DE19733860A1 - Device for data transmission in mobile radio networks - Google Patents

Abstract

The invention relates to a data transmission device which is used in radio telephone networks for radio transmission in a TDAMA framework and/or a TDD/CDMA transmission procedure. The inventive device comprises control means, an HF part, signal filters, channel estimators, modulators, at least one means of switching controlled by the control means to enable switching between the transmission procedures, data estimators, and channel coders/decoders. According to the invention, at least one signal filter and/or one HF part is jointly used for both transmission procedures.

Description

The invention relates to a device for data transmission in cellular networks, especially base stations and mobiles stations in mobile radio networks with TDMA and / or TD / CDMA radio interface.

Messages (e.g. Spra che, image information or other data) with the help of electromagnetic waves over a radio interface between between transmitting and receiving radio station (base station or mobile station). The blasting of the electro magnetic waves occur at carrier frequencies that in the frequency band provided for the respective system lie. With GSM (Global System for Mobile Communication) are the carrier frequencies in the range of 900, 1800 or 1900 MHz. For future mobile radio networks with TDMA or TD / CDMA transmission method via the radio interface, for example UMTS (Universal Mobile Telecommunication System) or other 3rd generation systems are frequencies provided in the frequency band of approx. 2000 MHz.

The emitted electromagnetic waves are due to of losses through reflection, diffraction and radiation in dampened the curvature of the earth and the like. Consequently the reception power drops when receiving radio station is available. This damping depends on the location and also time-dependent for moving radio stations.

A radio communication system is known from DE 195 49 158, which is a CDMA subscriber separation (CDMA Code Division Multiple Access) uses, with the radio interface additional Lich a time division multiplex subscriber separation (TDMA Time Multiple Access Division). It therefore becomes a TD / CDMA transmission method for the radio interface  utilized. A JD process (JD Joint Detection) applied to knowledge of spreading codes several participants improved detection of the over carry carried data. It is known that one Connection via the radio interface at least two data channels can be allocated, with each data channel through an individual spreading code can be distinguished. The the radio communication system shown here is a candidate for a 3rd generation mobile phone system.

From P. Vary, "Implementation Aspects of the Pan-European digital mobile radio system ", IEEE 1989, pp. 4-17 to 4-22 the structure of a GSM radio station with HF part, filters, Ka channel estimators, modulators / demodulators, channel coders / channel decoders known. The GSM standard uses a comm combination of FDMA (Frequency Division Multiple Access) and TDMA for the radio interface and has worldwide acceptance found. Over 20 million participants will be in Europe alone operated via this standard. Extensive investments in the Infrastructure and in mobile stations have been done so far.

The transition from the 2nd generation of mobile communications (GSM) to the 3rd Mobile radio generation is in turn for the network operators require significant investments when network elements such as Mobile switching center, base station controller or base stations can be replaced or additionally installed have to. Also by the manufacturers of the infrastructure and the Mobile stations are significant development expenses necessary.

The invention has for its object a device to specify the data transmission in a mobile network, the a TD / CDMA transmission supports and economically is to be produced. This task is done by the facility solved with the features of claim 1. Beneficial Further developments can be found in the subclaims.  

According to the invention, the device for data transmission in mobile radio networks is used for radio transmission as part of a TDMA and / or as part of a TD / CDMA transmission method. The facility includes:

• Control means for controlling the device,
• - At least one RF part for processing high-frequency Transmit and receive signals,
• - signal filter for filtering the transmit and receive signals,
• - At least one channel estimator for evaluating the reception signals regarding their transmission channel,
• at least one modulator for modulating the transmission signals,
• - At least one switch controlled by the control means means for connecting a signal filter to each Channel estimator or with a modulator,
• - At least one data estimator evaluating received signals for detecting the transmitted data, and
• - Channel encoder / decoder for coding or decoding the Send or receive signals.

According to the invention, at least one signal filter and / or one HF part used for both transmission methods.

Such a device for data transmission, the Modula gates, channel estimators and data estimators for both transmissions providing methods (TDMA and TD / CDMA), but ge common components - signal filter and / or RF part ge uses together - increases the acceptance of new mobile communications wetting and reducing development expenses since so far used components can be taken over.

