JP2002505549A - Telecommunications system for performing wireless telecommunications between mobile and / or stationary transmitters / receivers based on code multiplexing and time division multiplexing - Google Patents

Abstract

(57) [Summary] Improving "bearer processing" over a conventional technique for a telecommunication system performing wireless telecommunication between mobile and / or stationary transmission / reception devices based on code multiplexing and time division multiplexing. Therefore, in both TDD and FDD modes, the transmission route service configured as a "bearer service", ie the logical channels of the telecommunications system, such as the AGCH, BCCH, PCH, RACH and / or FACCH channels (these (Needed in the downstream and / or upstream direction in the telecommunications system) at the code level formed by the code.

Description

DETAILED DESCRIPTION OF THE INVENTION

A telecommunications system for performing wireless remote communication between mobile and / or stationary transmitting and receiving devices is a special communication system having a communication transmission section between a communication source and a communication receiving side. For example, a base station and a mobile unit are used as a transmitting device and a receiving device for communication processing and communication transmission. 1) Communication processing and communication transmission are performed in a preferred transmission direction (unidirectional communication) or in both transmission directions (two-way communication). 2) the communication process is advantageously digital; 3) the communication transmission is wireless via a remote transmission section and to various communication transmission schemes for multiplexing the communication transmission section. It is performed based on. As various communication transmission methods, for example, F
DMA (Frequency Division Multiple Access), TDMA (Time Division Mu
ltiple Access) and / or Code Division Multiple Access (CDMA), for example, according to the following wireless standards. As radio standards, DECT [Digital Enhanced (formerly European) Cordless Telecommunication; Nachrichtentechnik Elektrnik 42 (1992) Jan./Feb. Nr. 1, Berlin DE; U. Pi
lger "Struktur des DECT-Standards", PP.23-29, ETSI-Publikation ETS 300175-
1 ... 9, Oct. 1992, DECT-Publikation des DECT-Forum, Feb. 1997, pp. 1-16], GSM [Groupe Speciale Mobile or Global System for Mobile Communica
tion; Informatik Spektrum 14 (1991) Juni, Nr. 3, Berlin, DE; A. Mann: "Der GSM-S
tandard-Grundlage fuer digitale europaeische Mobilfunknetze ", pp.137-152,
telekom praxis 4/1993, P. Smolka "GSM-Funkschnittstelle-Elemente und Fun
ktionen ", pp. 17-24], UMTS [Universal Mobile Telecommunication System; (1): Nachrichtentec
hnik Elektronik, Berlin 45, 1995 Heft 1, pp. 10-14, Heft 2, pp. 24-27; P. Ju
ng, B. Steiner: "Konzept eines CDMA-Mobilfunksystems mit gemeinsamer Dete
ktion fuer die dritte Mobilfunkgeneration "; (2): Nachrichtentechnik Elek
tronik, Berlin 41,1991, Heft 6, PP.223-227 &pp.234; PWBaier, J. Jung,
A. Klein: "CDMA-ein guenstiges Vielfachzugriffsverfahren fuer frequenzs
elective und zeitvariante Mobilfunkkanaele "; (3): IEICE Transactions on
Fundamentals of Electronics, Communications and Computer Sciences, Vol.E7
9-A, No. 12, Dec. 1996, pp. 1930-1937; PWBaier, P. Jung: "CDMA Myths and R
ealities Revisited "; (4): IEEE Personal Communications, Feb. 1995, pp.38
-47; A.Urie, M.Streeton, C.Mourot: "An Advanced TDMA Mobile Access Syste
m for UMTS "; (5): telekom praxis, 5/1995, pp.9-14; PWBaier:" Spread-Sp
ectrum-Technik und CDMA-eine urspruenglich militaerische Technik erobe
rt den zivilen Bereich "; (6): IEEE Personal Communications, Feb. 1995, p.
p.48-53; PGAndermo. LMEwerbring: "An CDMA-Based Radio Access Design
for UMTS "; (7): ITG Fachberichte 124 (1993), Berlin, Offenbach: VDE Verl
ag ISBN 3-8007-1965-7, pp. 67-75; Dr. T. Zimmermann, Siemens AG: "Anwendung
von CDMA in der Mobilkommunikation "; (8): telcom report 16, (1993), Heft
1, pp.38-41; Dr.T.Ketseoglou, Siemens AG, Dr.T.Zimmermann, Siemens AG:
"Effizienter Teilnehmerzugriff fuer die 3. Generation der Mobilkmmunikat
ion-Vielfachzugriffsverfahren CDMA macht Luftschnittstelle flexibler ";
(9): Funkschau 6/98: R. Sietmann "Ringen um die UMTS-Schnittstelle", pp.
76-81], WACS or PACS, IS-54, IS-95, PHS, PDC etc. [IEEE Communications
Magazine, Jan. 1995, pp. 50-57; DDFalconer et al: "Time Division Multip
le Access Methods for Wireless Personal Communocations ".

