Patent Abstract:
The present invention discloses an access device for supporting a variable data layer including: a user access processing module unit for receiving and processing an input command of a user, providing externally-received voice data to the user, and processing access to a local area network; a central control processing module unit for processing the voice data processed in or inputted to the user access processing module unit, and controlling processing units of the respective modules; and a wide area network access processing module unit for receiving data from the central control processing module unit, and performing a matching operation for a physical layer access. As a result, the access device supports the variable data layer, minimizes hardware variations due to variations of a physical layer access medium, and utilizes system hardware according to environmental variations of the physical access unit.

Full Description:
CROSS REFERENCE TO RELATED ART 
     This application claims the benefit of Korean Patent Application No. 2000-79754, filed on Dec. 21, 2000, which is hereby incorporated by reference in its entirety. 
     BACKGROUND OF THE INVENTION 
     1. Field of the Invention 
     The present invention relates to an access device for supporting a variable data layer, and in particular, to an improved access device for supporting a variable data layer which can minimize variations of system hardware constitution due to access variations of a physical layer unit. 
     2. Discussion of the Related Art 
       FIG. 1  is a block diagram illustrating a conventional access device for supporting 10 Base-T access of a physical layer. Referring to  FIG. 1 , the access device for supporting the 10 Base-T access includes a user access processing module unit  12  having an analog access processing unit  10  and a digital access processing unit  11 ; a central control processing module unit  16  having a time division multiplexing (TDM) switching unit  13 , a voice processing unit  14  and a processor module unit  15 ; and a local area network (LAN) access processing module unit  18  having a LAN access processing unit  17 . In the conventional access device, when the user inputs a command, the user access processing module unit  12  processes the command of the user and transmits the processing result to the central control processing module unit  16 . The central control processing module unit  16  converts the command of the user into data usable in an external layer. The LAN access processing module unit  18  externally transmits the converted data from the central control processing module unit  16 . 
     The operation of the conventional access device will now be explained. When the user inputs a specific command, if the inputted command is an analog data, such as a telephone or fax, the user access processing module unit  12  enables the analog access processing unit  10  to process the data. If a private exchange externally transmitting/receiving a digital data is engaged, the user access processing module unit  12  enables the digital access processing unit  11  to process the data. The data processed in the analog access processing unit  10  is transmitted to the TDM switching unit  13  through TDM bus A. The data processed in the digital access processing unit  11  is transmitted to the TDM switching unit  13  through TDM bus B. 
     The TDM switching unit  13  performs a switching operation between TDM buses A and B, and transmits the processed data to the voice processing unit  14  through TDM bus C. The voice processing unit  14  compresses the received voice data according to a compression method provided by a CPU  24  of the processor module unit  15 , and transmits the compressed voice data to the CPU  24  of the processor module unit  15  through a host processor interface (HPI). The HPI bus acts as address/data buses for transmitting/receiving data to/from a processor of the processor module unit  15  and an auxiliary processor of the voice processing unit  14 , and related control signals. 
     In order to transmit the compressed voice data to a corresponding system through the LAN access processing unit  17 , the CPU  24  of the processor module unit  15  converts voice compression information and destination information into internet protocol (IP) frames, and transmits the frames to the LAN access processing unit  17 . The LAN access processing unit  17  transmits the IP packet from the processor module unit  15  to an external IP network, such as the Internet. 
     When the packet is received from the external IP network, the LAN access processing unit  17  receives the IP packet and transmits it to the CPU  24  of the processor module unit  15 . The processor module unit  15  extracts the IP frame from the IP packet, and extracts compressed voice data, voice compression information and destination information from the extracted IP frame. Then, the processor module unit  15  transmits the compressed voice data to the voice processing unit  14  through the HPI bus, transmits control information for restoring the voice compression data according to the extracted voice compression information, and transmits path control information of the TDM switching unit  13  according to the destination address. 
