KR100377661B1 - Telecommunications system with wireless code and time-division multiplex based telecommunication between mobile and/or stationary transmitting/receiving devices - Google Patents

Abstract

The present invention relates to a wireless communication system between mobile and / or fixed transceivers based on code and time division multiplex. In a wireless communication system between a mobile and / or fixed transceiver based on the code and time division multiplex, in TDD mode and FDD mode

1) During the first phase of the "handover" process, i.e. during the indication of "handover", a "handover" time slot pair is detected by the fixed transceiver (BS),

2) during the second phase of the "handover" process, i.e. during the initiation of "handover",

The fixed transceiver BS transmits the first message " handover request " M1 to the mobile transceiver MT1 ... MTn assigned to the fixed transceiver BS, and by this message, the fixed transceiver ( BS sends a "handover" time slot pair to mobile transceiver MT1 ... MTn, and

The fixed transceiver transmits the first message "handover request" to the mobile transceiver until the mobile transceiver allocated to the fixed transceiver transmits a "handover" by the first message,

3) The "handover" process is terminated during the third phase of the "handover" process, ie during the execution of "handover".

Description

TELECOMMUNICATIONS SYSTEM WITH WIRELESS CODE AND TIME-DIVISION MULTIPLEX BASED TELECOMMUNICATION BETWEEN MOBILE AND / OR STATIONARY TRANSMITTING / RECEIVING DEVICES

A wireless communication system between mobile and / or fixed transceivers is a special information system having an information transmission section between an information source and an information sink. Here, for example, a base station and a mobile station are used as the transmitting and receiving device for information processing and transmission,

1) information processing and information transmission can be made in one preferred transmission direction (simplex operation) or in two transmission directions (duplex operation),

2) information processing is preferably made of digital;

3) The information transmission is based on various information transmission methods for multiple use of the information transmission interval wirelessly through the remote transmission interval. Various methods for multiple use of the information transmission section are as follows. Frequency Division Multiple Access (FDMA), Time Division Multiple Access (TDMA) and / or Code Division Multiple Access (CDMA). These methods are for example

DECT [Digital Enhanced (formerly European) Cordless Telecommunication; See ETSI-Publikation ETS 300175-1 ... 9, October 1992 and DECT-Publikation des DECT-Forum, February 1997, pages 1 to 16, Nachrichtentechnik Elektronik 42 (1992), Jan./Feb. No. 1, Berlin, DE; U. Pilger "Struktur des DECT-Standards", pages 23-29],

GSM [Group Speciale Mobile Order Global System for Mobile Communication; See Informatik Spektrum 14 (1991) June, No 3, Berlin, DE; Publikation telekom praxis 4/1993, P. Smolka "GSM-Funkschnittstelle-Elemente und Funktionen", pages 17-24 A. Mann: "Der GSM-Standard-Grundlage fuer digitale europaeische Mobilfunknetze", pages 137-152,

UMTS (Universal Mobile Telecommunication System); Reference (1): Nachrichtentechnik Elektronik, Berlin 45, 1995, Volume 1, pages 10 to 14 and Volume 2, pages 24 to 27; P. Jung, B. Steiner: "Konzept eines CDMA-Mobilfunksystems mit gemeinsamer Detektion fuer die dritte Mobilfunkgeneration"; (2): Nachrichtentechnik Elektronik, Berlin 41, 1991, Vol. 6, pages 223 to 227 and page 234; P.W. Baier, P. Jung, A. Klein;: "CDMA -ein guenstiges Vielfachzugriffsverfahren fuer frequenzselektive und zeitvariante Mobilfunkkanaele"; (3): IEICE Tramsactions on Fundamentals of Electronics, Communications and Computer Sciences, Vol. E79-A, No 12, 1996 December, pages 1930-1937; P.W. Baier, P. Jung: "CDMA Myths and Realities Revisited"; (4): IEEE Personal Communications, February 1995, pages 38-47; A. Urie, M. Streeton, C. Mourot: “An Advanced TDMA Mobile Access System for UMTS”; (5): telekom praxis, 5/1995, pages 9-14; P.W. Baier: "Spread-Spectrum-Technik und CDMA-eine urspruenglich militaerische Technik erobert den zivilen Bereich"; (6): IEEE Personal Communications, February 1995, pages 48 to 53; P.G. Andermo, L.M. Ewerbring: "An CDMA-Based Radio Access Design for UMTS"; (7): ITG Fachberichte 124 (1993), Berlin, Offenbach: VDE Verlag ISBN 3-8007-1965-7, pages 67-75; Dr. T. Zimmermann, Siemens AG: "Anwendung von CDMA in der Mobilkommunikation"; (8): telcom report 16, (1993), Vol. 1, pages 38-41; Dr. T. Ketseoglou, Siemens AG und Dr, T. Zimmermann, Siemens AG: "Effizienter Teilnehmerzugriff fuer die 3. Generation der Mobilkommunikation -Vielfachzugriffsverfahren CDMA macht Luftschnittstelle flexibler"; (9): Funkschau 6/98: R. Sietmann "Ringenum die UMTS-Schnittstelle", pages 76-81] WACS or PACS, IS-54, IS-95, PHS, PDC, etc. [see: IEEE Communications Magazine, January 1995, pages 50-57; D.D. Falconer et al .: "Time Division Multiple Access Methods for Wireless Personal Communications"]