The implementation of CDMA algorithms is facilitated and the development effort for these data facilities transmission, which also includes the evaluation and generation of signals transmitted by a CDMA transmission method support is significantly reduced. With this, these Facilities can be manufactured more economically.  

According to an advantageous embodiment of the invention the device for data transmission contains a means for Power regulation, through which a regulation of the transmission power the transmission signals for both transmission methods becomes. It is also advantageous to include the device at least one block encoder / decoder for additional Co equip signaling information. Additional Lich, the control means can be such that a Evaluation of received signaling information and a Preparation of signaling information to be sent for both transmission procedures are carried out.

Signaling algorithms, signaling mechanisms, syn Chronization and algorithms for power regulation can be done from GSM cellular network can be taken over. Only when transferring procedures for the data via the radio interface Adjustments for a TD / CDMA transmission necessary.

According to a further advantageous embodiment of the invention the HF part consists of a receiving part and a transmission part. There is no need to redesign the HF part but only a modification that the wider range of Send and receive signals are taken into account.

The higher bandwidth is in the receiving section for a signal amplification, filtering and transfer to the base band and at the transmitting part for a signal amplification, a fil and a transmission in the high-frequency transmission band consider. The same applies to the signal filters that are made a digital transmission filter and a digital reception fil ter exist.

Since at least parts of the functions of the Sig nalfilter, the channel estimator, the modulators, the control means, the data estimator, the channel encoder / decoder and Block encoder / decoder reali by program components be realized, the realization of these components is in the Zu  interact with a digital signal processing device device that allows easy updating of the components enables.

The program components are advantageously structured in this way turiert that they by new transmitted from the cellular network Program components can be replaced at least partially or through new parameters to the other transfer can be switched. So that's a Software update by exchanging or supplementing the program components possible, so that for example a mobile station can adapt to the current network environment. It is for GSM mobile stations only an extension of the digital one Signal processing around the algorithms of a common Detection (joint detection) for the transmission layer perform. Higher layers (layer 2, ...) remain partially unaffected.

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

Show

Fig. 1 is a block diagram of a mobile radio network,

Transmission method FIG. 2 to FIG. 5, various combinations of mobile stations and base stations and their ability TDMA and TD / CDMA support,

Fig. 6 is a schematic representation of signaling to the exchange of program components,

Fig. 7 is a block diagram of the means for data transmission,

Fig. 8 is a block diagram of the RF part of the transmitter of the device,

Fig. 9 is a block diagram of the RF part of the receiver of the device,

Fig. 10 is a detailed block diagram of the transmitter of the device,

Fig. 11 is a detailed block diagram of the receiver of the device,

Fig. 12 is a block diagram of the signal processing means with program components.

The radio communication system shown in FIG. 1 corresponds in structure to a known GSM mobile radio network, which consists of a multiplicity of mobile switching centers MSC, which are networked with one another or provide access to a fixed network PSTN. Furthermore, these mobile switching centers MSC are each connected to at least one base station controller BSC. Each base station controller BSC in turn enables a connection to at least one base station BTS. Such a base station BTS is a radio station that can establish a radio link to mobile stations MS via a radio interface. A service control unit SCP in the sense of an intelligent network (IN) implements functions for software updates for the mobile radio network or for parts thereof.

When dividing the cellular network can be in facilities BTS, BSC are distinguished, the services according to the GSM standard dard, services according to a 3rd generation standard (UMTS) with TD / CDMA radio interface or both standards below support. The radio cells of the corresponding base stations BTS (GSM / UMTS), BTS (GSM), BTS (UMTS) can also do this overlay.  

According to the invention, the mobility of the mobile stations MS should not be hindered by the different standards available. A mobile station MS that only supports the GSM standard can continue to establish a radio connection to a base station BTS of the GSM standard ( FIG. 2). However, the mobile station MS can also be supplied by a base station BTS, which supports both standards (UMTS, GSM) ( FIG. 5).

