KR20010010625A - Digital signal processor and selector/transcoder thereof in radio network controller for international mobile telecommunications-2000 - Google Patents

Abstract

PURPOSE: A digital signal processor of an international mobile telecommunications-2000(IMT-2000) control station system is provided to process a Giga instructions per second(1GIPS) and to perform a multi-channel voice coder-decoder(CODEC) function, so as to process data even when one user occupies multi channels. CONSTITUTION: A multi-mode digital signal processor(DSP)(60) performs a DSP function relating to voice data with a multi-voice compressing mode. A buffer(40) buffers the voice data processed in the multi-mode DSP(60). A data transceiver(30) transceives voice data for being voice-compressed. The multi-mode DSP(60) comprises as follows. A first DSP(61) processes the voice data with a qualcomm code excited linear prediction(QCELP) voice compressing mode. A second DSP(62) processes the voice data with an enhanced variable rate vocoder(EVRC) voice compressing mode. A third DSP(63) processes the voice data with a conjugate-structure algebraic code excited linear prediction(CS-ACELP) voice compressing mode.

Description

Digital signal processing apparatus and selector / transcoder using the same in the global mobile communication control station system {international mobile telecommunications-2000}

The present invention relates to an IMT-2000 (International Mobile Telecommunications-2000) control station system, and more particularly, to AAM2 (ATM Adaptation Layer-2; ATM Adaptation Layer 2) received by the control station; Asynchronous Transmission Mode) Digital signal processing of the IMT-2000 control station system that enables vocoding of cell-type voice data regardless of vocoding type and performs multi-channel voice codec function. A device and a selector / transcoder using the same.

In general, IMT-2000 system is developed to provide users with free mobility around the world. Various services such as voice, non-voice and video are integrated into one terminal, and multimedia and intelligent for various media are provided. It is a system to provide a service, and to achieve thorough security of personal information as a user's own service through personalization of the service. In order to transmit all kinds of traffic, the sub-network of IMT-2000 system should be adopted as ATM (Asynchronous Transfer Mode) network.

When the ATM network is applied as a lower network of the IMT-2000 system, the advantages of the conventional PSTN / ISDN (Public Switching Telephone Network / Integrated Services Data Network) network are described as follows.

First, hardware handover due to conventional time-slot switching inevitably results in temporary loss of information, while ATM cell switching is a soft hand that does not lose any information at the time of handover. Soft handover is possible.

Second, using the advantages of ATM, a virtual connection tree that can shorten handover processing time and minimize information loss during handover by grouping regions with high probability of handover between adjacent cells into a cluster. Technical applications such as virtual connection tree are easy.

Third, since the efficient use of the bandwidth for the variable speed traffic in the ATM can be reduced the probability of blocking due to resource constraints during handover.

Fourth, it is possible to efficiently use a transmission path between a base station controller (BSC) and a mobile station controller (MSC) for a conventional voice service and a low speed data service.

Fifth, it has applicability to various kinds of traffic. That is, the change can be minimized when adding a new service in the conventional network.

Sixth, it has efficiency in accommodating broadband service. In order to guarantee service when providing a high speed and multimedia service target of up to 2Mbps in the pico / micro cell area of IMT-2000 with a conventional ISDN exchange, a hybrid interface must be provided. It does not guarantee multislot switching, and data-driven high-speed services are bursty, which is inefficient with hybrid technology in circuit-switching. In addition, ITU-T's current IMT-2000 standard is mobile call processing UNI (User-Network Interface) protocol based on Q.2931 of B-ISDN (Broadband ISDN). .

Seventh, since ATM has broadcasting capability, it is possible to easily realize paging function when incoming to mobile terminal.

In consideration of the various situations described above, it is preferable to use an ATM switch for securing the competitiveness of the IMT-2000 system for realizing mobile multimedia in the future and for future service evolution. However, in order for the ATM switching network to be a sub-network of the IMT-2000, the ATM switching system must have a quality of service (QoS) guarantee and a large capacity of mobile call processing.

Therefore, low-speed data information such as voice between an IMT-2000 system based on ATM (Asynchronous Transfer Mode) technology and an MSC (Pulse Code Modulation (PCM) data exchange function) In order to reduce packetization delay, ATM layering cell technology is used for user data transmission. Therefore, AAL (ATM Adaptation Layer) type 2 is applied to unify the processing of the lower layer for both signaling and traffic.