     The voice processing unit  14  restores the received voice data according to a restoring method provided by the CPU  24 , and transmits the restored data to the TDM switching unit  13  through TDM bus C. The TDM switching unit  13  transmits the restored voice data from the voice processing unit  14  to the analog/digital access processing unit  10  or  11  of the user access processing module unit  12  through TDM bus A or B, maintaining the switching path transmitted from the CPU  24 . 
     The aforementioned process will now be described in short in view of software processing. The access device receives a reset signal from a peripheral interface logic in the processor module unit  15  after receiving power, determines an operation state of the CPU, forms an initial setup for the operation of the CPU from a boot ROM memory, and downloads a program programmed by software operation from an application RAM region. The respective access processing units  10  or  11  of the user access processing module unit are initialized for operation. In addition, a switching path is set up for the TDM switching unit  13 . A voice processing method selected with the corresponding system through the LAN access processing unit is designated in the voice processing unit  14 , so that the voice processing unit  14  can compress the voice data received through the TDM buses and restore the compressed voice data received through the HPI bus. 
     As described above, the processor module unit  15  sets up the basic environment where the system can be operated as the access device. After the initial setup process, the CPU of the processor module unit  15  periodically tests and processes the respective processing units, transmits the voice compression data received through the HPI interface to the LAN access unit in the form of an IP packet, decomposes the IP packet received through the LAN access unit to extract the compression voice data, and transmits the extracted data to the voice processing unit through the HPI bus. The voice processing unit restores the compressed voice data. 
     The general access device supports a specific data layer of a specific physical layer. In order to support access of another or a different physical layer, the access device requires a special external system. For example, the access device for supporting the 10 Base-T which is a transmission path standard of the LAN where the physical layer is standardized as IEEE 802.3 cannot directly access an x-type digital subscriber line (xDSL) network. 
       FIG. 2  shows a structure for accessing the xDSL network by using the conventional access device for supporting the 10 Base-T. As illustrated in  FIG. 2 , the conventional access device for supporting the 10 Base-T cannot access the xDSL network. In order to access the xDSL network, the access device should use an xDSL modem, or remove the 10-Base T, receive a service function of an access device and use the access device accessing the xDSL. 
     As described above, the conventional access device accesses in an IP environment and supports a specific physical layer access unit. However, according to technical developments of the xDSL, the conventional access device requires a special external system or a new system to access the xDSL network. In addition, applicability of the hardware is reduced. 
     SUMMARY OF THE INVENTION 
     Accordingly, an object of the present invention is to provide an access device for supporting a variable data layer by using a wide area network access processing module unit. 
     Additional features and advantages of the invention will be set forth in the description which follows, and in part will be apparent from the description, or may be learned by practice of the invention. The objectives and other advantages of the invention will be realized and attained by the structure particularly pointed out in the written description and claims hereof as well as the appended drawings. 
     In order to achieve the above-described object of the present invention, there is provided an access device for supporting a variable data layer including: a user access processing module unit having analog/digital access processing units for providing input/output services to the user, and having a local area network access processing unit; a central control processing module unit having a time division multiplexing switching unit for transmitting the voice data from the user access processing module unit to the voice processing unit, or the data from the voice processing unit to the user access processing module unit, and the voice processing unit for compressing the voice data from the time division multiplexing switching unit according to a method defined in a processor module unit, and compressing/restoring the data from the processor module unit according to a defined restoring method, and the processor module unit for controlling processing units of the module units; and a wide area network access processing module unit having a frame conversion processing unit for converting the data from the central control processing module unit to a frame which can support a physical layer access, or a data type which can be processed in the processor module unit of the central control processing module unit, and a physical access unit for performing a physical medium access. 
     In one aspect of the present invention, the user access processing module unit includes: an analog access processing unit for satisfying the user&#39;s demand for processing an analog data such as a telephone and fax; a digital access processing unit for satisfying the user&#39;s demand using a private exchange for processing a digital data; and a local area network access processing unit for externally transmitting or receiving 10 Base-T physical layer data. 