[0002] "Communication" is a generic concept for semantic content (information) and physical presentation (signal). Even if the meaning of the communication is the same, that is, even if the information is the same, different signal forms may occur. Thus, for example, the subject communication can be transmitted as (1) in the form of an image, (2) as a spoken word, (3) as a written character, and (4) as an encrypted word or image. .

The transmission formats according to (1) to (3) are usually represented by continuous (analog) signals. On the other hand, in the transmission format according to (4), usually, a discrete signal (for example, a pulse or a digital signal) is generated.

What FIGS. 1 to 7 show, FIG. 1 shows a three-level structure of a WCDMA / FDD wireless interface in the “downlink”.

FIG. 2 shows a three-level structure of a WCDMA / FDD radio interface on the “uplink”.

FIG. 3 shows a three-level structure of a TDCDMA / TDD radio interface.

FIG. 4 shows a radio scenario in which channel multiplexing is used by frequency multiplexing / time division multiplexing / code multiplexing.

FIG. 5 shows the basic structure of a base station configured as a transmitting device / receiving device.

FIG. 6 shows the basic structure of a mobile station which is also configured as a transmitting / receiving device.

FIG. 7 shows a DECT transmission time frame.

In the UMTS scenario (3rd generation mobile radio or IMT-2000), for example, the publication Funkschau 6/98: R. Sietmann "Ringen um die UMTS-Schnittstelle", pp.
There are two partial scenarios according to .76-81. In the first partial scenario, the licensed and tuned mobile radio is a WCDMA technology (Wideband Code Division Multi-Media).
For example, in GSM, FDD mode (Frequency Divisi)
on Duplex). On the other hand, in the second partial scenario, the unlicensed uncoordinated mobile radio uses TD-CDMA technology (Time Division-Code Division Multiplexing).
iple Access), for example, in DECT in TDD mode (Time Division
Duplex).

[0012] For WCDMA / FDD operation of a universal mobile telecommunications system, the radio interface of the telecommunications system is used in the up and down direction of telecommunications, and the publication ETS
I STC SMG2 UMTS-L1, Tdoc SMG2 UMTS-L1 163/98: "UTRA Physical Layer Descr
According to iption FDD Parts "Vers.0.3, 1998-05-29, each contains multiple physical channels. Of these, the first physical channel (the so-called Dedicated Physica
l Control CHannel DPCCH) and a second physical channel (so-called Dedicated Ph
ysical Data CHannel DPDCH) is shown in FIGS. 1 and 2 based on a three-level structure (three-layer structure). The three-level structure consists of a multi-time frame (superframe) MZR having a length of 720 ms (T _MZR = 720 ms), a time frame (radio frame) having a length of 10 ms (T _FZR = 10 ms), and a length of 0.625 ms. (T _ZS = 0.625 ms). Each multi-time frame MZR includes, for example, 72 time frames ZR, and each time frame ZR has, for example, further 16 time slots ZS1... ZS16. Individual time slots ZS, ZS1 ... ZS16 (burst) has a burst structure for the first physical switch Yaneru DPCCH, for channel estimation, the pilot sequence PS with N _{pilo t} bits, for output control of, N TPC sequence TPCS (Traffic Power Control) with _TPC bits, and for the transport format indication, TFCI sequence TFCIS with N _TFCI bits (Traffic
Format Channel Indication), as well as a second physical channel DPDCH, having a valid data sequence NDS of N _Data bits.

In the downlink (downward direction of telecommunications; wireless connection from a base station to a mobile station) of a WCDMA / FDD system of ETSI or ARIB, FIG. 1 shows a first physical channel (DPCCH). )) And a second physical channel (Dedicated Physical Data Channel (DPDCH)) are temporally multiplexed. On the other hand, in the uplink (uplink direction of telecommunications; wireless connection from a mobile station to a base station), In FIG. 2, I / Q multiplexing is performed. In I / Q multiplexing, the second physical channel DPDCH is transmitted on the I channel and the first physical channel DPCCH is transmitted on the Q channel.