In the ATM network, all information is transmitted in units of cells. Therefore, the part related to cell transmission is not processed separately for a transmission medium or service such as voice, data, and video. However, the quality of service such as delay time and error rate required for each service is different, and it is necessary to absorb the difference in quality conditions for ATM cellization of the original information of each service. It is the ATM Adaptation Layer (AAL) that is responsible for this function.

AAL1 can only carry data of one subscriber in a cell. Therefore, if there is no traffic on the subscriber's channel, only the channel is allocated and other users cannot use this channel, which has channel inefficiency. Therefore, AAL2 is proposed to improve channel efficiency than AAL1. Since AAL2 contains data of multiple subscribers on the channel, if there is a trafficless subscriber, it can carry data of other subscribers, thus maximizing channel efficiency. However, AAL2 converts the AAL2 form into AAL2 'form because the data of multiple subscribers in one channel cannot handle the process of vocoding the ATM cell generated in this AAL2 form through the ATM switch. Here, AAL2 'type is an AAL that carries a function of carrying voice data of one subscriber to one ATM cell. Thus, each subscriber voice data can be vocoded separately.

As such, the IMT-2000 system for providing low-speed voice data while maximizing channel efficiency by using AAL2 type ATM cells is required to provide multimedia services. There are cases where requests for services of various qualities and methods occur. However, in the conventional cellular mobile communication control station system or personal communication service (PCS) control station system, voice data in the form of ATM cell cannot be processed in units of ATM cells. There is no multichannel voice codec capability. In addition, since the cellular mobile phone system does not provide the voice compression method applied in the PCS system, and the PCS system does not provide the voice compression method applied in the cellular mobile phone system, the control station of the cellular mobile phone system uses the voice applied in the control station. Only the terminal adopting the compression method can be accommodated, and the control station of the PCS system can also accept only the terminal adopting the voice compression method applied by the control station. Therefore, IMT-2000 system, which intends to accommodate both existing cellular mobile phone network and PCS network, provides voice compression method newly applied while basically providing voice compression method in cellular mobile phone system and PCS system. There is a need for a digital signal processor (DSP) and a selector / transcoder using the DSP.

Accordingly, the present invention has been proposed to provide a multi-mode voice data vocoding function and a multi-channel voice codec function required by the IMT-2000 service as described above.

An object of the present invention has a 1 Giga Instructions Per Second (GIPS) processing speed and implements a DSP (Digital Signal Processing Unit) that performs a multi-channel voice codec function, so that a user can handle even when occupying multiple channels. The present invention provides a digital signal processing apparatus (DSP) of an IMT-2000 control station system.

Another object of the present invention is to implement a multi-mode speech compression function by implementing multiple DSPs for processing speech data in different speech compression modes, thereby processing all speech data of different speech compression schemes regardless of the compression scheme. To provide a DSP for an IMT-2000 control station system.

Another object of the present invention is to implement a selector / transcoder by using a DSP that performs a multi-channel voice codec function and a multi-mode voice compression function, and an ATM cell bus structure and a cell bus dedicated chip, thereby providing all kinds of traffic. Selector using the DSP of the IMT-2000 control station system to enable high-speed processing of voice data in the form of ATM cells between an ATM switch of a control station that switches traffic through an ATM method and a mobile switching center (MSC). To provide a transcoder.

In order to achieve the above object, the digital signal processing apparatus (DSP) of the IMT-2000 control station system according to the present invention,

A multi-mode DSP for performing digital signal processing (DSP) on voice data in a multi-voice compression mode;

A buffer unit for buffering voice data to be processed in the multi-mode DSP;

The technical configuration is characterized by consisting of a data transmission and reception unit for transmitting and receiving voice data to be subjected to voice compression processing.

The multi-mode DSP may include: a first DSP performing a multi-channel voice codec function in a Qualcomm Code Excited Linear Prediction (QCELP) voice compression mode; A second DSP performing a multi-channel voice codec function in an enhanced variable rate voCoder (EVRC) voice compression mode; And a third DSP that performs a multi-channel voice codec function in a CS-ACELP (Conjugate-Structure Algebraic Code Excited Linear Prediction) voice compression mode.