     In another aspect of the present invention, the central control processing module unit includes: a time division multiplexing switching unit for switching TDM buses, the data inputted by the user and processed in the user access processing module unit being transmitted through the TDM buses; a voice processing unit for compressing an externally-transmitted voice signal and restoring an externally-received voice signal according to a method defined in a CPU of a processor module unit; and the processor module unit having the CPU for initializing sub processing units of the processing module units, monitoring the status thereof, converting 10 Base-T physical layer data into an IP frame in transmission, extracting a voice data from the IP frame in reception, converting xDSL physical layer data into a frame supportable in a wide area network in transmission, and removing an overhead data from the received data in reception, a peripheral I/F logic for performing interface of the CPU, CPU related memory units, and a PLD/PGA logic for performing interface with the wide area network access processing module unit through UTOPIA bus. 
     In still another aspect of the present invention, the wide area network access processing module unit includes: a frame conversion processing unit having a framer unit for converting the data received from the central control processing module unit to an xDSL physical layer through UTOPIA bus into a frame usable in the physical layer, an encoding unit for converting the frame into a signal usable in the physical layer, a decoding unit for converting the signal from a physical access unit into a signal usable in the system, and a deframer unit for converting the data from the decoding unit into a frame type through UTOPIA bus to be processed in the processor module unit of the central control processing module unit; and the physical access unit for supporting a physical access medium. 
     It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory and are intended to provide a further explanation of the invention as claimed. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
       The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and, together with the description, serve to explain the principles of the invention. 
         FIG. 1  is a block diagram illustrating a conventional access device for supporting 10 Base-T access of a physical layer; 
         FIG. 2  shows a schematic structure for accessing xDSL network by using the conventional access device for supporting the 10 Base-T; and 
         FIG. 3  is a block diagram illustrating an access device for supporting a variable data layer in accordance with a preferred embodiment of the present invention. 
     
    
    
     DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS 
     A preferred embodiment of the present invention will now be described with reference to the accompanying drawings. In the following description, reference is made to the accompanying drawings which form a part hereof and which illustrate the preferred embodiment of the present invention. It is understood that other embodiments may be utilized and structural and operational changes may be made without departing from the scope of the present invention. 
       FIG. 3  is a structure diagram illustrating the access device for supporting the variable data layer in accordance with the preferred embodiment of the present invention. Referring to  FIG. 3 , the access device  100  includes a user access processing module unit  33 , a central control processing module unit  40  and a WAN (Wide Area Network) access processing module unit  41 . 
     According to the preferred embodiment, the user access processing module unit  33  includes an analog access processing unit  30  (preferably an A/D converter or codec), a digital access processing unit  31  and a LAN access processing unit  32 . The central control processing module unit  40  includes a TDM switching unit  34 , a voice processing unit  36  and a processor module unit  37 . The WAN access processing module unit  41  includes a frame conversion processing unit  38  and a physical access unit  39 , such as DB 25, RJ-48 connectors, etc. 
     The analog access processing unit  30  of the user access processing module unit  33  processes data from an analog system, such as telephone and fax. The digital access processing unit  31  processes data from a digital system, such as a digital private exchange or other suitable system known to one of ordinary skill in the art, through T1 or E1 line. 
     The TDM switching unit  34  of the central control processing unit  40  performs a switching operation between the TDM buses under the control of a CPU  54  of the processor module unit  37 . The voice processing unit  36  compresses the externally-transmitted voice data and restores the externally-received compressed voice data according to a compression/restoring method defined between the CPU  54  of the processor module unit  37  and the corresponding system. For example, the voice processing unit  36  compresses the 64 kbps data to either the 5.6 kbps or the 6.3 kpbs data preferably using the G.723.1 standard protocol or other suitable algorithm known to one of ordinary skill in the art. 