For TDCDMA / TDD operation of a general purpose mobile telecommunications system, the radio interface of the telecommunications system can be used in both the upstream and downstream directions of telecommunications.
TSG RAN WG1 (S1.21): "3rd Generation Partnership Project (3GPP)" Vers.0
According to .0.1, 1999-01, again based on a three-level structure for all physical channels. This three-level structure consists of a multi-time frame MZR, a time frame ZR and a time slot ZS, and is shown in FIG. Each multi-time frame MZR also comprises 72 time frames ZR, each time frame ZR having, for example, again 16 time slots ZS1... ZS16. Each of the time slots ZS, ZS1... ZS16 (burst) has a first time slot structure (burst structure) ZSS1 proposed by ARIB or a second time slot structure (burst structure) ZSS2 proposed by ETSI. . The first time slot structure sequentially, first effective data Siemens N _Data1 bits, with the N _{pil ot} bits, pilot sequence PS for channel estimation, comprising a N _TPC bit, the output control TPCS sequence, a _TFCI sequence with N _TFCI bits for indicating a transport format, a second valid data sequence NDS2, and a guard time zone SZZ (guard period) of N _Guard bits. The second time slot structure includes, in order, a first valid data sequence NDS1, a first TFCI sequence TFCIS1, a midamble sequence MIS for channel estimation, a second TFCI sequence TFCIS2, a second valid data sequence NDS2, And a protection time slot SZZ.

FIG. 4 shows, for example, two radio cells and a base station (Base Transceiver) arranged therein.
2 shows a GSM radio scenario with iver Station). Here, the first base station BTS
1 (transmitter / receiver) omnidirectionally “covers” the first radio cell FZ1 and the second base station BTS2 (transmitter / receiver) omnidirectionally covers the second radio cell FZ2. Here, based on FIG. 1 and FIG. 2, a radio scenario of using channel multiplexing by frequency multiplexing / time division multiplexing / code multiplexing is shown. In this scenario, base station BTS1
, BTS2 via a radio interface installed for this radio scenario, a plurality of mobile stations MS1... MS5 (transmitting / receiving equipment) present in the radio cells FZ1, FZ2 and the corresponding transmission channel TRC. (Transmission Channel) unidirectional or bidirectional (uplink UL (Up Link) and / or downlink DL (D
own Link)). The base stations BTS1 and BTS2 are connected to a base station control unit BSC (Base Stati
on Controller), the base station controller performs frequency management and switching functions within the framework of base station control. The base station control unit BSC is a mobile switching center MSC (Mobi
le Switching Center), a higher-level telecommunications network, for example, PSTN (Public Swi
tched Telecommunication Network). The mobile switching center MSC is the managing central office for the telecommunication system shown. The mobile switching center provides full call management, authenticates telecommunications subscribers and incorporates local monitoring of the network with built-in registers (not shown).

FIG. 5 shows the basic structure of base stations BST1 and BST2 configured as transmitting / receiving devices, and FIG. 6 shows mobile stations MS1... MS5 similarly configured as transmitting / receiving devices. The basic structure of is shown. The base stations BST1 and BST2 transmit and receive wireless communications from and to the mobile stations MS 1... MS5, while the mobile stations MS1... MS5 transmit and receive from the base stations BTS1 and BTS2. It sends and receives wireless communication. For this purpose, the base station has a transmitting antenna SAN and a receiving antenna EA
N, and the mobile stations MS1 to MS5 have a common antenna ANT for transmission and reception, which can be controlled by the antenna switching unit AU. In the upstream direction (reception path) base station B
ST1 and BST2 receive at least one radio communication FN having a frequency component / time component / code component from at least one of the mobile stations MS1 to MS5 via the reception antenna EAN. On the other hand, the mobile stations MS1... MS5 are provided with at least one radio having a frequency component / time component / code component from at least one of the base stations BST1 and BST2 via a common antenna ANT in the downlink direction (reception path). The communication FN is received. Here, the wireless communication FN includes a carrier signal in which information integrated from data symbols is superimposed and modulated and spread over a wide band.

In the radio receiver FEE (receiver), the received carrier signal is filtered, down-mixed to an intermediate frequency, further sampled, and quantized. After the A / D conversion, the signal distorted by the multipath propagation in the radio path is supplied to the equalizer EQL, and the equalizer almost equalizes the distortion (Stw .: synchronization).

Subsequently, the channel estimator KS transmits the transmission channel TRC through which the wireless communication FN is transmitted.
Is estimated. Here, the transmission characteristics of the channel are represented by the channel pulse response in the time domain. In order to be able to estimate the channel pulse response, the radio communication FN was configured as a training information sequence on the transmitting side (in this embodiment by the mobile stations MS1 ... MS5 or by the base stations BTS1, BTS2). Specific additional information is allocated or assigned in the form of a so-called midamble.

Following this, the individual mobile station-specific signal components contained in the common signal are equalized and separated in a known manner by a common data detector DD for all received signals. After equalization and separation, the symbol / data converter SDW converts the previously existing data symbols into binary data. The original bit stream is then formed from the intermediate frequency in the demodulator DMOD, and then the individual time slots are assigned to the correct logical channel and thus to different mobile stations in the demultiplexer DMUX.

