DE19841469A1 - Method and radio communication system for the synchronization of subscriber stations - Google Patents

Abstract

According to the invention at least one broadband synchronization channel is assigned to a base station for the synchronization of subscriber stations in a radio communications system. The base stations at least once transmits a first and a second synchronization sequence which are different from each other. A subscriber station receives the synchronization sequences and carries out a synchronization on the basis of the time of reception of said synchronization sequences and the recognized synchronization sequences. The two synchronization sequences are transmitted at intervals, so that their interferences no longer accumulate and interference power is better distributed over time. This also makes it possible to use a single, switchable filter for the detection of both synchronization sequences.

Description

The invention relates to a method and a radio communication tion system for the synchronization of subscriber stations, ins especially the synchronization within a cellular network systems with broadband channels and FDD or TDD part subscriber separation.

In radio communication systems, messages (for example 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 connection between a base station and subscriber stations, the subscriber stations being mobile stations or fixed Can be radio stations. The radiation of the electromagnetic table waves takes place with carrier frequencies in the intended frequency band for the respective system. 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.

Two modes are provided for the third generation of mobile communications, where one mode is FDD (frequency division dup lex), see ETSI STC SMG2 UMTS-L1, Tdoc SMG2 UMTS-L1 221/98, dated August 25, 1998, and the other mode a TDD operation (time division duplex), see DE 198 27 700. The Be Operating modes are found in different frequency bands Application and use both time slots.

From ETSI STC SMG2 UMTS-L1, Tdoc SMG2 UMTS-L1 221/98, dated August 25, 1998, is in chapters 2.3.3.2.3 and 6.3 for the FDD Mode described a synchronization process, the synch uses chronization sequences that occur in each time slot  be sent. This is a synchronization of the participant possible at the beginning of the time slot. By the sequence of the transmissions of a second synchronization Sequence is signaled which code group (scrambling code) is used by the base station. Still is the frame start can also be derived from this.

The transmissions of the synchronization sequences of all base stations, see FIG. 10 in ETSI STC SMG2 UMTS-L1, Tdoc SMG2 UMTS-L1 221/98, dated August 25, 1998, relate to the beginning of a frame, a first and a second Synchronization sequence are transmitted simultaneously. The synchronization sequences represent interfering interferences for the other connections in the radio communication system, which impair the transmission quality.

It is therefore an object of the invention, a method and a Specify radio communication system with which the through the Synchronization-related interference for the other ver ties are reduced. This task is accomplished by the Method with the features of claim 1 and the radio Communication system with the features of claim 11 ge solves. Advantageous further developments are the dependent claims refer to.

According to the invention, a base station is used for synchronization of subscriber stations in a radio communication system, assigned at least one broadband synchronization channel, in which the base station has at least one first and one sends second synchronization sequence that differs the. A subscriber station receives the synchronization sequences and leads based on the time of reception of the synchro nization sequences and the recognized synchronization sequences a time synchronization through.

The two synchronization sequences are no longer time the same, but separated by a time interval  Posted. This adds up the interference of both Synchronization sequences no longer and the interference performance is better distributed over time. So that exists also the possibility of a single, switchable filter for To use detection of both synchronization sequences. The second synchronization sequence can also be used before the first are sent, so the time interval is negative.

The first and second synchronization sequences are advantageous sent in a time slot, d. H. cyclically recurring a synchronization channel as a time slot or part of a time slot for the subscriber stations offered in which two synchronization sequences are sent become. This makes fast synchronization as a pre suspension for logging into the radio communication system enables.

According to an advantageous embodiment of the invention first synchronization sequence is the same in each time slot and is used for coarse synchronization, while the second syn Chronization sequence from a group of synchronizations sequences can be selected. By the selection and sequence of second synchronization sequences are information about portable.

The synchronization sequences are advantageously un modulated orthogonal gold codes. So that the Synchroni sation procedures for FDD mode can hardly be modified. Interference of the synchronization channel on the rest According to the invention, connections are reduced in FDD mode. The synchronization process is also for radio communications tion systems in which the time slots are part of a TDD transmission schemes are with broadband channels. Here can have multiple time slots per frame for the Synchroni sation can be used. For multimode subscriber stations NEN parts of the detection device for both modes be applied.  

To those caused by the synchronization sequences To minimize interference on the other channels this with other transmissions from the base station lower power sent. Through a coding gain the information in the order of the synchronization sequences This disadvantage can easily be compensated for.

It is also advantageous to choose Synchroni sationssequen and / or their sequence further information transferred to. This will make it ready for operation faster of the subscriber stations. The others Information relates to a frame synchronization from which Base station used midambles, spreading codes or general my code or information on the configuration of an Organisa tion channel. A high coding gain is achieved if the coding of further information by choice and / or sequence of the synchronization sequences over several Time slots extends.