Conform to wireless standards such as

"Message" is a higher concept for meaning (information) as well as physical representation (signal). Even if the meanings of the messages are the same (ie, the information is the same), different signal types may appear. For example, a message related to one destination

1) in the form of burns

2) as a voice word

3) as a character word

4) It can be transmitted as an encrypted word or picture.

The transmission schemes according to (1) ... (3) are characterized as normally continuous (analog) signals, while in the transmission scheme according to (4), ordinary discontinuous signals (e.g. pulses, digital signals) are formed.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

1 is a "three plane structure" of a WCDMA / FDD air interface in "downlink",

2 is a "three plane structure" of the WCDMA / FDD air interface in the "uplink"

3 is a "three plane structure" of a TDCDMA / TDD air interface;

4 is a wireless scenario with channel multiple use according to frequency / time / code multiplex,

5 is a configuration of a base station formed of a transceiver;

6 is a configuration of a mobile station formed of a transceiver;

7 shows a DECT transmission time frame.

The UMTS-scenario (third mobile radio generation or IMT-2000) is provided with two partial scenarios, for example according to the publication Funkschau 6/98: R. Sietmann "Ringenum die UMTS-Schnittstelle", pages 76-81. In the first scenario, the licensed coordinate mobile radio is based on Wideband Code Division Multiple Access (WCDMA) technology and operates in FDD-mode (Frequency Division Duplex) as in GSM, while in the second scenario non-coordinated The mobile radio is based on TD-CDMA-technology (Time Division-Code Division Multiple Access) and is operated in TDD-mode (Time Division Duplex) as in DECT.

In the WCDMA / FDD operation of the universal mobile communication system, the air interface of the communication system is uplink and downlink of the communication. . 0.3, 1998-05-29 in accordance with a number of physical channels. The channel comprises a 720 ms long (T _MZR = 720 ms) multi time frame (super frame) (MZR), a 10 ms long (T _FZR = 10 ms) time frame (wireless frame) (ZR) and The first physical channel, the so-called dedicated physical control channel (DPCCH), and the second physical channel, so-called dedicated physical data in connection with a "three-plane structure" consisting of 0.625 ms long (T _ZS = 0.625 ms) time slots (ZS). Channel (DPDCH). Each multi time frame MZR comprises for example 72 time frames ZR, while each time frame ZR comprises for example 16 time slots ZS1... ZS16. Individual time slots (ZS, ZS1 ... ZS16) (bursts) are burst structures for the first physical channel (DPCCH), pilot sequence (PS) with N _pilot bits for channel evaluation, and Power Power Control Valid data with N _data bits for the second physical channel (DPDCH), TFCI sequence with TPC sequences (TPCS) with N _TPC bits and N _TFCI bits for Traffic Format Channel Indication Sequence (NDS).

ETSI or ARIB-in the "downlink" (downlink direction of communication; wireless connection from base station to mobile station) of the WCMDA / FDD system of FIG. 1- the first physical channel ["dedicated physical control channel (DPCCH)"] and second physical While the channel (“Dedicated Physical Data Channel (DPDCH)”) is multiplexed in time, the " uplink " (upward direction of communication; wireless connection from the mobile station to the base station)-I / Q multiplexing in FIG. In the I / Q multiplex, a second physical channel (DPDCH) is transmitted on an I-channel and a second physical channel (DPCCH) is transmitted on a Q-channel.

The air interface of the communication system in TDCDMA / TDD operation of the universal mobile communication system is a publication on the uplink and downlink of communication TSG RAN WG1 (S1.21): " 3 rd Generation Partnership Project (3GPP)" Vers. In accordance with 0.0.1, 1991-01, includes a "three-plane structure" consisting of multi time frame (MZR), time frame (ZR) and time slot (ZS) for all physical channels shown in FIG. Each multi time frame MZR comprises for example 72 time frames ZR, while each time frame ZR comprises for example 16 time slots ZS1... ZS16. Individual time slots (ZS, ZS1 ... ZS16) (bursts) are the first valid data sequence (NDS1) with N _Data1 bits in sequence according to the ARIB proposal, the pilot sequence (PS) with N _pilot bits for channel evaluation. A first time slot comprising a TPC sequence (TPCS) with N _TPC bits for power control, a TFCI sequence with N _TFCI bits for traffic format indication, and a guard time zone (SZZ) (guard period) with N _Guard bits The first valid data sequence NDS1, the first TFCI sequence TFCIS1, the midamble for channel evaluation (MIS), the second TFCI sequence (TFCIS2), A second time slot structure (burst structure) ZSS2, consisting of two valid data sequences NDS2 and a guard time zone SZZ.