In the channel codec KC, the obtained bit sequence is decoded for each channel. Bit information is allocated to control and signaling time slots or voice time slots according to the channel. In the case of a base station (FIG. 5), control and signaling data and voice data are transmitted to the base station controller B.
For transmission to the SC, it is handed over to a common interface SS responsible for signaling and voice coding / decoding (voice codec). On the other hand, in the case of the mobile station (FIG. 6), the control and signaling data is transmitted to the control and signaling unit ST which controls the complete signaling and control of the mobile station.
The voice data is delivered to the SE, and the voice data is delivered to a voice codec SPC configured for voice input / output.

In the audio codec of the interface SS in the base stations BTS1 and BTS2,
The audio data becomes a predetermined data stream (for example, a stream of 64 kbit / s in the net direction and a stream of 13 kbit / s in the net direction).

In the control unit STE, complete control of the base stations BST1 and BST2 is executed.

In the downlink direction (transmission path), the base stations BTS1 and BTS2 transmit at least one radio communication FN having a frequency component / time component / code component via a transmission antenna SAN.
To at least one of the mobile stations MS1... MS5. On the other hand, mobile stations MS1 ...
The MS 5 transmits the frequency component / signal through the common antenna ANT in the uplink direction (transmission path).
At least one radio communication FN with a time component / code component is transmitted to the base station BTS1,
Transmit to at least one of BTS2.

The transmission path starts as follows in the case of the base stations BST1 and BST2 in FIG. That is, control and signaling data and voice data obtained from the base station control unit BSC via the interface SS by the channel codec KC are allocated to control and signaling time slots or voice time slots, and these are converted into bit sequences for each channel. Start as encoded.

The transmission path starts as follows in the case of the mobile stations MS 1 to MS 5 in FIG. That is, 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 allocated to control and signaling time slots or voice time slots, and these are assigned to each channel. It starts as encoded into a bit sequence.

The bit sequences obtained by the base stations BTS1, BTS2 and the mobile stations MS1... MS5 are respectively converted into data symbols by a data / symbol converter DSW. Following this, the respective data symbols are spread in a spreading device SPE with respective subscriber-specific codes. The burst generator BG includes a burst synthesizer BZS and a multiplexer MUX. Next, in the burst generator BG, a training information sequence is added to each spread data symbol in the burst synthesizer BZS for channel estimation in the form of a midamble, and the multiplexer M
The burst information thus obtained in the UX is set in the correct time slot. Subsequently, each of the obtained bursts is up-modulated by the modulator MOD and D / A converted. Thereafter, the signal thus obtained is radiated as the radio communication FN via the radio transmission device FSE (transmitter) via the transmission antenna SAN or the common antenna ANT.

In the TDD telecommunication system (Time Division Duplex), a transmission time frame composed of a plurality of time slots is transmitted in a downlink transmission direction (downlink) and an uplink transmission direction (downlink).
(Uplink) is a telecommunications system which is advantageously centrally divided.

A TDD telecommunications system having such a transmission time frame is, for example, a known DECT system [Digital Enhanced (formerly: European) Cordless
Telecommunication; Nachrichtentechnik Elektrnik 42 (1992) Jan./Feb. Nr. 1,
Berlin, DE; U. Pilger "Struktur des DECT-Standards", pp.23-29, ETSI-Publ
ikation ETS 300175-1 ... 9, Oct. 1992, DECT-Publikation des DECT-Forum, Fe
b. 1997, pp. 1-16].

FIG. 7 shows a DECT transmission time frame having a duration of 10 ms. This time frame consists of twelve downlink time slots and twelve uplink time slots. For any two-way telecommunications connection in the downlink DL (downlink) and uplink UL (uplink) at a given frequency, DE
According to the CT standard, an empty time slot pair comprising a downlink time slot ZS _DOWN and an uplink time slot ZS _UP is selected. In this time slot pair, the interval between the downlink time slot ZS _DOWN and the uplink time slot ZS _UP is also half of the DECT transmission time frame (5 ms) according to the DECT standard.

In the FDD telecommunication system (Frequency Division Duplex), a time frame composed of a plurality of time slots is a first frequency band for a downlink (downlink) and a time frame for an uplink (uplink). Is a telecommunications system transmitted on a second frequency band.