If, for example, 17 variants of the second synchronization sequence are used and the sequence of eight transmissions of the second synchronization sequence is evaluated, 17 ⁸ options are available. Only a small part of it has to be used.

To minimize system resources for "broadcast" purposes in the Consuming TDD mode are the synchronization sequences sent in time slots in which additional information of an organizational channel. So only a small number of downward time slots (from the base station to the subscriber station) become. The degrees of freedom of the asymmetry of both transmission directions in TDD mode is hardly restricted.

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

Show

Fig. 1 is a schematic representation of an FDD radio interface between subscriber stations and base station part,

Fig. 2 is a schematic representation of a TDD radio interface between subscriber stations and base station part,

Fig. 3a, a scheme for the use of a temporal Ab b stands when sending the synchronization sequences, and

Fig. 4 is a flow chart for the synchronization.

In Fig. 1, the radio transmission in FDD mode in the downward direction from the base station to the subscriber stations is shown schematically, wherein as in ETSI STC SMG2 UMTS-L1, Tdoc SMG2 UMTS-L1 221/98, from 25.8.1998, Fig. 9, a frame structure is assumed. A superframe contains 72 frames fr1, fr2, .. fri, .. fr72, each individual frame slotting ts1, ts2,. . , tsi,. . , ts16 includes. Different channels SCH, DPCH, CCPCH are offered in parallel within a time slot tsi, the information of the channels SCH, DPCH, CCPCH differing by a spreading with individual spreading code.

A first check is of the multitude of possible channels channel CCPCH with a fixed data rate shown that one out 8-bit pilot sequence contains pilot that is created by a Data part data followed. The pilot sequence pilot is used for Channel estimation. A physika assigned to a participant Channel DPCH consists of control channel DPCCH and one DPDCH data channel. The former contains a pilot sequence pilot, Information on the power control TPC and information on the service comm combination TFI. The latter contains spread data.

In a synchronization channel SCH are synchronization sequences cp, cs sent with a known signal shape,  which the subscriber stations as a reference for a temporal Serve synchronization. With this FDD transmission method are the frequency bands for the uplink and the Downward direction separated.

The frame structure of the radio transmission in TDD mode can be seen from FIG. 2. According to a TDMA component (time division multiple access), a division of a broadband frequency range into a plurality of time slots ts of the same time duration is provided, for example 16 time slots ts0 to ts15, which form a frame fr. A frequency band extends over a frequency range B. Some of the time slots are used in the downward direction DL and some of the time slots are used in the upward direction UL. An asymmetry ratio of 3: 1 in favor of the downward direction DL is shown as an example. 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. Due to the variable allocation of the time slots ts for upward or downward direction UL, DL, a wide range of asymmetrical resource allocations can be made.

Information from several connections is transmitted in radio blocks within the time slots. The data d are connection-individually spread with a fine structure, a spreading code c, so that on the receiving side, for example, n connections can be separated by this CDMA component (code division multiple access). The spreading of individual symbols of the data d has the effect that, within the symbol duration T _sym Q chips of the duration Tchip are transmitted. 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: 4,096 Mcps
Frame duration: 10 ms
Number of time slots: 16
Time slot duration: 625 µs
Spreading factor: variable
Modulation type: QPSK
Bandwidth: 5 MHz
Repeat frequency value: 1

These parameters enable the best possible harmonization the TDD and FDD mode for the 3rd generation of mobile communications.

According to FIG. 3a in the downward direction, for example, two time slots ts 0, ts 8 uses for synchronization in the TDD mode be. Thus, two synchronization sequences cp, cs are sent in a time slot ts8 separated by a time interval tgap. The separation of the two synchronization sequences cp, cs has the advantage of reduced interference, since the interference power of both sequences is better distributed over time. The first synchronization sequence cp is the same in each time slot, for example the two time slots ts0, ts8 of the synchronization channel SCH for the TDD mode and each time slot ts for the FDD mode according to FIG. 3b. The second synchronization sequence cs can be re-selected from time slot to time slot.

The choice and order of the second synchronization sequence In TDD mode, cs also corresponds to a base station individual time offset toff with which the transmission of the first synchronization sequence cp with respect to the beginning of the Time slot ts8 is delayed to overlap the out consignments of neighboring and synchronized To prevent base stations. By receiving and evaluating the synchronization sequences cs can be the receiving part slave station MS determine the time offset toff and at the Take synchronization into account.

By the choice and sequence of the second synchronization sequences cs over several transmissions arise at the Ver Using 17 different unmodulated orthogonal cold  Codes with 256 chip length many different possibilities with which further information is transmitted. Because of the many possibilities, the coding gain is great, so that the synchronization sequences cp, cs with less Power can be sent.

