification TI sent out to the subscriber station UE is assigned for which data is currently being sent.

The Combination of channel measurement sequences The subscriber station UE can use tseq, for example, via a simple binary coding be assigned. To increase of reliability can however also be any redundant code of a channel coding method (e.g. BCH code) can be used. This allows for a given maximum number of channel measurement sequences tseq increase the number of identifiable subscriber stations UE. in the UTRA-TDD system, for example, 8 channel measurement sequences tseq are provided. By combining the channel measurement sequences tseq and a simple binary Code can 127 subscriber stations UE can be identified.

The Coding of participant-specific information using combinations of channel measurement sequences tseq can also be used to measure the power of a transmitter, in the uplink e.g. the subscriber station UE, by means of a receiver, for example the base station NB to regulate (power control loop). Such is also in the downlink Signaling possible.

For this purpose, the receiver, for example the base station NB, controls the transmission power through the transmission Signaling bit (TPC, transmit power control) in the physical layer. The transmitter, for example the subscriber station UE, changes its transmission power depending on the TPC bit (0 or 1) by a predetermined increment? P up or down. The combination of the channel measurement sequences tseq can be assigned to different increments ΔP of the transmission power change. The optimal step size ΔP depends on variable sizes such as the channel properties, the speed of the receiver or the transmission rate of the TPC bit. A rapid change in the step size ΔP is therefore desirable.

The assignment can be configured as follows (when using two channel measurement sequences tseq1, tseq2):

It it is also conceivable that the number of values to be signaled, e.g. the number of CDMA codes used is higher than the number of potential Combinations of channel measurement sequences tseq because e.g. not enough channel measurement sequences tseq available stand. In this case, you can a combination of channel measurement sequences tseq several possible Numbers of CDMA codes can be assigned. The subscriber station UE must then determine the number of actually active CDMA codes in a further step. This is done, for example, by correlation with all of them Code sequences and subsequent Threshold decision.

however it can be due to additive noise and cross correlations False detections come, i.e. an incorrect number becomes active CDMA codes determined. To the number of wrong decisions as possible To keep low, the allocation scheme of the Combinations of the channel measurement sequences tseq with the number of used CDMA codes chosen so that the difference in the respective numbers of CDMA codes by a combination of channel measurement sequences tseq, a so-called code word, are shown, is maximum. It is also advantageous if the difference between the respective numbers of CDMA codes for all code words if possible is equal to.

Such an assignment scheme can look like this, for example:
Number of channel measurement sequences tseq: 3
Number of code words: 7
Number of CDMA codes: 16

In this selected case, the difference in the number of CDMA codes for all code words is constant 7. Depending on the number of channel measurement sequences tseq used and the number of CD used However, MA codes other than the above can be selected. In particular, any redundant codes can also be used instead of the binary code selected here.

A Assignment as shown in the table above is not according to the invention limited to the display of active CDMA codes, but can be used for any participant-specific information, such as Information about Performance regulation or for the identification of participants.

Claims (15)

Method for signaling in a radio communication system, wherein the radio communication system supports a CDMA subscriber separation method, characterized in that a current number (n) of those in a radio cell (Z) of a base station (NB) of the radio communication system Base station (NB) allocated spread codes (c) coded by a selection and / or number of channel measurement sequences (tseq) to a subscriber station (UE) is signaled. A method according to claim 1, characterized in that from the base station (NB) of the radio communication system Participant identification coded by a selection and / or number of channel measurement sequences (tseq) is signaled to a subscriber station. Method according to a preceding claim, characterized characterized by the base station (NB) of the radio communication system one step size (ΔP) a change in transmission power the subscriber station (UE) coded by the selection and / or number of channel measurement sequences (tseq) to the subscriber station (UE) is signaled. Method according to a preceding claim, characterized characterized that the participant-specific information different Can have values and that in each case a selection and / or number of channel measurement sequences (tseq) one or more values of the subscriber-specific information assigned and signaled to the subscriber station (UE). A method according to claim 4, characterized that a difference in the values of the assigned subscriber-specific Information is maximum. A method according to claim 4 or 5, characterized that the difference in the values of the assigned subscriber-specific Information is constant. Method according to one of claims 4 to 6, characterized in that that one or more values of the number of in a radio cell (Z) the spreading codes (c) of the selection and / or number allocated to the base station (NB) of channel measurement sequences (tseq) assigned and signaled to the subscriber station (UE) become. Method according to a preceding claim, characterized characterized that for coding by selection and / or number of channel measurement sequences (tseq) channel coding methods are used. A method according to claim 8, characterized in that block codes are used. Method according to a preceding claim, characterized marked, the channel measurement sequences (tseq) by cyclically deriving one or more basic sequences be formed. Method according to a preceding claim, characterized characterized in that the subscriber station (UE) receives a joint detection method at the receiving end carried out becomes. Method according to a preceding claim, characterized characterized that the Number of channel measurement sequences (tseq) for signaling the number (n) of spread codes allocated (c) is minimized. Method according to a preceding claim, characterized characterized that the Coding of the number (n) of allocated spreading codes (c) by means of a or more channel measurement sequences (tseq) corresponding to a binary Coding done becomes. Method according to a preceding claim, characterized characterized that the Radio interface of the radio communication system according to one TDD procedure is organized. Base station (NB) of a radio communication system to carry out of the method of claim 1, wherein the radio communication system as a mobile radio system or is implemented as a wireless subscriber line system.