     The CPU  54  of the processor module unit  37  forms the compressed voice data received through the HPI bus in the form of an IP packet according to compression algorithm residing in the memory region. In addition, the processor module unit  37  extracts the compressed voice data from the IP packet received through the LAN access processing unit, disassembles the IP packet into ATM (Asynchronous Transfer Mode) cells according to variations of the program, or extracts the IP packet by combining the ATM cells. When the processor module unit  37  includes a PLD/PGA logic  55  for interfacing between the HPI bus and the UTOPIA bus (which is described below), the frame conversion processing unit  38  of the WAN access processing module unit  41  transmits or receives the ATM cells. In addition, the CPU  54  controls the status of sub processing units of the module units. A peripheral I/F logic  53  of the processor module unit  37  defines the initial operation of the CPU, or notifies the operation state of the system to the user according to the management of the CPU in each module unit. 
     ATM is a network protocol that has grown out of the need for a worldwide standard to allow interoperability of information, regardless of the end-system or type of information. ATM is a method of communication which can be used as the basis for both LAN and WAN interconnect. When information needs to be communicated, the sender requests a path through the network for a connection to the destination. When setting up this connection, the sender specifies the speed, type and other features of the call. 
     UTOPIA (Universal Test and Operations Physical Interface for ATM) is a standard for data transmission/reception between the physical layer and higher layer. UTOPIA is a high speed point-to-point parallel bus. UTOPIA is used in ATM applications. The UTOPIA bus is a standard defined by the ATM forum for moving data between the physical and ATM layers in the ATM protocol stack. The physical layer interfaces directly to the network media (i.e., twisted pair, optical fiber, etc.) and also handles transmission convergence (e.g., extracting the ATM cells from the transport coding scheme). The ATM layer processes the cell headers and directs routing. 
     The WAN access processing module unit  41  includes a frame conversion processing unit  38  having a framer unit  42  for converting the data received from the central control processing module unit  40  to an xDSL physical layer through the UTOPIA bus into a frame usable in the physical layer, an encoding unit  43  for converting the frame into a signal usable in the physical layer, a decoding unit  45  for converting the signal received from a physical access unit  39  into a signal usable in the access device  100 , and a deframer unit  44  for converting the data from the decoding unit  45  into a frame type through UTOPIA bus to be processed in the processor module unit of the central control processing module unit  40 ; and the physical access unit  39  for supporting a physical access medium according to variations of a physical access medium. 
     The 10 Base-T support operation and the XDSL interface support operation of the access device for supporting the variable data layer will now be explained, respectively. First, the 10 Base-T support operation of the access device will now be described. 
     When the input/output data of the user access processing module unit  33  is an analog data, such as a telephone or fax, the analog access processing unit  30  processes the data. Alternatively, the data is a digital data, such as digital trunk access of the private exchange, the digital access processing unit  31  processes the data. Depending on the type of data, the processed data is transmitted to the TDM switching unit  34  through the TDM bus A or B. 
     The TDM switching unit  34  transmits the data received through the TDM bus A or B to the voice processing unit  36  through the TDM bus C according to an internal switching operation. The voice processing unit  36  compresses the voice data received through the TDM switching unit  34  according to a compression method defined in the CPU  54  of the processor module unit  37 , and transmits the compressed voice data to the CPU  54  of the processor module unit  37  through the HPI bus. The CPU  54  converts the voice compression data, compression method and destination address into internet protocol (IP) frames to be transmitted to an external IP network, such as the Internet, through the LAN access processing unit  32 , and transmits the frames to the LAN access processing unit  32 . The LAN access processing unit  32  transmits the packet received from the processor module unit  37  to the external IP network. 