An FDD telecommunications system for transmitting time slots in this way is, for example, the well-known GSM system [Groupe Special Mobile or Global System f.
or Mobile Communication; Informatik Spektrum 14 (1991) Juni, Nr. 3, Berli
n, DE; A. Mann: "Der GSM-Standard-Grundalge fuer digitale europaeische
Mobilfunknetze ", pp.137-152, telekom praxis 4/1993, P.Smolka" GSM-Funksc
hnittstell-Elemente und Funktionen ", pp. 17-24].

The radio interface for the GSM system handles a number of logical channels called transmission route services (bearer services). For example, the AGCH channel (
Access Grant CHannel), BCCH channel (Broad Cast CHannel), FACC
H channel (Fast Associated Control CHannel), PCH channel (Paging CH)
annel), a RACH channel (Random Access CHannel), and a TCH channel (Traffic CHannel), and their respective functions in the radio interface are described, for example, in the publication Informatik Spektrum 14 (1991) Juni, Nr. 3,
Berlin, DE; A. Mann: "Der GSM-Standard-Grundlage fuer digitale europae
ische Mobilfunknetze "pp.137-152, telekom praxis 4/1993, P.Smolka" GSM-F
unkschnittstelle-Elemente und Funktionen ", pp. 17-24.

In the context of the UMTS scenario (3rd generation mobile radio or IMT-2000)
Since the WCDMA / FDD operation and the TDCDMA / TDD operation must be used in common, efficient handling by logical channels or transmission route services (bearer processing) requires moving and / or moving based on code multiplexing and time division multiplexing. Alternatively, it is desired in a wireless interface for a remote communication system that performs wireless remote communication between stationary transmitting and receiving devices.

An object of the present invention is to carry out this “bearer processing” for a telecommunication system that performs wireless telecommunication between mobile and / or stationary transmitting and receiving devices based on code multiplexing and time division multiplexing. It is an improvement over the prior art.

This problem is solved by the features of claims 1 and 6.

According to claims 1 and 6, the technical idea underlying the present invention is a telecommunications system for performing wireless telecommunications between mobile and / or stationary transmitting and receiving equipment based on code multiplexing and time division multiplexing. In contrast, in both the TDD mode and the FDD mode, transmission route services configured as "bearer services", such as logical channels of a telecommunications system according to claims 2 to 7, ie AGCH channels, BCCH channels, PCH channels, RACH channels, And / or multiplexing the FACCH channels (which are required in the downlink and / or uplink in telecommunications systems) at the code level formed by the codes.

The improvement of the invention according to claims 5 to 10 is advantageous in that the performance and the spectral efficiency of the telecommunication system in the TDD mode are, in part, significantly improved over known TDD systems.

[0038] Further advantageous refinements of the invention are described in the other claims.

An embodiment of the present invention will be described with reference to FIGS. 8 and 9.

FIG. 8 shows a TDD time-division multiplex frame (modified) based on the number of time slots with respect to the time frames of FIGS. 1 to 3 and the DECT transmission time frame of FIG.

FIG. 9 shows a channel assignment table for channels having frequency multiplexing components, code multiplexing components, and time division multiplexing components based on the time division multiplexing frame of FIG.

FIG. 8 shows a (modified) TDD time-division multiplex frame with eight time slots ZS ′ 1... ZS ′ 8 starting from the time frames of FIGS. 1 to 3 and the DECT transmission time frame of FIG. Show. Here, the first four time slots ZS ′
'1 ... ZS'4 are provided for the downlink transmission direction DL, and second four time slots ZS'5 ... ZS'8 are provided for the uplink transmission direction UL. The number of time slots has been reduced to 8 for 16 in FIGS. 1 to 3, but this is for reasons of presentation to the channel assignment table of FIG. 9 and is not a limitation on the present invention. Rather, the number of time slots can be arbitrarily increased or decreased depending on the telecommunications system as well as other physical resources (eg, codes, frequencies, etc.).

FIG. 9 shows a channel assignment table for a channel having a frequency multiplexing component, a code multiplexing component, and a time division multiplexing component based on the time division multiplexing frame of FIG. The time-division multiplex component of this table includes the time slots ZS'1... ZS'8 divided by TDD in FIG. The frequency multiplexing component includes twelve frequencies FR1... FR12, and the code multiplexing component includes eight codes (pseudo-random signals) C1.

On the first frequency FR 1, a transmission route service configured as a “bearer service”, for example a logical channel of a telecommunications system, ie for example a control channel for signaling, an AGCH channel, a BCCH channel, a PCH channel, RACH channels, TCH channels, and / or FACCH channels are multiplexed at the code level formed by codes C1 ... C8. These channels are required in the telecommunications system in the downstream and / or upstream direction. This multiplexing is advantageously extended for the telecommunication system described above. This avoids unnecessary occupation of time slots, or resources "time".

