DE19938747A1 - Method for channel estimation in a radio communication system - Google Patents

Abstract

In the method for channel estimation according to the invention, the amount of channel measurement sequences is expanded by using the time-inverse channel measurement sequences. The time inversions of the channel measurement sequences have the same properties as the original channel measurement sequences and can be derived from them in a simple manner. Another advantage is that the amount of available channel measurement sequences is doubled without additional signaling or storage of additional channel measurement sequences being necessary. The advantages can be achieved by simply redefining the use of the channel measurement sequences.

Description

The invention relates to a method for channel estimation in a radio communication system, in particular a radio Communication system with TD / CDMA subscriber separation.

In radio communication systems, for example the European one Second generation mobile radio system GSM (Global System for Mobile Communications), information such as wise language, image information or other data with the help of electromagnetic waves via a radio interface transfer. The radio interface relates to a ver binding between a base station and a variety of Subscriber stations, for example mobile stations or sta tional end devices. The radiation of the electromagnetic Waves occur with carrier frequencies that are in a for the respective system provided frequency band. For future radio communication systems, for example that UMTS (Universal Mobile Telecommunication System) or others 3rd generation systems are frequencies in the frequency band of approx. 2000 MHz is provided.

The emitted electromagnetic waves are due to losses due to reflection, diffraction and the like dampens. As a result, the reception power decreases, which at receiving radio station is available. This damping is location-dependent and also with moving radio stations time-dependent. In the case of a multipath, there are several Signal components delayed differently when received radio station. Describe the influences described ben the connection-specific transmission channel. From DE 197 34 936 is known as a channel estimate based on the evaluation transmitted and known in the receiver Channel measurement sequences the properties of the connection individual  duel transmission channel determined. This happens through a comparison of the previously known stored 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.

As part of the standardization of the TDD mode (time division duplex) for the third generation of mobile communications, see 3GPP, TS 25.221 , V1.2.1, from July 1999, pp. 13-15 and Annex A, a set of basic sequences has been assumed up to now , whereby from each basic sequence several channel measurement sequences can be derived by shifting. This set of basic sequences is limited to 128 and is a limitation for network planning since the same basic sequence cannot be used in neighboring cells. Suboptimal network planning in turn leads to additional effort when implementing a radio communication system and reduces the profitability of the system.

The invention has for its object a method for Channel estimation indicate that greater flexibility and enables improved network planning. This task will solved by the method according to claim 1. Beneficial Developments of the invention are the subclaims remove.

In the method for channel estimation according to the invention, the Set of channel measurement sequences using the inverse time Channel measurement sequences expanded. The time inverse of the channel measurement Sequences have the same properties as the original channel measurement sequences and can be easily derive from these. Another advantage is that doubling the amount of available channel measurement sequences is sufficient without additional signaling or Storage of channel measurement sequences is necessary. By a one are redefining the use of the channel measurement sequences the benefits attainable.  

According to an advantageous development of the invention the amount of channel measurement sequences by cyclic derivation of one or more basic sequences. So it drops again the signaling and storage effort and additional is a simultaneous joint channel estimation for multiple transmission channels possible if their channel measurement sequences were derived from the same basic sequence.

Is the derivation rule designed in such a way that it depends of transmission conditions of the radio interface by the Cyclic derivation 4, 8 or 16 channel measurement sequences are derived from a basic sequence, it follows increased flexibility in the design of the radio interface Job. With complicated transmission conditions, e.g. B. long Delay times and multipath propagation, only we few, but longer channel measurement sequences derived, with good ones Transmission conditions, however, a larger number of Channel measurement sequences. The number of channel measurement sequences is determined thus also the data rate or number of connections to which the channel measurement sequences are assigned.

After another signaling and storage space spa renden training of the invention on the receiving end only non-inverse channel measurement sequences or their basic sequence saves. Two processes are then used for channel estimation the channel measurement sequence and with that formed in the receiver Inverse of the channel measurement sequence performed. These processes can be carried out in parallel or sequentially.

A large number of different channel measurement sequences are shown in a channel with random access needed. The more channel measurement sequences are available to the lower the probability that two radio stations tions that select the channel measurement sequences uncoordinated, make the same choice and then by simultaneously  Send out the two channel measurement sequences a collision Evaluation of the channel measurement sequences at the receiving end prevented.

Embodiments of the invention are based on the enclosed ing drawings explained in more detail.

Show

Fig. 1 is a block diagram of a radio communication system,

Fig. 2 is a schematic representation of the frame structure of the radio interface, and

Fig. 3 use a channel with optional multiple access.

Fig. 1 shows part of a mobile radio system as an example for the structure of a radio communication system. A mobile radio system consists of a large number of mobile switching centers MSC, which belong to a switching network (SSS - Switching Subsystem) and are networked with one another or provide access to a fixed network, and one or more base station systems BSS (connected to these mobile switching centers MSC) BSS - 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 connect via a radio interface Build up mobile stations UE (UE - User Equipment). At least one radio cell Z educated. The size of the radio cell is usually determined by the Reach of an organizational channel (BCCH - Broadcast Con trol Channel), each of the base stations NB because maximum and constant transmission power is sent, certainly. With sectorization or hierarchical  Cell structures can also have several radio signals per base station NB cells are supplied. The functionality of this structure is transferable to other radio communication systems, in which the invention can be used.