4 is based on a GSM-wireless scenario, for example, comprising two radio cells and a base transceiver station disposed therein, wherein a first base station BTS1 (transceiver) draws a first radio cell FZ1; The second base station BTS2 (transceiver) "illuminates" the second radio cell FZ2 in all directions, and from Figures 1 and 2 the base stations BTS1, BTS2 are designed for the radio scenario and the radio cell FZ1 ), Via a radio interface with a plurality of mobile stations MS1 ... MS5 (transceiver device) at (FZ2), a radio unidirectional or bidirectional uplink (UL) for the corresponding transmission channel (TRC) And / or downlink (DL) —shows a wireless scenario with channel multiple use according to frequency / time / code multiplex that may or may be connected by communication. The base stations BTS1 and BTS2 are connected in a known manner (see GSM communication system) to a base station controller (BSC), which is managed and exchanged in the control category of the base station. Perform the function. A base station controller (BSC) is connected to a higher telecommunication network, such as a Public Switched Telecommunication Network (PSTN), via a Mobile Switching Center (MSC). The mobile switching center (MSC) is the management station for the communication system shown. The mobile switching center performs complete call management and authenticates the communication subscribers and monitors the position in the network via registers (not shown).

FIG. 5 shows the configuration of base stations BTS1 and BTS2 formed of a transceiver, while FIG. 6 shows the configuration of mobile stations MS1 ... MS5 formed of a transceiver. The base stations BTS1 and BTS2 transmit and receive information from and to the mobile stations MS1 ... MS5, while the mobile stations MS1 ... MS5 transmit and receive information from and to the base stations BTS1, BTS2. . The base station comprises a transmit antenna (SAN) and a receive antenna (EAN) for this purpose, while the mobile stations MS1 ... MS5 comprise an antenna ANT common to transmit and receive, controllable by an antenna switching connection (AU). do. The base stations BTS1 and BTS2 are at least one radio message FN with a frequency / time / code component of, for example, at least one mobile station MS1 ... MS5 via the uplink (receive path) receive antenna ANT. The mobile stations MS1 ... MS5 have at least one with frequency / time / code components of, for example, at least one base station BTS1, BTS2 via a common antenna ANT on the downlink (receive path). Receive a wireless message (FN). The radio message (FN) consists of a carrier signal spread over a wideband with modulated information consisting of data symbols.

Carrier signals received at the radio receiver (FEE) (receiver) are filtered, mixed and brought to an intermediate frequency. The intermediate frequency is sampled and quantized. After analog / digital conversion, the signal distorted by multipath propagation in the wireless path is fed to the equalizer. The equalizer compensates most of the distortion.

Then, in the channel estimator KS, the transmission characteristic of the transmission channel TRC for transmitting the radio message FN is evaluated. The transmission characteristics of the channel are represented by the channel pulse response over time. In order for the channel pulse response to be evaluated, the special additional information formed in the training information sequence on the transmitting side (in this case by the mobile station MS1 ... MS5 or the base station BTS1, (BTS2)) in the form of a so-called midamble. Assigned to a wireless message (FN).

Then, in one data detector DD common to all the received signals, the signal components unique to the individual mobile stations included in the common signal are corrected and separated in a known manner. After correction and separation, data symbols are converted into binary data in a symbol / data converter (SDW). The original bit stream is then obtained from the intermediate frequency in the demodulator DMOD, and then in a demultiplex DMUX individual time slots are assigned to the correct logical channel and accordingly to different mobile stations.

The bit sequence obtained in the channel codec KC is decoded according to the channel. Bit information is allocated to control and signaling time slots or voice time slots depending on the channel, and-in the case of a base station (FIG. 5)-control and signaling data and voice data for signaling and voice coding / for transmission to the base station controller (BSC). It is provided on one interface (SS) in charge of decoding (Sprach-Codec), while in the case of a mobile station (Fig. 6)-control and signaling of the control and signaling unit (STSE) in charge of complete signaling and control of the mobile station. Data and voice data are delivered to a voice codec (SPC) designed for voice input and output.