FIG. 9 shows an advantageous embodiment, according to which, at a first frequency FR 1, in the downlink transmission direction a first (fixed) fixedly set (arranged) first time slot ZS ′ 1. , And in the upstream transmission direction as second fixed time slots fixed (arranged) in the fifth time slot ZS'5, preferably all codes C1... C8, respectively. Is used for multiplexing the transmission route service. Of course, if the number of codes is less,
If more than one code is available, more may be used.

In the multiplexing shown in FIG. 9, for example, codes C 1... C 8 are divided as follows at a first time slot ZS ′ 1. That is, one code is divided so as to be reserved for the control channel and the AGCH channel for signaling, another code is reserved for the BCCH channel and the PCH channel, and the remaining six codes are reserved for the TCH channel. On the other hand, the codes C1... C8 are divided as follows in the fifth time slot ZS'5. That is, the code is divided such that one code is reserved for the RACH channel, another code is reserved for the FACCH channel for handover indication, and the remaining six codes are reserved for the TCH channel.

[0047] The spectral efficiency and / or capability of the telecommunications system can be further improved as follows. That is, as shown in FIG. 9, for various connection scenarios, the first connection scenario VSZ1, the second connection scenario VSZ2, the third connection scenario VSZ3, the fourth connection scenario VSZ5, and the fifth connection scenario VSZ5. In addition, a plurality of bi-directional TDD telecommunications connections are respectively partially and unequally allocated in the downlink and uplink transmission directions for respective physical resources "code, frequency, time". To each connection scenario VSZ1... VSZ5 belong, for example, a first group G1 and a second group G2 of telecommunication connections. First
Groups are indicated by cross-hatching and the second group is indicated by hatching. Each group now includes at least one two-way telecommunications connection.

In the first connection scenario VSZ1, the first telecommunications connection group G1 has six codes in the second time slot ZS′2 in the downlink transmission direction at the second frequency FR2—the first code C1, 2 code C2, 3rd code C3, 4th code C4
, A fifth code C5 and a sixth code C6, and six more codes C1... C6 are allocated to the sixth time slit ZS'6 in the uplink transmission direction. On the other hand, the second telecommunications connection group G2 has the first code C1 assigned to the fourth time slot ZS'4 in the downlink transmission direction at the second frequency FR2, and the eighth time slot ZS 'in the uplink transmission direction. 8 is again assigned the first code C1.

The fourth time slot ZS′4 and the second time slot ZS′2 are “downlink” time slots ZS _DOWN , and the sixth time slot ZS′6 and the eighth time slot ZS′8 are "Uplink" time slot ZS _UP .

For each telecommunications connection group G 1, G 2, a “downlink” time slot ZS _DOWN And "uplink" time slot ZS_UPAnd the first interval AS1 is
According to the operation (see FIG. 7), it is half of the time division multiplex frame ZMR. Interval AS1
Is therefore a fractional part of the length of the time-division multiplex frame ZMR, the fractional part having the value 0.
5

In the second connection scenario VSZ2, the first telecommunications connection group G1 allocates six codes C1... C6 to the fourth time slot ZS′4 in the downlink transmission direction at the fourth frequency FR4. In the uplink transmission direction, six codes C1... C6 are also assigned to the seventh time slot ZS'7. On the other hand, at the fourth frequency FR4, the second telecommunications connection group G2 is assigned codes C1... C4 to the second time slot ZS'2 in the downlink transmission direction and the fifth time slot in the uplink transmission direction. The first code C1 and the second code C2 are assigned to the slot ZS'5.

The fourth time slot ZS′4 and the second time slot ZS′2 are “downlink” time slots ZS _DOWN and the seventh time slot ZS, similar to the first connection scenario VSZ1. '7 and the fifth time slot ZS'5 are "uplink" time slots ZS _UP .

For each telecommunications connection group G1, G2, a “downlink” time slot ZS _DOWN And “uplink time slot” ZS_UPAnd the second interval AS2 is time-division
This is a fractional part of the length of the multiplex frame ZMR. Where the fractional part is greater than 0.5
The second interval AS2 is fixed or small.

In the third connection scenario VSZ3, the first telecommunications connection group G1 has four codes C in the second time slot ZS′2 at the sixth frequency FR6 in the downlink transmission direction.
.. C4, and six codes C1... C6 and a seventh code C7 and an eighth code C8 are assigned to the eighth time slot ZS'8 at the fifth frequency FR5 in the uplink transmission direction. On the other hand, the second telecommunications connection group G2 has the code C1 in the third time slot ZS'3 at the sixth frequency FR6 in the downlink transmission direction.
.. C3 are assigned to the fifth time slot ZS′5 at the fifth frequency FR5 in the uplink transmission direction.