     When the IP packet is inputted from the external IP network through the LAN access processing unit  32 , the LAN access processing unit  32  transmits the received IP packet to the CPU  54  of the processor module unit  37 . The CPU  54  extracts voice data from the received IP packet, transmits the extracted data to the voice processing unit  36  through the HPI bus, designates a different restoring method in the voice processing unit  36 , and sets up a path of the TDM switching unit  34  according to a destination of the compressed voice data. The voice processing unit  36  restores the voice compression data received through the HPI bus according to the restoring method designated by the CPU  54  of the processor module unit  37 , and transmits the restored data to the TDM switching unit  34  through the TDM bus C. The TDM switching unit  34  transmits the restored data to the analog/digital access processing unit  30 ,  31  of the user access processing module unit  33  according to a switching path designated by the CPU  54 , so that the user can receive a voice service. 
     The xDSL interface support operation of the access device will now be described. The 10 Base-T support operation and the xDSL interface support operation are performed in the same manner until the voice data is compressed into the IP packet or the voice compression data extracted from the IP packet is restored in the analog/digital access processing units  30  and  31 , the TDM switching unit  34  and the voice processing unit  36 . Thereafter, the converted data may be transmitted to the LAN access processing unit  32  of the user access processing module unit  33 , or converted into the IP packet in the CPU  54  of the processor module unit  37 . The IP packet is divided into ATM cells by applicable program resident in the process module unit  37 , and transmitted to the PLD/PGA logic  55  for interfacing between the HPI bus and the UTOPIA bus. 
     The ATM cells transmitted to the PLD/PGA logic  55  are applied to the framer unit  42  of the frame conversion processing unit  38  of the WAN access processing module unit  41  through the UTOPIA bus, converted into xDSL frame supportable in the xDSL interface, transmitted to the encoder unit  43 , converted into a signal usable in the xDSL physical access unit, transmitted to the physical access unit  39  according to an access type of a physical medium, and then transmitted to the corresponding system through the external xDSL network. 
     When receiving data, the xDSL network signal is received from the corresponding communication system, such as xDSL, through the physical access unit  39 , passed through the decoding unit  45 , converted into a signal usable in the access device  100 , and transmitted to the deframer unit  44  of the frame conversion processing unit  38 . The deframer unit  44  extracts the ATM cells useful in the system from the received xDSL frame, and transmits them to the PLD/PGA logic  55  of the processor module unit  37  of the central control processing module unit  40  through the UTOPIA bus. 
     The PLD/PGA logic  55  converts the ATM cells received through the UTOPIA bus, and transmits the converted cells to the CPU  54  through HPI bus. The CPU  54  re-combines the received ATM cells, removes a header data, extracts the available IP packet, and analyzes the IP packet to extract the compressed voice data, voice compression/restoring method and destination information. The CPU  54  transmits the compressed voice data to the voice processing unit  36  through the HPI bus, transmits control information to the voice processing unit  36  according to the voice compression/restoring method, and sets up a switching path of the TDM switching unit  34  according to the destination information. The voice processing unit  36  restores the voice compression data according to the control information of the CPU  54 , and transmits the restored data to the TDM switching unit  34  through TDM bus C. The TDM switching unit  34  transmits the data to the analog/digital access processing unit  30 , 31  through the TDM bus A or B according to the switching path setup control information of the CPU  54 , so that the user receives accessed service through, for example, xDSL network. 
     Moreover, if a routing protocol supporting the IP packet processing can be built in the CPU  54  of the processor module unit  37  with the IP packet having the voice data, the local network as well as the analog/digital voice access service can be embodied by using the LAN access processing unit of the user access processing unit, thus connecting to the external WAN network through the access device. 
     As discussed earlier, the access device of the present invention supports the variable data layer, minimizes hardware variations due to variations of a physical layer access medium, and utilizes system hardware according to environmental variations of the physical access unit. 
     The foregoing embodiments and advantages are merely exemplary and are not to be construed as limiting the present invention. The description of the present invention is intended to be illustrative, and not to limit the scope of the claims. Many alternatives, modifications, and variations will be apparent to those skilled in the art. In the claims, mans-plus-function clauses are intended to cover the structure described herein as performing the recited function and not only structural equivalents but also equivalent structures.

Technology Classification (CPC): 7