In addition, the selector / transcoder using the DSP of the IMT-2000 control station system according to the present invention to achieve the above object,

Various resources for initializing various resources in the selector / transcoder (STBA), performing channel allocation functions, and for processing voice data in the form of AAL2 'ATM (Asynchronous Transfer Mode) cells in ATM units. A control unit controlling an operation;

Cell that transmits and receives ATM cell type voice data through cellbus switching and a matching device (STIA) that matches voice data in the form of AAL2 'ATM cell transmitted between a control station and an exchange station to the selector / transcoder (STBA). A cell routing unit;

A DSP unit which compresses voice data in the form of ATM cell received by the cell routing unit in a multiple voice compression scheme under the control of the controller;

An IPC unit configured to receive cell routing information through the STIA and an Inter Processor Communication (IPC) scheme and to provide it to the controller;

The technical configuration of the PCM matching unit for transmitting and receiving PCM (Pulse Code Modulation) voice data between the control unit and the DSP unit.

The DSP unit includes a DSP for processing the voice data switched in the cell routing unit using a voice compression method applied to a cellular mobile telephone system, and a voice compression method applied to the PCS system for the voice data switched in the cell routing unit. And a DSP for processing the voice data switched by the cell routing unit using a voice compression method applied to an IMT-2000 system, and performing a corresponding voice compression mode under the control of the controller. .

1 is a block diagram of an IMT-2000 control station system to which the present invention is applied;

2 is a system mounting diagram of the STIA and STBA of FIG.

3 is a connection diagram between STIA and STBA of FIG. 1;

4 is a block diagram of a selector / transcoder block according to the present invention;

5 is a block diagram of a digital signal processing apparatus according to the present invention;

<Explanation of symbols for main parts of drawing>

20: STBA 21: control unit

22: Cell routing part 23: DSP part

24: PCM matching part 25: IPC part

26: alarm and status monitoring unit 27: monitoring and LAN matching unit

Hereinafter, a digital signal processing apparatus of the present invention IMT-2000 control station system and a selector / transcoder using the same will be described in detail with reference to the accompanying drawings.

The IMT-2000 system, which will be commercialized in the future, adopts an ATM switch in a Radio Network Controller (RNC) because the ATM network is a backbone, and the present invention provides an ATM switch between an ATM switch and a switching center (MSC) of the control station. The purpose of the present invention is to allow voice data in the form of ATM to be vocoded.

Fig. 1 is a block diagram of a system for matching between an ATM switch and an exchange station in an IMT-2000 control station system to which the present invention is applied.

As shown, a switch multiplexing / demultiplexing assembly (SMDA) performs a matching function with an ATM switch 5 for switching an ATM cell in an ATM manner, thereby switching an ATM cell in an ATM switch. Demultiplexed to be transmitted to the MMDA (7) and STIA (10), and multiplexed by the ATM cells transmitted from the MMDA (7) and STIA (10) and transmitted to the ATM switch (5).

The MSC Multiplexing / Demultiplexing Assembly (MMDA) 7 is matched with the switching center 1 to multiplex the ATM cells transmitted from the SMDA 6 and the STIA 10 so that the switching center 1 And demultiplex the ATM cells transmitted from the switching center 1 to the SMDA 6 and the STIA 10.

The STIA (Selector & Transcoder Interface Assembly) 10 receives ATM data from the SMDA 30 and the MMDA 40 through a cell bus and separates the signals in 25Mbps units. To match the STBA 20.

The operation of the control station system to which the present invention is applied will be described below.

When voice data in the form of AAL2 ATM cell for voice service and data and control signals in the form of AAL5 ATM cell for data service are transmitted from the base station to the control station, the AAL2 ATM cell is AAL2 'type ATM for ATM switching and vocoding. After being converted to a cell, it is sent to the ATM switch 5.

In this way, when the ATM cells in the ATM switch 5 are switched to the ATM scheme and transmitted to the SMDA 6 at 155 Mbps, the SMDA 6 separates the AAL5 ATM cells from the AAL2 'ATM cells and performs cell bus switching. Therefore, the AAL5 type ATM cell is transmitted to the MMDA 7, and the AAL2 'ATM cell type voice data is transmitted to the STIA 10 for vocoding processing.

The STIA 10 transmits the AAL2 'type voice data to the STBA 20 in 25 Mbps units. Then, the STBA 20 according to the present invention processes the speech compression method and transmits the STBA 10 to the STIA 10 again. The STIA 10 then transmits the AAL2 'ATM voice data received from the STBA 20 to the MMDA 7.

In this way, the AAL5 ATM cells transmitted from the SMDA 6 through cell bus switching are multiplexed and transmitted to the switching center 1. In addition, the AAL2 'type ATM cell received from the STIA 10 is multiplexed and transmitted to the MSC 1.