The voice data in the voice codec of the interface SS at the base stations BTS1 and BTS2 becomes a predetermined data stream (e.g., 64 kbit / s stream in the network direction or 13 kbit / s stream in the network direction).

In the control unit STE, complete control of the base stations BTS1 and BTS2 is made.

The base stations BTS1 and BTS2 are at least one radio message FN with a frequency / time / code component of, for example, at least one mobile station MS1 ... MS5 via the downlink (transmission path) transmit antenna SAN. The mobile stations MS1 ... MS5, on the uplink (transmission path), have at least one frequency / time / code component of, for example, at least one base station BTS1, BTS2 via a common antenna ANT. Send one wireless message (FN).

Since the transmission path starts at the base stations BTS1 and BTS2 in FIG. 5, the control and signaling data and the voice data obtained from the base station controller BSC through the interface SS in the channel codec KC are controlled and signaled at the time slot or voice. It is assigned to a time slot, which is coded into a bit sequence according to the channel.

Since the transmission path starts at the mobile stations MS1 ... MS5 in FIG. 6, the voice data obtained from the voice codec SPC and the control and signaling data obtained from the control and signaling unit STSE in the channel codec KC are controlled and controlled. It is assigned to a signaling time slot or voice time slot, which is coded into a bit sequence according to the channel.

The bit sequences obtained at the base stations BTS1 and BTS2 and the mobile stations MS1 ... MS5 are converted into data symbols by the data / symbol converter DSW. Then, each data symbol is spread by each subscriber individual code in a spreading device (SPE). Next, in the burst synthesizer (BZS) of the burst generator (BG) consisting of a burst synthesizer (BZS) and a multiplexer (MUX), a training format sequence in the form of a midamble for channel evaluation is added to the spread data symbol and In the multiplexer MUX, the burst information obtained in this manner is set to the correct time slot, respectively. Then, the obtained burst is high frequency modulated and digital / analog converted in the modulator MOD, and then the signal obtained in this manner is transmitted as a wireless message FN via the transmitting antenna SAN or the transmitting antenna SAN. Emitted from a common antenna (ANT).

A TDD communication system (Time Division Duplex) is a communication system in which a transmission time frame consisting of a plurality of time slots is preferably divided centrally for the downlink transmission direction (downlink) and the uplink transmission direction (uplink).

TDD communication systems including the transmission time frame include, for example, known DECT systems [Digital Enhanced (formerly European) Cordless Telecommunication; Nachrichtentechnik Elektronik 42 (1992) January / February, No. 1, Berlin, DE; ETSI-Publikation ETS 300175-1 ... 9, October 1992 and DECT-Publikation des DECT-Forum, February 1997, pages 1-16, U. Pilger "Struktur des DECT-Standards", pages 23-29 ]

7 shows a DECT transmission time frame with a duration of 10 ms, consisting of 12 "downlink" time slots and 12 "uplink" time slots. For any two-way communication connection to a frequency scheduled in the downlink direction (downlink) and uplink direction (uplink), the "downlink" time slot (ZS _DOWN ) and the "uplink" time slot (according to the DECT-standard) ZS _up ), one empty time slot pair is selected. The interval between the "downlink" time slot (ZS _DOWN ) and the "uplink" time slot (ZS _UP ) in the time slot pair is half the length (5ms) of the DECT transmission time frame according to the DECT-standard.

In a frequency division duplex (FDD) communication system, a transmission time frame composed of a plurality of time slots is transmitted in a first frequency band in a downlink transmission direction (downlink) and in a second frequency band in an uplink transmission direction (uplink). to be.

As the FDD communication system for transmitting time frames in the above manner, a known GSM system [Group Speciale Mobile Order Global System for Mobile Communication; See Informatik Spektrum 14 (1991) June, No 3, Berlin, DE; Publikation telekom praxis 4/1993, P. Smolka "GSM-Funkschnittstelle-Elemente und Funktionen", pages 17-24 A. Mann: "Der GSM-Standard-Grundlage fuer digitale europaeische Mobilfunknetze", pages 137-152] There is this.

The air interface for the GSM system includes a plurality of logical channels called a bearer service, namely, an AGCH channel, an access channel, a BCCH channel, a fast associated control channel, and a PCH channel. Paging Channel, RACH Channel (Random Access Channel), and TCH-Traffic Channel. Their function at the air interface is described, for example, in the publication Informatik Spektrum 14 (1991) June, No. 3, Berlin, DE; Regarding Publikation telekom praxis 4/1993, P. Smolka "GSM-Funkschnittstelle-Elemente und Funktionen", pages 17-24 A. Mann: "Der GSM-Standard-Grundlage fuer digitale europaeische Mobilfunknetze", pages 137-152 It is.