The further information concerns the frame synchronisa tion and code used by the base station depending on the mode groups (FDD) or Mittambamel, spreading codes (TDD; whereby the Middle notes and spreading codes are assigned independently and information about the configuration of an organization channel BCCH. Two used for synchronization Time slots ts per frame for the frame start after Detect the synchronization in a time slot ts with the factor two inaccurate; by 16 timeslots by a factor 16. The frame synchronization is therefore easy through a certain sequence of second synchronization sequences cs brought about. In addition, the later detection of Information on a scalable BCCH organizational channel accelerates if configuration information is already during synchronization.

The in a control device, e.g. B. the radio resource mana ger RNC of a base station system, assignment made a broadband synchronization channel SCH for the syn chronization and in TDD mode also different time offsets regarding the start of time slot ts0, ts8 for sending the synchronization sequences cp, cs precedes synchronization as the first step 1.

In a second step 2, the base station sends BS controlled through the control means KM, the synchronization sequences cp, cs in the given order and with the given time interval. The order can be for each base sta tion BS be individual and correspond with the others Information and in TDD mode also with the time Offset toff.  

A subscriber station MS receives 3 in a third step the synchronization sequences cp, cs and performs a coarse syn Chronization based on the first synchronization sequence cp by.

By evaluating the second synchronization sequences cs in A fourth step 4 is also the time in TDD mode slot synchronization to the beginning of the time slot ts possible, by evaluating further information also the frame synchronization for both modes in a fifth Step S and preparation for the reception of the organisa tion channel is carried out.

Steps 3 to 5 are added by the subscriber station assigned synchronization means performed SYNC for example by a signal processing processor and by several signal-matched filters or a switchable signal matched filter formed correlators are formed.

Claims (11)

1. Procedure for the synchronization of subscriber stations (MS) in a radio communication system, in which
a base station (BS) is assigned at least one broadband synchronization channel,
the base station (BS) in the synchronization channel sends at least once a first and a second synchronization sequence (cp, cs) which differ,
a subscriber station (MS) receives the synchronization sequences (cp, cs),
the subscriber station (MS) uses the time of reception of the synchronization sequences (cp, cs) and the recognized synchronization sequences (cp, cs) to carry out a time synchronization,
characterized in that the two synchronization sequences (cp, cs) are transmitted separately by a time interval (tgap). 2. The method according to claim 1, characterized in that that the first and second synchronization sequence (cp, cs) in a time slot (ts) are sent. 3. Procedure according to claim 2, characterized in that that the first synchronization sequence (cp) in every time slot (ts) is the same and the second synchronization sequence (cs) from a group of synchronization sequences (cs) can be selected. 4. The method according to any one of the preceding claims, characterized characterized in that the synchronization sequences (cp, cs) are unmodulated orthogonal gold codes. 5. The method according to any one of the preceding claims, characterized characterized in that the synchronization sequences (cp, cs) with compared to other transmissions of the base station (BS) lower power are sent.   6. The method according to any one of the preceding claims, characterized characterized in that the broadband synchronization channel is part of an FDD transmission scheme, the syn Chronization sequences (cp, cs) of several broadcasts for the Synchronization can be used. 7. The method according to any one of the preceding claims, characterized characterized in that the time slots (ts) are part of a TDD Transmission schemes are, with multiple time slots (ts) per Frame (fr) can be used for synchronization. 8. The method according to claim 7, characterized in that that the synchronization sequences (cp, cs) in time slots (ts) are sent, in which additional information of a Organizational channel (BCCH) are transmitted. 9. The method according to any one of the preceding claims, characterized characterized in that the sequence during synchronization several synchronization sequences (cs) is taken into account. 10. The method according to any one of the preceding claims, characterized characterized by the sequence of the Synchronisa tion sequences (cp, cs) further information the one that has a frame synchronization and / or from the base station (BS) used spread codes (c) concern. 11. Radio communication system
with several base stations (BS) for at least one-time transmission of a first and a second synchronization sequence (cp, cs), which differ,
with a control device (RNC) which assigns at least one broadband synchronization channel to the base station (BS), with a subscriber station (MS) for receiving and evaluating the synchronization sequences (cp, cs),
with the subscriber station assigned synchronization means (SYNC) which, based on the time of reception of the synchronization sequences (cp, cs) and the recognized synchronization sequences (cp, cs), carries out a time synchronization, characterized in that control means assigned to the base station (BS) ( KM) control the transmission times of the synchronization sequences (cp, cs) so that the two synchronization sequences (cp, cs) are sent separately by a time interval (tgap).