In addition, the operation in which the ATM cell transmitted from the MSC 1 to the control station at 155 Mbps is transmitted to the ATM switch 5 of the control station is an inverse process of the process of transmitting the ATM cell from the ATM switch 5 to the MSC 1. This is done by doing

Now, the STBA (Selector & Transcoder Board Assembly (Selector / Transcoder)) 20 according to the present invention will be described. FIG. 3 is a diagram illustrating the connection between the STBA and the STIA according to the present invention. As shown, eight STBAs 20 are connected per STIA 10 that separates AAL2 'type voice data into 25 Mbps units.

4 is a block diagram of an STBA according to the present invention.

As shown, each of the eight STBAs 20a-20h includes: a controller 21 for initializing various resources in the STBA 20 and performing a channel allocation function; A cell routing unit 22 performing a cell bus switching function under the control of the control unit 21 for transmitting and receiving ATM cell voice data with the STIA 10; A digital signal processing (DSP) unit 23 for compressing the voice data switched by the cell routing unit 22 in a multiple voice compression scheme; An IPC unit 25 which receives cell routing information from the STIA 10 and provides the controller 21 to the controller 21 in an inter processor communication (IPC) manner between the controller 21 and the STIA 10; ; A PCM matching unit 24 for matching between the control unit 21 and the PCM bus; An alarm and status monitoring unit 26 for monitoring a mounting state of the STBA 20, recognizing a mounted slot, and monitoring an abnormality state of the STBA 20; It consists of a monitoring and LAN matching unit 27 for maintenance function and LAN interface function via RS-232C.

Before describing the operation of the STBA 20 according to the present invention configured as described above, the DSP according to the present invention will be described.

Fig. 5 is a block diagram of a digital signal processing apparatus of the IMT-2000 control station system according to the present invention.

As shown, a multi-mode DSP 60 performing digital signal processing (DSP) on voice data in a multi-voice compression mode; A buffer unit 40 for buffering voice data to be processed in the multi-mode DSP 60; It is composed of a data transceiver 30 for transmitting and receiving voice data to be compressed.

The multi-mode DSP 60 includes: a first DSP 61 for processing voice data in a Qualcomm Code Excited Linear Prediction (QCELP) voice compression mode; A second DSP 62 for processing the voice data in an enhanced variable rate voCoder (EVRC) voice compression mode; The third DSP 63 is configured to process voice data in a Conjugate-Structure Algebraic Code Excited Linear Prediction (CS-ACELP) voice compression mode.

The buffer unit 40 includes: buffers 41-43 for reading and buffering voice data to be processed by the DSP from the data transmission / reception unit 30; ROMs 44-46 for storing execution programs and booting programs of DSPs; A buffer (47-49) for temporarily buffering a program read from each of the ROMs (44-46); When the capacity of the buffers 47-49 is insufficient, the SDRAMs 50-52 for code storage and driving correspond one-to-one with the first to third DSPs 51-53, respectively.

The operation of the DSP unit according to the present invention configured as described above is as follows.

When the voice data received by the STBA 20 is to be processed in the QCELP mode, the control unit 21 of the STBA 20 transfers the received voice data to the data transmitting / receiving unit 30 of the DSP unit through a connector 28. At the same time as the transmission, a control signal is output so that this audio data is transmitted to the first DSP 51. The connector 28 performs a matching function between the control unit 21 and the DSP unit 23 of the STBA 20.

Accordingly, the first DSP 61 reads the voice data from the data transmission / reception unit (DPRAM) 31 and processes it in the QCELP mode.

In this way, the DSP unit 23 receives voice data for voice compression processing under the control of the control unit 21 in the STBA 20 and processes the voice data in the corresponding voice compression mode among the three voice compression modes. Thus, the multi-DSP unit 23 includes three DSPs such as a DSP performing a QCELP function, a DSP performing an EVRC function, and a DSP performing a CS-ACELP function so as to perform these three voice compression functions. All three voice compression functions can be performed.

Therefore, the DSP unit can accept and process all voice data of QCELP, EVRC, and CS-ACELP. Therefore, it is possible to accommodate all the QCELP type terminal, EVRC type terminal, CS-ACELP type terminal. That is, it can accommodate a cellular mobile phone terminal, a PCS terminal, and an IMT-2000 terminal.

In addition, each DSP is implemented by TMS320C6201, which has processing capacity of about 8 channels / chip or more, and can process voice data of 30 channels / mode. This allows one user to occupy and use multiple channels.

Next, the operation of the STBA according to the present invention having the DSP unit having the three voice compression modes as described above is as follows.