The main difference between a GSM system with a frequency and time plane, operated in a licensed, coordinated mode, and a DECT system with a frequency and time plane, operated in an unlicensed, non-coordinated mode, is the physical resource "channel". It is in the manner of being assigned to the system subscriber or communication subscriber.

In an authorized coordinate communication system, channel assignment is controlled by a management authority, i.e. a network operator. This is possible because all mobile stations within the radio range of the base station use the same time base. That is, because it operates in synchronization. Synchronous operation enables a clear definition of time slot boundaries and thus a clear separation of different communication subscribers. Adjacent base stations do not need to operate synchronously, since the separation of channels used in adjacent radio cells is generally done by the frequency plan in the frequency plane. Channel allocation in this manner is called "Fixed Channel Allocation (FCA).

In an unlicensed, non-coordinated communication system that does not have a network operator for channel assignment, the channel is first assigned dynamically-"Dynamic Channel Selection (DCS)"-then assigned. The frequency / time plane is used for "dynamic channel selection (DCS)" as well as for channel assignment as a platform or "pool". In such a system, the mobile station regularly monitors the frequency / time plane and selects a frequency / time slot combination where the transmission channel is least interfered. Since adjacent non-coordinated operation base stations and mobile stations are always asynchronous, so the time bases intervene with each other, a condition often occurs where the degree of interference reaches an unacceptable value. In this case, the relay of the communication connection to the other channel-"handover"-that is, the relay of different frequency / time slot combinations is started or started. This case is referred to as "intra cell handover".

In the category of UMTS scenarios (Third Mobile Radio Generation or IMT-2000), the WCDMA / FDD operation and the TDCDMA / TDD operation must be used together, so in addition to the efficient processing by logical channel or transmission path service (bearer handling), the above-mentioned From the reason, an appropriate " handover " process for a wireless communication system between mobile and / or fixed transceivers based on code and time multiplexing can be omitted.

It is an object of the present invention to provide a reliable "handover" process in accordance with an indication of "handover" in a wireless communication system between mobile and / or fixed transmission / reception apparatus based on code and time division multiplex.

This object is achieved by the features of claim 1.

The idea of the present invention is-in accordance with claim 1-in a wireless communication system between a mobile and / or fixed transmission / reception apparatus based on code and time division multiplex, in TDD mode and FDD mode.

1) during the first phase of the "handover" process, i.e. during the indication of "handover", a "handover" time slot pair is detected by the fixed transceiver;

2) during the second phase of the "handover" process, i.e. during the initiation of "handover",

The fixed transceiver BS transmits a first message " handover request " to the mobile transceiver configured for the fixed transceiver, and through which the fixed transceiver BS "handovers" time to the mobile transceiver. Pass slot pairs, and

The fixed transceiver BS transmits the first message "handover request" to the mobile transceiver until the mobile transceiver allocated to the fixed transceiver transmits a "handover" initiation by the first message. ,

3) The "handover" process is terminated during the third phase of the "handover" process, ie during the execution of "handover".

Preferred refinements of the invention are given in the dependent claims.

An embodiment of the present invention is illustrated by FIGS. 8 to 10.

8 illustrates a TDD time multiplex frame in which the number of time slots is different (modified) from the time frame of FIGS. 1 to 3 and the DECT transmission time frame of FIG.

9 shows a channel assignment table for channels with frequency-, code- and time multiplex components, based on the time multiplex frame of FIG.

10 shows a message flow diagram of a "handover" process.

8 shows a (modified) TDD time multiplex frame (MRR) with eight time slots ZS'1 ... ZS'8 starting from the time frames of FIGS. 1-3 and the DECT transmission timeframe of FIG. The first four time slots ZS'1... ZS'4 correspond to the downlink (downward transmission direction) DL and the second four time slots ZS'5. ..ZS'8) is provided for the uplink (uplink transmission direction) UL. The number of time slots is reduced from " 16 " according to Figs. 1 and 3 to 8 because only the channel allocation table of Fig. 9 is described, the number of time slots does not affect the present invention. Rather, the number of time slots may vary somewhat arbitrarily depending on the respective communication system—such as other physical resources (eg code, frequency, etc.).

9 shows a channel assignment table for channels with frequency-, code-, and time multiplex components, based on the time multiplex frame according to FIG. The temporal multiplex components of this table comprise time slots ZS'1 ... ZS'8 with a TDD classification according to FIG. The frequency multiplex component includes twelve frequencies (FR1 ... FR12), while the code multiplex component includes eight codes (pseudo random signals) C1 ... C8.