A mobile station MS that supports both standards ( FIGS. 3 and 4) can communicate with a GSM base station BTS (GSM) as well as with a base station BTS that only allows TD / CDMA transmission or both transmission methods. Such a mobile station MS is a device for data transmission according to the invention. A base station BTS, which supports TD / CDMA or both transmission methods, is also an inventive device.

A mobile station MS or a base station BTS, which support TD / CDMA or GSM transmission, do not have to have all the program modules P1 to P9 required for this constantly stored. In Fig. 6 it is shown how loading program modules P1 'to P9' replaces or supplements the existing program modules in the sense of a software update or a parameter setting.

An exchange of messages between a mobile station MS and a service control unit SCP, which is also used as an operation and Maintenance center can start with a network-side information via an organizational channel. This Information signals the mobile station MS which Stan dards in the corresponding radio cell.

The subscriber gives the mobile station MS a call request (MOC) on or will establish a connection to the mobile station MS (MTC) and the mobile station does not yet have  the necessary program modules P1 'to P9' for processing of the signals according to the available standard, so this is reported to the service control unit SCP, which points to it down the program modules P1 'to P9' of the mobile station MS plays or a switch to the corresponding modules by performing a parameter update. It can be a broadcast service (broadcast) or an individual transmission become. The same applies to the base station BTS, which is not via the necessary program modules or parameters P1 'to P9' disposes. The BTS base station can also provide the necessary pro grammodule P1 'to P9' from the service control unit SCP load.

Have both the BTS base station and the Mobilsta tion MS via the necessary software, so the connection can being constructed. An alternative way to download software consists of the program modules P1 'to P9' in the Base station BTS to store and from there the requesting To provide mobile stations MS.

It is also possible to use a dialog between the Service control unit SCP and the mobile station MS one Select the standard that best possible (according to performance or Costs) the service profile desired by the participant corresponds. During the dialog for the selection of a standard are the subscriber from the service control unit SCP these are offered in the form of a menu or a table, if necessary supplemented by information on costs and the storage required capacity. The participant can then enter make the selection of the standard by means of the mobile station MS. The program modules P1 'belonging to the selected standard to P9 '(programs, data and / or parameters) are then from the service control device SCP to the mobile station MS transfer.

The structure of a device for data transmission is shown in Fig. 7, wherein a division into a digital part, which is realized by digital signal processing means DSP, and an RF part, which consists of a transmitting part HF-S and a receiving part HF-E, is made. The transmitting part HF-S and the receiving part HF-E are connected to a common antenna device A.

The transmission path of the digital signal processing consists of a convolutional encoder FC for channel coding of user data and signaling data previously stored in a block encoder BC were block coded. Then in an interleaver I scrambled the data and depending on the transmission standard Modulator GSM-MOD for GSM modulation or a modulator JD-MOD fed for TD / CDMA modulation. A first order switching means UM1, which like a second shown later Switching means UM2 is controlled by a control means SE, connects the selected modulator GSM-MOD or JD-MOD with a digital transmission filter SF and continue with the transmission part HF-S. A means LR for transmitting power control adjusts Specifications of the control means SE the transmission power for broadcasting dough nale tx.

In the reception path through the antenna device A received reception signals rx in the receiving section HF-E worked and fed to digital signal processing. A digital receive filter EF filters the broadband Received signals rx and are on the second switching means UM2 sends the signals to a channel estimator that is either a Channel estimator GSM-KS according to the GSM standard or a channel JD-KS is based on the TD / CDMA standard. According to the channel The signals are estimated to the respective data estimator GSM-D or JD-D supplied, which perform the data detection. The data of both paths are in a deinterleaver DI again descrambled together and then a fall tion decoder FD supplied for channel decoding. Signali Sation information is supplied to a block decoder BD leads, which decodes this data from the control means SE gives.  

The control means SE specifies the ones to be sent or the ones received White signaling data in the transmission or reception path ter and establishes the connection to a human-machine interface MMI (keyboard, screen) on a mobile station MS or to network-side signaling channels the base station BTS.

The transmitting part HF-S in FIG. 8 includes a digital / analog converter D / A for real and imaginary parts, first analog transmit filter FS1 for low pass filtering of the signals in the baseband, a first mixer MS1 tx for converting the transmission signals into the transmission frequency band, and a power amplifier PA for amplifying the transmission signals tx.