When the voice data in the form of ATM cells switched in the ATM switch 5 is demultiplexed in the SMDA 6 and transmitted to the STIA 10, the STIA 10 separates the ATM cell voice data in units of 25 Mbps and uses 8 STBAs. The corresponding STBA 20 is transmitted.

The STBA 20 performs a voice compression and routing function based on the voice compression mode and routing information received through the IPC communication with the CPU of the STIA 10. Thus, the STBA 20 separates the received AAL2 'ATM cell type voice data into 48 byte units so that the DSP unit 23 can process the voice data. That is, it determines which compression mode of the three voice compression modes is to be processed. When the compression mode is determined, the voice data can be processed in this compression mode.

Thus, when the voice data is decoded in the voice compression mode under the control of the control unit 21 in the DSP unit 23, the STBA 20 bundles the decoded voice data by 48 bytes again and puts them on the ATM cell bus. To send). The STIA 10 then transmits the decoded ATM cell form voice data to the MSC 1 via the MMDA 7.

In addition, the operation of transmitting voice data in the form of ATM cell from the MSC 1 to the corresponding base station via the ATM switch 5 of the control station is performed by the above-described ATM switch 5 from the ATM switch 5 to the MSC 1 in the form of voice of the ATM cell. It is performed through the reverse of the operation of transmitting data.

Referring to each device inside the STBA 20, the control unit 21 is equipped with a real time operating system (OS), initializes various resources in the STBA 20, and collects state information And to collect statistics, configuration management, faults and alerts, and if possible report various faults to the STIA 10, implemented in MPC 860.

The cell routing unit 22 performs voice data switching through the STIA 10 and the ATM cell. The cell routing unit 22 is controlled by the control unit 21 through an 8-bit address bus and an 8-bit data bus. Address translation and routing header information is exchanged through SRAM. The size of the external translation RAM depends on the system's ATM cell bus processing capacity.

The IPC unit 25 receives cell routing information from the STIA 10 and provides it to the controller 21 in an inter processor communication (IPC) manner between the control unit 21 of the STBA and the STIA 10. . The IPC unit 25 is implemented in a structure such as HDLC, ethernet, bus, etc., which is determined according to the transmission amount and characteristics of the IPC information. The HDLC structure uses RS485 and is implemented using a serial communication controller (SCC) inside the MPC860. In addition, the bus structure can perform real time communication through a mailbox using a dual port memory method.

The alarm and status monitoring unit 26 performs the mounting status monitoring of the STBA 20, the slot recognition mounted and the abnormality monitoring of the STBA 20, and the alarm information and the slot position information are provided in the parallel port of the MPC860 ( It is recognized as a system through the parallel port and implemented according to the backplane and the interface of the STIA board. Status information is implemented using an external register so that the MPC860 can read the board's status at any time by writing it to an external register and handle interrupts when an interrupt occurs.

The monitoring and LAN matching unit 27 is used for maintenance and follows the RS-232C standard using a serial management controller (SMC) inside the MPC860. The speed can support up to 38400bps. An Ethernet port is required for program upgrade and development, and follows the 10baseT (TP) standard using a serial communication controller (SCC) inside the MPC860.

The STBA 20 performs a time synchronization function, a code division multiple access (CDMA) type radio access standard layer 2 processing function, an ATM layer AAL2 protocol processing function, and performs an AAL2 'ATM cell. It allows speech data to be speech compressed in a multi-mode manner and to code and decode multichannel speech.

These STBAs support forward and reverse call channel management (Traffic Frame Processing, Frame Check Sequence (FCS) Control Frame Processing, Traffic Channel Element (TCE) Control Frame Processing) and call setup, call transfer, message type switching, and handoff ( call processing functions such as hand off) and power control.

Thus, the control station converts PCM voice data received in the form of ATM cell into QCELP, EVRC, CS-ACELP data and processes voice data in units of ATM cells.

As described above, the DSP of the IMT-2000 control station system according to the present invention has a 1 Giga Instructions Per Second (GIPS) processing speed and performs a multi-channel voice codec (DSP) function. ) Can be implemented in multiple ways, so that a single user can handle multiple channels. In addition, the DSP implements voice processing in 13K QCELP mode, DSP processing voice data in EVRC mode, and DSP processing voice data in CS-ACELP mode. All can be processed irrespective of this, and both cellular and PCS terminals can be accommodated.

In addition, the selector / transcoder using the DSP according to the present invention implements a multi-channel voice codec function, uses a DSP unit to perform a multi-voice compression mode, and uses an ATM cell bus structure and a cell bus chip. Voice data in the form of an ATM cell can be processed at a high speed between an ATM switch of a control station that switches all kinds of traffic in an ATM manner and a mobile switching center (MSC).