The second time slot ZS′2 and the third time slot ZS′3 are “downlink” time slots ZS _DOWN , and the eighth time slot ZS′8 and the fifth time slot ZS′5 are "Uplink" time slot ZS _UP .

For each telecommunications connection group G1, G2, a “downlink” time slot ZS _DOWN And "uplink" time slot ZS_UPIs the third interval AS3
This is a fractional part of the length of the multiplex frame ZMR. Here, each fractional part is the third
Are selected such that the interval AS3 is variable.

In the fourth connection scenario VSZ4, the first telecommunications connection group G1 assigns the first code C1 to the fourth time slot ZS′4 at the eighth frequency FR8 in the downlink transmission direction, and performs the uplink transmission. In the direction, the seventh code C1... C7 is assigned to the sixth time slot ZS'6 at the ninth frequency FR9, while the second telecommunications connection group G2 is assigned to the eighth frequency in the downlink transmission direction. In FR8, the third
The first code C1 is assigned to the time slot ZS′3 of the first time slot, and the first code C1 is assigned to the fifth time slot ZS′5 at the ninth frequency FR9 in the uplink transmission direction.
Is assigned.

The fourth time slot ZS′4 and the third time slot ZS′3 are “downlink” time slots ZS _DOWN , and the sixth time slot ZS′6 and the fifth time slot ZS′5 are "Uplink" time slot ZS _UP .

For each telecommunications connection group G1, G2, a “downlink” time slot ZS _DOWN And "uplink" time slot ZS_UPAnd the fourth interval AS4 is time-division
This is a fractional part of the length of the multiplex frame ZMR. Here, the fractional part is the fourth interval A
S4 is chosen to be fixed.

In the fifth connection scenario VSZ5, the first telecommunications connection group G1 has the eleventh frequency F
In R11, the first code C1 and the second code C2 are assigned to the fourth time slot ZS'4 in the downlink transmission direction, and the first code C1 is again assigned to the fifth time slot ZS'5 in the uplink transmission direction. And the second code C2. On the other hand, the second telecommunications connection group G2 is assigned the codes C1... C5 to the first time slot ZS'1 in the downlink transmission direction at the eleventh frequency FR11 and the eighth time slot ZS in the uplink transmission direction. Codes C1 ... C3 are assigned to '8.

The fourth time slot ZS′4 and the first time slot ZS′1 are “downlink” time slots ZS _DOWN , and the fifth time slot ZS′5 and the eighth time slot ZS′8 are "Uplink" time slot ZS _UP .

For each telecommunications connection group G1, G2, a “downlink” time slot ZS _DOWN And "uplink" time slot ZS_UPIs the fifth interval AS5
This is a fractional part of the length of the multiplex frame ZMR. Here, the fractional part is the second interval AS
2 is chosen to be variable.

[Brief description of the drawings]

FIG. 1 shows a three-level structure of a WCDMA / FDD radio interface on the downlink.

FIG. 2 shows a three-level structure of a WCDMA / FDD radio interface in the uplink.

FIG. 3 shows a three-level structure of a TDCDMA / TDD radio interface.

FIG. 4 shows a radio scenario in which channel multiplexing is used by frequency multiplexing / time division multiplexing / code multiplexing.

FIG. 5 shows the basic structure of a base station configured as a transmitting device / receiving device.

FIG. 6 shows the basic structure of a mobile station which is also configured as a transmitting / receiving device.

FIG. 7 shows a DECT transmission time frame.

FIG. 8 shows a TDD time-division multiplex frame (modified) based on the number of time slots with respect to the time frames of FIGS. 1 to 3 and the DECT transmission time frame of FIG.

FIG. 9 shows a channel assignment table for a channel including a frequency multiplexing component, a code multiplexing component, and a time division multiplexing component based on the time division multiplexing frame of FIG.

──────────────────────────────────────────────────続 き Continued on the front page F term (reference) 5K022 EE02 5K028 BB04 KK01 MM13 5K067 AA21 AA41 CC02 CC04 CC10 EE02 EE10

Claims (10)