The receiver RF-E of FIG. 9 includes a first ana lied reception filter EF1, a receiving amplifier RPA rx for measuring and amplifying the received signals, a second mixing stage MS2 rx for converting the received signals tied to the base (it can also be used more mixing stages), second analog receive filter EF2 and finally an analog / digital converter A / D for real and imaginary parts, which generates digital receive signals rx which can be processed in the digital signal processing means DSP.

The receiving section HF-E and transmitting section HF-S are broadband, at for example, designed for a frequency band of B = 1.6 MHz.

Only the TD / CDMA mode is explained in more detail below.

The transmission path of the device is shown in detail in FIG. 10. It is shown in the usual form of description for the modeling and simulation of a communications technology system, in which the dependency between different functions and the system structure is shown.

In the submodule S2, the input data d _S1 ^(k) , k = 1. .K, which optionally consists of the uncoded data d _Q1 ^(k) , k = 1. .K, or from the data d _Q2 ^(k) , k = 1. . K, go out, subjected to channel coding with subsequent interleaving. The data from a first data source Q1 are transmitted via a user data channel TCH, the data from a second data source Q2 via a signaling channel SACCH or FACCH.

A 4-PSK modulation and a spreading of the data with the modulated subscriber-specific CDMA codes c ^(k) , k = 1. .K, takes place in sub-module S3. This is followed by the summation of all the spread data sequences in sub-module S4 and a subsequent integration of the midamble into the burst structure in sub-module S5. The spectral shaping of the transmission signal s follows in the sub-module S6; in the modules S7 to S9 the conversion of the time-discrete 4-times oversampled transmission signal in the baseband s _S6 into the time and value-continuous bandpass range of the transmission frequency band.

In Fig. 11, the receive path of the device is shown in detail. Takes place in the sub-module E1 of FIG. 11, the implemen tation of the reception signals RX from the transmission frequency band in the lowpass and the split into a real and an imaginary component. Analog subpass filtering takes place in submodule E2 and finally, in submodule E3, double oversampling of the received signal with 13/3 MHz and a word length of 12 bits.

A digital low-pass filtering is carried out in sub-module E4 a filter of the bandwidth 13/6 MHz with the highest possible Slope for channel separation. Then takes place in Sub-module E4 a 2: 1 decimation of the 2-times oversampled Signal.

The received signal e obtained in this way consists essentially of two parts, namely a part em for channel estimation and parts e1 and e2 for data estimation. In the sub-module E5, all channel impulse responses h ^{(k) are} estimated using a known midamble basic code m of all data channels transmitted in the respective time slot.

In sub-module E6, parameters b ^(k) for adapted filters for each data channel are determined using the CDMA codes c ^(k) . In the sub-module E7, the interference originating from the midambles m ^(k) is eliminated in the reception blocks e1 / 2 used for data estimation. This is possible by knowing h ^(k) and m ^(k) .

The cross-correlation matrix A ^{* T} A is calculated in sub-module E8. Since A ^{* T} A has a Töplitz structure, only a small part of the matrix is required here, which can then be used to expand the entire size. In the sub-module E9, a Cholesky decomposition from A ^{* T} A into H ^{* T} H takes place, where H is an upper triangular matrix. Due to the potty structure of A ^{* T} A, H also has approximately a potty structure and need not be fully calculated. A vector s represents the reciprocal of the diagonal elements of H, which can be used to advantage in solving equations.

Adapted filtering of the received symbol sequences e1 / 2 with b ^(k) takes place in sub-module E10. Submodule E11 implements the system solver 1 for H ^{* T} * z1 / 2 = e1 / 2, and submodule E12 the system solver 2 for H * d1 / 2 = z1 / 2. In the sub-module E13, the estimated data d1 / 2 are demodulated, descrambled and finally convolutionally decoded by means of a Viterbi decoder. The decoded data blocks d _E13 ^(k) are optionally fed to a first data sink D1 or via the source decoder E14 to a second data sink D2. Source decoding is necessary for data blocks that were transmitted via SACCH or FACCH signaling channels.