Claims (9)

In the digital signal processor for performing a voice compression processing function, A multi-mode DSP for performing digital signal processing (DSP) on voice data in a multi-voice compression mode; A buffer unit for buffering voice data to be processed in the multi-mode DSP; A digital signal processing apparatus (DSP) of an IMT-2000 control station system, characterized by comprising a data transmitting and receiving unit for transmitting and receiving voice data to be compressed. The method of claim 1, wherein the multi-mode DSP, A first DSP that performs a multi-channel speech codec function in a Qualcomm Code Excited Linear Prediction (QCELP) speech compression mode; A second DSP performing a multi-channel voice codec function in an enhanced variable rate voCoder (EVRC) voice compression mode; A digital signal device (DSP) of an IMT-2000 control station system, comprising a third DSP that performs a multi-channel voice codec function in a CS-ACELP (Conjugate-Structure Algebraic Code Excited Linear Prediction) voice compression mode. The method of claim 2, wherein the first to third DSP, A digital signal device (DSP) of an IMT-2000 control station system having a 1 Giga Instructions Per Second (GIPS) processing speed and a processing capacity of 8 channels / chip or more. The method of claim 1, wherein the buffer unit, A buffer which reads and buffers voice data to be processed by the DSP from the data transceiver; A ROM for storing an execution program and a booting program of the DSP; A buffer for temporarily buffering the program read from the ROM; SDRAM for storing and driving code when the capacity of each buffer is insufficient, Digital signal processing apparatus (DSP) of the IMT-2000 control station system, characterized in that one-to-one correspond to each of the DSP. In a selector / transcoder that performs selection and voice compression processing on voice data transmitted between a control station and a switching center (MSC), Various resources for initializing various resources in the selector / transcoder (STBA), performing channel allocation functions, and for processing voice data in the form of AAL2 'ATM (Asynchronous Transfer Mode) cells in ATM units. A control unit controlling an operation; Cell that transmits and receives ATM cell type voice data through cellbus switching and a matching device (STIA) that matches voice data in the form of AAL2 'ATM cell transmitted between a control station and an exchange station to the selector / transcoder (STBA). A cell routing unit; A DSP unit which compresses voice data in the form of ATM cell received by the cell routing unit in a multiple voice compression scheme under the control of the controller; An IPC unit configured to receive cell routing information through the STIA and an Inter Processor Communication (IPC) scheme and to provide it to the controller; Selector / transcoder using a digital signal processing device (DSP) of the IMT-2000 control station system, characterized in that the PCM matching unit for transmitting and receiving PCM (Pulse Code Modulation) voice data between the control unit and the DSP unit (selector / transcoder). The method of claim 5, An alarm and status monitoring unit configured to monitor the mounting state of the STBA, recognize the mounted slot, and monitor whether the STBA is abnormal; A selector / transcoder using a digital signal processing device (DSP) of an IMT-2000 control station system further comprising a monitoring and LAN matching unit for maintenance function and LAN interface function through RS-232C. (selector / transcoder). The method of claim 5, wherein the DSP unit, A DSP for processing the voice data switched in the cell routing unit using a voice compression method applied to a cellular mobile telephone system, a DSP for processing the voice data switched in the cell routing unit using a voice compression method applied to a PCS system; And a DSP for processing the voice data switched by the cell routing unit using a voice compression method applied to an IMT-2000 system, and performing a corresponding voice compression mode under the control of the controller. Selector / transcoder using digital signal processing device (DSP) of station system. The method of claim 5 or 7, wherein the DSP unit, Quality Code Excited Linear Prediction (QCELP) mode, Enhanced Variable Rate voCoder (EVRC) mode, and CS-ACELP (Speech Code) mode for coding and decoding voice data while maintaining a good quality of voice service. A selector / transcoder using a digital signal processing device (DSP) of an IMT-2000 control station system, characterized in that it operates in Conjugate-Structure Algebraic Code Excited Linear Prediction mode. The method of claim 5, wherein the AAL2 'form, In order to improve channel efficiency, AAL2 type ATM cells generated by multiplexing voice data of multiple users in one ATM cell are loaded with one user's data in one ATM cell so that ATM switching and vocoding can be performed. A selector / transcoder using a digital signal processing apparatus (DSP) of an IMT-2000 control station system, characterized in that the form is given when it is given.