[Claims] 1. A radio interface for a telecommunications system for performing radio telecommunications between mobile and / or stationary transmitting / receiving equipment based on code multiplexing and time division multiplexing, comprising: A predetermined carrier frequency (FR1... FR12) has a plurality of time slots (Z Z) each having a predetermined time slot duration (T _ZS ).
S'1 ... ZS'8), the telecommunications system is divided so that it can be driven in the TDD mode or the FDD mode. Here, the time slot for each carrier frequency (FR1 ... FR12) is set. (ZS'1 ... Z
S'8) form one time-division multiplexed frame (ZMR), respectively, and (b) in the time slot (ZS'1 ... ZS'8) or in the frequency domain of the telecommunications system, the uplink and downlink. A two-way telecommunications connection is established between the telecommunications subscribers of the mobile transceiver (MS1 ... MS5) and / or the stationary transceivers (BTS1, BTS2) of the telecommunications system at the same time, at most at the same time. Only a number can be formed, wherein the subscriber signal transmitted for separation is combined with a pseudo-random signal (C1... C8), which is individually assigned to the subscriber, ie a so-called code, ) The transmission route service, which is configured as a "bearer service" and is required in the downstream and / or upstream direction in the telecommunications system, is multiplexed at the code level formed by the codes (C1 ... C8) Wireless interface, wherein in that, it is. 2. At least some of the logical channels of the telecommunications system, eg control channels for signaling, AGCH channels, BCCH channels, PCH
CH channel, RACH channel, TCH channel, and / or FACCH
The wireless interface according to claim 1, wherein the channels are multiplexed at a code level as a transmission route service. 3. The method according to claim 1, wherein the first selected time slot (ZS′1) is in the downlink direction and
The wireless interface according to claim 1 or 2, wherein the selected time slots (ZS'5) are provided in the upstream direction, and multiplexing is performed in these. 4. The first selected time slot (ZS′1) is a time slot (ZS′1).
ZS'1 ... ZS'8) is the first time slot (ZS'1), and the second selected time slot (ZS'5) is the time slot (ZS'1 ... ZS'8). The wireless interface according to claim 3, which is the fifth time slot (ZS'5). Relative wherein each telecommunication connection in TDD mode, select the time slot pair, "downlink" timeslot (ZS _'DOWN), and "uplink" time slot (ZS' _UP) is as follows is the, i.e. the same carrier frequency (FR1 ... FR12) or different carrier frequencies (FR1 ... FR12) in allocated "downlink" timeslot (ZS _'dOWN) and an uplink time slot (ZS' _uP ) Is selected to be a fractional part of the length of a time division multiplexed frame (ZMR), said interval (AS2 ... AS5) being fixed or variable; The wireless interface according to claim 1. 6. A method for controlling a telecommunications connection in a telecommunications system that performs wireless telecommunications with mobile and / or stationary transceivers based on code multiplexing and time division multiplexing, comprising: (a) a telecommunications system; The carrier frequencies (FR1... FR12) set in advance are divided by a predetermined time slot time (T _ZS ) such that the telecommunication system is driven in the TDD mode or the FDD mode. And time slots (ZS'1 ... Z8) for each carrier frequency (FR1 ... FR12)
'8) form one time-division multiplexed frame (ZMR), respectively; (b) in the time slot (ZS'1 ... ZS'8) or frequency domain of the telecommunications system, in the uplink and downlink. At least a predetermined number of mobile communication devices (MS1 ... MS5) of the telecommunications system and / or at least a predetermined number of telecommunications subscribers of the stationary transceivers (BTS1, BTS2) at the same time. The subscriber signal transmitted for separation here is a pseudorandom signal (C1... C8) which is individually assigned to the subscriber, ie in a manner which is combined with a so-called code. , A transmission route service, which is configured as a "bearer service" and is required in the downstream and / or upstream direction in the telecommunications system, is formed by codes (C1 ... C8) Multiplexing at a level. 7. At least some of the logical channels of the telecommunications system, eg control channels for signaling, AGCH channels, BCCH channels, P
CH channel, RACH channel, TCH channel, and / or FACCH
7. The method of claim 6, wherein the channels are multiplexed at the code level as a transmission route service. 8. The multiplexing is performed in a first selection time slot (ZS ′) in the uplink direction.
7. The method according to claim 6, wherein in (1), the downlink is performed in the second selected time slot (ZS'5).
Or the method of 7. 9. A time slot (ZS′1) for a first selected time slot (ZS′1).
The first time slot (ZS'1) of ZS'1 ... ZS'8) is assigned, and the time slot (ZS'1 ... ZS'8) is assigned to the second selected time slot (ZS'5). Method according to claim 8, wherein a fifth time slot (ZS'5) is assigned. Against 10. Each telecommunication connection in TDD mode, select the time slot pair, "downlink" timeslot (ZS _'DOWN), and "uplink" time slot (ZS' to _UP) as follows Ie, "downlink" time slots (ZS ' _DOWN ) and uplink time slots (ZS' _UP ) assigned to the same carrier frequency (FR1 ... FR12) or different carrier frequencies (FR1 ... FR12). .. AS5 is selected to be a fractional part of the length of the time division multiplexed frame (ZMR), said interval (AS2... AS5) being fixed or variable. Item 10. The method according to any one of Items 6 to 9.