A transmission path service formed as a "bearer service" at the first frequency FR1, that is, a logical channel of a communication system required for downlink and / or uplink in a communication system, such as a control channel for signaling, an AGCH channel, a BCCH channel, The PCH channel, RACH channel, TCH channel and / or FACCH channel are bundled in the code plane spread by the codes C1 ... C8. This bundling appears to be desirable in the communication system described above, because it avoids unnecessary allocation of time slots, i.e., resources "time".

9 shows a preferred embodiment. According to this embodiment, the entire code C1 ... C8 for bundling the aforementioned transmission path service is fixedly given in advance during the first time slot ZS'1 on the downlink at the first frequency FR1 ( Combined) as a first selection time slot and uplink with a fixed, previously given (combined) second selection time slot for a fifth time slot ZS'5. Of course, less code may be used or more code may be used if more than eight codes are used.

In the bundling shown in FIG. 9, during the first time slot ZS'1, codes C1 ... C8 are used for one control channel for signaling and AGCH channel for signaling, and the other code for BCCH channel and PCH. For the channel, and the remaining six codes are partitioned to be reserved or provided for the TCH channel, while during the fifth time slot ZS'5, the codes C1 ... C8 are assigned for one RACH channel, The other code is split for the FACCH channel for handover indication, and the remaining six codes are reserved or provided for the TCH channel.

Further, as shown in FIG. 9, in different connection scenarios, that is, the first connection scenario VSZ1, the second connection scenario VSZ2, the third connection scenario VSZ3, the fourth connection scenario VSZ4, and In the fifth access scenario VSZ5, there are multiple bidirectional TDD communication connections in which each physical resource, " code, frequency, time " is allocated partially and identically in the downlink and uplink. If done, the spectral efficiency and / or performance of the communication system is improved. These connection scenarios VSZ1 ... VSZ5 belong to, for example, a first group G1 of communication connections indicated by rising and falling hatches and a second group G2 of communication connections indicated by falling hatches. Here, each group includes at least one bidirectional communication connection.

In a first access scenario VSZ1, a first group G1 of communication connections has six code-first codes C1, first during a second time slot ZS'2 on the downlink at a second frequency FR2. Has a second code C2, a third code C3, a fourth code C4, a fifth code C5, and a sixth code C6, and in the uplink during the sixth time slot ZS'6. While having six codes C1 ... C6, the second group G2 of the communication connection is the first code C1 during the fourth time slot ZS'4 on the downlink at the second frequency FR2. And the first code C1 during the eighth time slot ZS'8 in the uplink.

The fourth time slot ZS'4 and the second time slot ZS'2 are "downlink" time slots ZS _DOWN , while the sixth time slot ZS'6 and the eighth time slot ZS ' 8) is an "uplink" time slot (ZS _UP ).

First interval between the " downlink " time slot ZS _DOWN and " uplink " time slot ZS _UP -according to the prior art (see FIG. 7) for each communication connection in the groups G1, G2. AS1 is 1/2 of the time multiplex frame ZMR. Thus, the interval AS1 is part of the time multiplex frame ZMR length, which part has a value of 0.5.

In the second connection scenario VSZ2, the first group G1 of the communication connection receives six codes C1 ... C6 during the fourth time slot ZS'4 downlink at the fourth frequency FR4, And with the six codes C1 ... C6 for the sixth time slot ZS'6 on the uplink, while the second group G2 of the communication connection has a second downlink at the fourth frequency FR4. Codes C1 ... C4 during time slot ZS'2 and a first code C1 and a second code C2 during fifth time slot ZS'5 in the uplink.

The fourth time slot ZS'4 and the second time slot ZS'2 are the "downlink" time slots ZS _DOWN- as in the first connection scenario VSZ1, while the seventh time slot ( ZS'7 and the fifth time slot ZS'5 are "uplink" time slots ZS _UP .

The second interval AS2 between the " downlink " time slot ZS _DOWN and the " uplink " time slot ZS _UP in each communication connection of the groups G1 and G2 is the length of the time multiplex frame ZMR. Is part of which is measured so that the second interval AS2 is fixed and the value is greater than or less than 0.5.

In the third connection scenario VSZ3, the first group G1 of the communication connection is given four codes C1 ... C4 during the second time slot ZS'2 at the sixth frequency FR6 on the downlink, Uplink has six codes C1 ... C6 and seventh code C7 and eighth code C8 during the eighth time slot ZS'8 at the fifth frequency FR5, while communicating connection The second group G2 of the code C1 ... C3 during the third time slot ZS'3 at the sixth frequency FR6 on the downlink and the fifth group FR5 at the fifth frequency FR5 on the uplink. During the 5 time slots ZS'5 have codes C1 ... C4.

The second time slot ZS'2 and the third time slot ZS'3 are "downlink" time slots ZS _DOWN , while the eighth time slot ZS'8 and the fifth time slot ZS ' 5) is an "uplink" time slot (ZS _UP ).