The example of FIG. 1 shows a mobile station UE, which moves at a speed V in the radio cell Z of the base station NB. The mobile station UE has set up a connection to the base station NB, on which a signal transmission of a selected service takes place in the upward UL and downward direction DL. During the connection, the mobile stations UE and base stations NB periodically evaluate the transmission properties of the radio interface by channel estimation according to DE 197 34 936.

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 be used before, can be seen from FIG. 2. According to a TDMA component, a division of a broadband frequency range into several time slots ts of the same time duration is provided, for example 15 time slots ts0 to ts14, which form a time frame for fr. A time slot ts is allocated for a channel RACH with random multiple access.

A frequency band B extends over a certain Fre quenz range. Part of the time slots is used for the signal Downlink DL transmission and part of the time slots used in the upward direction UL. An example is a Asymmetry ratio of 3: 1 in favor of the downward direction DL shown. This corresponds to this TDD transmission method Frequency band B for the upward direction UL the frequency band B for the downward direction DL. The same is repeated for white lower carrier frequencies. Through the variable allocation of time slots ts for up or down direction UL, DL can do a lot complex asymmetrical resource allocations the.  

Information of several connections is transmitted in radio blocks within the time slots ts. The data d are spread individually with a fine structure, a spreading code c, so that, for example, n connections on the receiving side can be separated by this CDMA component (code division multiple access). The spreading of individual symbols of the data d causes the duration T _chip to be transmitted within the symbol duration T _sym Q chips. The Q chips form the connection-specific spreading code c.

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 factor: variable
Modulation type: QPSK
Bandwidth: 5 MHz
Repeat frequency value: 1

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

The invention will be explained in more detail using the channel measurement sequences in the RACH channel with optional multiple access. However, as can be seen from FIG. 2, both channel measurement sequences m, which are derived from a non-inverted basic sequence m0, and channel measurement sequences ml, which are derived from an inverted basic sequence mi0, can also be used as central messages in channels for useful data transmission or signaling. The channel measurement sequences serve as middle messages for the connection-accompanying tuning of the receiver for data detection.

The channel measurement sequences m, mi consist of chips that the same duration as the chips of the spread data have to to facilitate the evaluation at the receiving end. The Inver tation consists in a reversal of the order in time the chips. The first chip becomes the last, the second becomes the penultimate u. s. w.

The basic sequences m0, mi0 can be expanded periodically, see above that by simply moving and appending by 1/16, 1/8 or 1/4 of the basic sequence m0, mi0, each 16, 8 or 4 different channel measurement sequences can be derived.

Fig. 3 shows a channel RACH in uplink UL, which is divided in time points by way of example eight subchannels through different transmit. In addition, there are 16 channel measurement sequences m1 in each subchannel. .m8 and mi1. .mi8 usable, so that there are 8 × 16 collision groups within the channel. If the division into subchannels is omitted, there are still 16 collision groups. A mobile station UE can arbitrarily, ie without prior assignment, choose when sending a radio block in the RACH channel under 128 options, so that a collision with a transmission from another mobile station UE, which faced the same choice, is unlikely. Fig. 3 shows by hatched areas, the channel-measuring sequences currently used in the channel RACH m, mi.

Due to the expanded set of channel measurement sequences m, mi the throughput in the RACH channel increases and also the delays time until a broadcast is successfully received reduced because fewer collisions occur on average.

The transmissions of the mobile stations UE in the RACH channel include the channel measurement sequence m, mi and additional symbols, e.g. B. mind at least 122, with which the mobile station UE has a reference number, the purpose of the access and, if necessary, additional information can sieren.  

Only the basic sequence m0 and an educational regulation for the channel measurement sequences m, mi ge be stores, the inverse mi0 and also the derivatives ml can then be generated quickly if required. This ver also reduces the effort of signaling, because within a radio cell must the participating radio station UE, NB the permissible channel sequences m, mi are communicated beforehand.

Claims (6)

1. Method for channel estimation in a radio communication system, in which

• Base stations (BS) and subscriber stations (MS) are connected to one another via a radio interface,
• a first channel measurement sequence (m1) is selected from a limited amount of channel measurement sequences (m),
• the first channel measurement sequence (m1) is transmitted via the radio interface,
• the received distorted first channel measurement sequences (m1) is compared with a stored first channel measurement sequences (m1) at the receiving end for channel estimation,

characterized in that

• - The amount of channel measurement sequences (m) is expanded by using the time-inverse channel measurement sequences (mi).

2. The method according to claim 1, wherein the number of channel measurement sequences (m, mi) by cyclical Ab directing one or more basic sequences (m0, mi0) is formed. 3. The method according to any one of the preceding claims, in which depending on the transmission conditions of the radio interface due to the cyclical derivation 4, 8 or 16 channel measurements sequences (m, mi) derived from a basic sequence (m0, mi0) become. 4. The method according to any one of the preceding claims, in which the channel measurement sequences (m, mi) are chip sequences and the radio interface according to a CDMA subscriber separation procedure is trained. 5. The method according to any one of the preceding claims, in which only the channel measurement sequence (m) is stored at the receiving end and for channel estimation two processes with the channel measurement sequence  (m) and with the inverse (mi) of the receiver Channel measurement sequence are performed. 6. The method according to any one of the preceding claims, in which the channel measurement sequences (m, mi) in one channel (RACH) with choice free multiple access can be sent.