FIG. 12 shows the device for data transmission, the HF part HF-S and HF-E being pronounced according to FIG. 7 and the digital signal processing means DSP in addition to one or more digital signal processors - not shown - several program modules P1 to stored in a memory P9 contains. These program modules P1 to P9 represent the components of the digital signal filters P8, P9, the channel estimator P6, the modulators P4, the control means P1, the data estimator P6, the channel encoder / decoder P2, P3 and block encoder / decoder P2, P3. According to a software update, at least parts of the program modules P1 to P9, in particular the program modules P4 and P6 for modulation, channel and data estimation, can be supplemented by program modules P4 'and P6', which then also enable transmission with the respective different standard.

The device presented in the exemplary embodiments for Data transmission BTS, MS for a cellular network with one Combination of FDMA, TDMA and CDMA is for requirements 3rd generation systems suitable. It is particularly suitable is interested in an implementation in existing GSM mobile communications networks for which only a small amount of change is required. The design of dual-mode mobile stations MS, both according to the GSM standard, as well as the presented TD / CDMA Working standard is made easier.

Claims (13)

1. Device for data transmission in mobile radio networks, radio transmission being carried out as part of a TDMA and / or as part of a TD / CDMA transmission method,

• - with control means (SE) for controlling the facility,
• with at least one HF part (HF-E, HF-S) for processing high-frequency transmit and receive signals (tx, rx),
• - filter with signal (EF, SF) to filter the transmit and receive signals (tx, rx),
• with at least one channel estimator (JD-KS, GSM-KS) for evaluating the received signals (rx) with regard to their transmission channel,
• with at least one modulator (JD-MOD, GSM-MOD) for modulating the transmission signals (tx),
• - With at least one switching means (UM1, UM2) controlled by the control means (SE) for connecting a respective signal filter (EF, SF) with one of the channel estimators (JD-KS, GSM-KS) or with one of the modulators (JD- MOD, GSM-MOD),
• - With at least one data estimator (JD-D, GSM-D) evaluating the received signals (rx) for detecting the transmitted data, and
• with channel encoders / decoders (FC, FD) for coding or decoding the transmit or receive signals (tx, rx),

wherein at least one signal filter (EF, SF) and / or HF part (HF-E, HF-S) is used for both transmission methods. 2. Device according to claim 1, with a means (LR) for power regulation, through which one Regulation of the transmission power of the transmission signals (tx) for both Transfer procedure is carried out. 3. Device according to one of the preceding claims, with at least one block encoder / decoder (BC, BC) for additional coding of signaling information. 4. Device according to one of the preceding claims,  in which the control means (SE) are so pronounced that an evaluation of received signaling information and a preparation of signaling information to be sent he follows. 5. Device according to one of the preceding claims, whose HF part consists of a receiving part (HF-S) and a transmission part (HF-S) exists. 6. Device according to claim 5, the receiving part (HF-E) for the high-frequency reception signals (rx) a signal amplification, a filtering and a Carries out to baseband. 7. Device according to claim 5, whose transmission part (HF-S) for the transmission signals (tx) a signal amplification, filtering and a transfer to the high frequency band. 8. Device according to one of the preceding claims, whose signal filter (EF, SF) is a digital transmission filter (SF) and has a digital receive filter (EF). 9. Device according to one of the preceding claims, with a digital signal processing device (DSP) that at least part of the functions of the signal filter (EF, SF), the Channel estimators (JD-KS, GSM-KS), the modulators (JD-MOD, GSM-MOD), the control means (SE), the data estimator (JD-D, GSM-D), the channel encoder / decoder and block encoder / decoder (BC, BD) realized by program components (P1,.., P9). 10. Device according to claim 9, in which the program components (P1,.., P9) are structured in this way rated that they are transmitted from the mobile network new program components or parameters (P1 ',.., P9') at least at least partially can be replaced.   11. Device according to one of the preceding claims, in which the TDMA transmission method according to the GSM standard he follows. 12. Device according to one of the preceding claims, which is pronounced as a mobile station (MS). 13. Device according to one of claims 1 to 11, which is pronounced as a base station (BTS).