In each communication connection of the groups G1 and G2, the third interval AS3 between the "downlink" time slot ZS _DOWN and the "uplink" time slot ZS _UP is the time multiplex frame ZMR length. The portion is measured so that the third interval AS3 is variable.

In the fourth access scenario VSZ4, the first group G1 of the communication connection is assigned the first code C1 during the fourth time slot ZS'4 at the eighth frequency FR8 on the downlink and the uplink. Having seven codes C1 ... C7 for the eighth time slot ZS'8 at the ninth frequency FR5, while the second group G2 of the communication connection is in the downlink at the eighth frequency FR8 It has a first code C1 during the third time slot ZS'3 and a first code C1 during the fifth time slot ZS'5 at the ninth frequency FR9 on the uplink.

The fourth time slot ZS'4 and the third time slot ZS'3 are "downlink" time slots ZS _DOWN , while the sixth time slot ZS'6 and the fifth time slot ZS ' 5) is an "uplink" time slot (ZS _UP ).

In each communication connection of the groups G1 and G2, the fourth interval AS4 between the "downlink" time slot ZS _DOWN and the "uplink" time slot ZS _UP is the time multiplex frame ZMR length. The portion is measured so that the fourth interval AS4 is fixed.

In a fifth access scenario VSZ5, the first group G1 of communication connections is in the downlink at the eleventh frequency FR11 during the fourth time slot ZS'4 during the first code C1 and the second code C2. ) Has a first code C1 and a second code C2 during the fifth time slot ZS'5 on the uplink, while the second group G2 of the communication connection is at the eleventh frequency FR11. Code C1 ... C5 for the first time slot ZS'1 on the downlink and Code C1 ... C3 for the eighth time slot ZS'8 on the uplink.

The fourth time slot ZS'4 and the first time slot ZS'1 are "downlink" time slots ZS _DOWN , while the fifth time slot ZS'5 and the eighth time slot ZS ' 8) is an "uplink" time slot (ZS _UP ).

In each communication connection of the groups G1 and G2, the fifth interval AS5 between the "downlink" time slot ZS _DOWN and the "uplink" time slot ZS _UP is the time multiplex frame ZMR length. The portion is measured so that the second interval AS2 is variable.

10 shows a message flow diagram of a "handover" process. The "handover" process is in principle three steps: the first step indicated by the indication of "handover", the second step indicated by the start or start of "handover" (handover initiation), and the presented sequence The third step is indicated by the execution of "handover".

When the quality of service (QoS) to be transmitted is degraded, "handover" is indicated by the base station BS. That is, the first phase of the "handover" process is initiated. The degradation of the quality of service (QoS) to be transmitted is optionally detected by a mobile station, i.e., a first mobile station (MT1), a second mobile station (MT2), or an nth mobile station (MTn). This qualitative degradation is transmitted to the base station BS via, for example, a FACCH channel. In this case, the base station BS is a "master" in relation to the "handover" process, while the mobile stations MT1 ... MTn are "slaves". However, the mobile station may be a “master” in connection with the “handover” process and the base station may be a “slave”.

By the indication of "handover" through the base station BS, the base station BS uses the channel selection list to select a "handover" time slot pair in which the characteristics of the service to be transmitted are further improved than the current communication slot pair. . A "handover" time slot pair is already determined during the first phase of the "handover" process, i.e., the "handover" indication.

At the second stage of the "handover" process, i.e. at the beginning of the "handover", the base station BS starts to form a BCCH channel during the "downlink" time slot of the "handover" time slot pair. Information (data service) transmitted in the "downlink" time slot of the communication time slot pair in the traffic mode from the "downlink" time slot of the "handover" time slot pair is transmitted simultaneously.

During the "broadcast" mode in which the second phase of the "handover" process begins-unlike the "traffic" mode-simultaneous transmission of information (data service) does not appear.

After the BCCH channel of the "downlink" time slot of the "handover" time slot pair is successfully formed, the base station BS sends a first message "Handover Request" (M1) through the BCCH channel to the " Downlink " time slot to the mobile stations MT1 ... MTn connected to the base station BS via the channel. The first message M1 conveys the position of the "handover" time slot pair. After transmission of the first message M1, the base station BS resumes simultaneous transmission (data service) of information in a "downlink" time slot of a communication time slot pair and a "handover" time slot pair, thereby transmitting the first message. The message M1 is " handed over " by the first message M1 to all mobile stations MT1 ... MTn connected to the base station BS on the BCCH channel during the " downlink " time slot of the communication time slot pair. Send until you start acknowledging.

When the mobile stations MT1 ... MTn connected to the base station BS have to transmit consecutive data of the related mobile stations MT1 ... MTn, from the communication time slot pair after reception of the first message M1 Replace with a "handover" time slot pair directly. Here, data transmission ends in the communication slot pair and resumes seamlessly in the "handover" time slot pair.

However, if the relevant mobile station MT1 ... MTn has to transmit consecutive data, the individual mobile station MT1 ... MTn sends a second message "Handover Confirmation" M2 in the signaling channel to the base station BS. ).

The base station BS thus receives, on the one hand, simultaneous data in the communication time slot pair and the "handover" time slot pair, and on the other hand, the second message M2. In the first case, data transmitted from the individual mobile stations MT1 ... MTn to the "uplink" time slot of the "handover" time slot pair is received without error by the base station BS, or-in the second case, the base station. When (BS) receives the second message (M2), the initiation of "handover" via the first message (M1) is considered to be last acknowledged by the base station (BS).

The second phase of the "handover" process, i.e. "handover" initiation, ends when all mobile stations MT1 ... MTn have acknowledged the "handover" initiation by the first message.

In the third step of the "handover" process, that is, the execution step of "handover", after all mobile stations MT1 ... MTn have acknowledged the "handover" initiation by the first message M1, "handover" The time slot pair is used as a new communication time slot pair, and then transmission ends in the communication slot pair thus far.

Claims (8)

A method for controlling relay of a communication connection between mobile and / or fixed transceivers in a wireless communication system based on code and time division multiplex, a) the predetermined carrier frequency FR1 ... FR12 for the communication system is divided into a number of time slots ZS'1 ... ZS "8 having a predetermined time slot duration T _ZS so that the communication system May be operated in a TDD mode or an FDD mode, wherein the time slots ZS'1 ... ZS'8 each form one time multiplex frame ZMR for each carrier frequency FR1 ... FR12, b) A maximum predetermined number of bidirectional communication connections in the communication system's time slots (ZS'1 ... ZS'8) or frequency ranges, via the up and down links Can be simultaneously formed between the communication subscriber and / or fixed transceiver BTS1, BTS2, and the transmitted subscriber signal is separably combined with the pseudo random signals C1 ... C8 individually assigned to the subscriber, c) during the first phase of the "handover" process, i.e. during the indication of "handover", a "handover" time slot pair is detected by the fixed transceiver (BS), d) during the second phase of the "handover" process, i.e. during the initiation of "handover", d1) The fixed transceiver BS transmits a first message "Handover Request" M1 to the mobile transceiver MT1... MTn assigned to the fixed transceiver BS, through the first message. The fixed transceiver BS transmits a "handover" time slot pair to a mobile transceiver MT1 ... MTn; d2) The fixed transceiver BS, when the mobile transceiver MT1 ... MTn assigned to the fixed transceiver BS, acknowledges the "handover" start by the first message M1. To transmit the first message " handover request " M1 to the mobile transceiver device MT1 ... MTn; e) the "handover" process is terminated during the third phase of the "handover" process, ie during execution of the "handover". The method of claim 1, The first message (M1) is acknowledged by a second message (M2). The method of claim 1, And the first message (M1) is acknowledged in such a way that the mobile transceiver (MT1 ... MTn) directly transmits the data to be transmitted in a "handover" time slot pair. The method according to any one of claims 1 to 3, A transmission path service formed of a "bearer service" required in downlink and / or uplink in a communication system is bundled in a code plane spread by a code (C1 ... C8). The method of claim 4, wherein At least a portion of a logical channel of a communication system, such as a control channel for signaling, an AGCH channel, a BCCH channel, a PCH channel, a RACH channel, a TCH channel and / or a FACCH channel, is bundled in the code plane as a transmission path service. . The method of claim 4, wherein The bundling in a first selection time slot (ZS'1) on the downlink and in a second selection time slot (ZS'5) on the uplink. The method of claim 6, The first time slot ZS'1 of the time slots ZS'1 ... ZS'8 is allocated to the first selection time slot ZS'1, and the time is assigned to the second selection time slot ZS'5. And a fifth time slot (ZS'5) of the slots (ZS'1 ... ZS'8) is allocated. The method according to any one of claims 1 to 3, In TDD mode, one time slot pair for each communication connection, namely the "downlink" time slot (ZS ' _Down ) and the "uplink" time slot (ZS' _UP ), is the same carrier frequency (FR1 ... FR12). ) Or the interval (AS2 ... AS5) between the "downlink" time slot (ZS ' _DOWN ) and the "uplink" time slot (ZS' _UP ) assigned to different carrier frequencies (FR1 ... FR12) And selected to be part of a multiplex frame (ZMR) length, wherein the spacings AS2... AS5 are fixed or variable.