KR100247029B1 - A multiplexing method and video interface unit in atm network - Google Patents

Abstract

The present invention relates to a video interface device and a video signal multiplexing method of an asynchronous transmission mode network configured to support a bidirectional on-demand video system. In particular, the video interface device of the asynchronous transmission mode network according to the present invention includes a VMCA module; An SIU module for connecting a subscriber side with the VMCA; And an asynchronous transmission mode cell bus that carries a function of carrying an asynchronous transmission mode cell between the SIU module and the VMCA module.

In addition, the video signal multiplexing method of the asynchronous transmission mode network according to the present invention comprises the steps of: receiving a video signal from a subscriber and adding a header to configure an asynchronous transmission mode cell; Multiplexing and transmitting the configured asynchronous transmission mode cell; Multiplexing the received cells; Transmitting the multiplexed cell to an asynchronous transmission mode switch; Receiving an asynchronous transmission mode cell from an asynchronous transmission mode switch; Analyzing a type of the received asynchronous transmission mode cell and selecting a corresponding subscriber board and a port in case of a subscriber cell; Loading the selected asynchronous transmission mode cell on a corresponding subscriber board; Demultiplexing an asynchronous transmission mode cell for the subscriber; And extracting a signal from the demultiplexed asynchronous transmission mode cell and transmitting the extracted video signal to a corresponding subscriber side.

Description

Video interface device and video signal multiplexing method in asynchronous transmission mode network {A MULTIPLEXING METHOD AND VIDEO INTERFACE UNIT IN ATM NETWORK}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a video interface device and a video signal multiplexing method in an asynchronous transfer mode (ATM) network. In particular, the present invention relates to asynchronous transmission of video information encoded in Moving Picture Expert Group (MPEG) 1 or MPEG 2. Image of an asynchronous transmission mode network having an image multiplexing device of an asynchronous transmission mode network which converts into an ATM cell and transmits it through an asynchronous transmission mode switch and restores image information through the transmitted asynchronous transmission mode cell. The present invention relates to an interface device and a video signal multiplexing method.

In order to support multimedia services such as video on demand (hereinafter referred to as VOD) and digital CATV service, data is transmitted and received using an asynchronous transmission mode network.

Figure 1 shows a schematic diagram of a conventional analog CATV system.

As shown, the analog CATV system includes a program provider and a system operator; It consists of a distribution network and a subscriber unit.

It is commonly referred to as a cable head-antenna end (HE) including the program provider and the system operator.

The HE is the most important part of the CATV system, and has a function of retransmitting a received broadcast wave, producing a program of its own, and processing various kinds of information for supporting future interactive services.

The distribution network functions to transmit the broadcast wave received from the HE to the subscriber side, and uses various branch amplifiers by sharing a transmission path or one transmission path that connects the HE and subscribers one-to-one according to the configuration of the distribution network. It can be configured as a tree / branch type that constitutes a branch network.

The subscriber device generally uses a general TV as a device for receiving various broadcast waves received through the distribution network. However, since the general TV cannot accommodate 11 to 13 or more channels due to a bandwidth problem, it is necessary to convert a frequency band of the received broadcast wave to receive 30 or 60 channel broadcast waves. Has a converter In addition, the converter may use a one-way converter, a two-way converter, or the like, depending on the transmission type.

In the analog CATV system, a system operator transmits various channels of services provided by a program provider to each subscriber through a distribution network.

In recent years, the VOD service, which has become a lot of interest, can select and watch movies, sports, and educational programs at the time that subscribers want to watch stored in the VOD server of the exchange office by using the transmission line already installed. It is an interactive TV service that can be provided with other communication services.

The VOD service can be instantly watched by the user at any time, regardless of time, and can utilize various functions such as play, rewind, pause, and quick operation as the VTR is operated while watching. The program is already watching the next user can see from the beginning. In addition, it is attracting much attention because of the advantage of being able to support other communication services while watching video.

However, currently provided VOD services are limited to small scale services using local area networks. The VOD service using the LAN is difficult to support a video signal in real-time due to the network configuration or the transmission bandwidth supported by the LAN.

In addition, current VOD service or digital CATV system must have interactive to support service according to user's request. However, there is a problem that the current analog CATV system cannot support this.

Therefore, the present invention was devised to solve the conventional problems as described above,

Video interface device and video in asynchronous transmission mode network using asynchronous transmission mode network with faster data transmission speed to support bidirectional communication in VOD service and digital CATV system, and having multiplexing device to support video service It is an object to provide a signal multiplexing method.

1 is a configuration diagram of an analog CATV network

2 is a block diagram of a video interface device of an asynchronous transmission mode network according to the present invention.

The present invention to achieve the above object,

Demultiplexing the asynchronous transmission mode cells received from the asynchronous transmission mode switch, transmitting the asynchronous transmission mode cells to each subscriber interface device, and multiplexing the asynchronous transmission mode cells received from each subscriber interface device. A Video Multiplexer Control Assembly (VMCA) module to perform; A subscriber interface for receiving video information from a subscriber, constructing an asynchronous transmission mode cell, transmitting the same to the VMCA module, receiving an asynchronous transmission mode cell from the VMCA module, extracting a video signal, and distributing a cell to each subscriber. A subscriber interface unit (SIU) and an asynchronous transmission mode cell bus functioning to carry an asynchronous transmission mode cell between the SIU and the VMCA module.

The present invention for achieving another object,

Receiving a video signal from a subscriber and adding a header to configure an asynchronous transmission mode cell; Multiplexing the configured asynchronous transmission mode cells and transmitting them to an image multiplexing control module using a cell bus; A third step of multiplexing the cells received by the image multiplexing control module; A fourth step of performing traffic processing and channel management for the multiplexed cell and transmitting it to an asynchronous transmission mode switch; A fifth step of receiving an asynchronous transmission mode cell from an asynchronous transmission mode switch; Analyzing a type of the received asynchronous transmission mode cell and selecting a corresponding subscriber board and a port in the case of a subscriber cell and ignoring it if not in the subscriber cell; A seventh step of delivering the selected asynchronous transmission mode cell to the corresponding subscriber board via the cell bus; An eighth step of demultiplexing the asynchronous transmission mode cell for the subscriber; And a ninth step of extracting a video signal by removing a header from the demultiplexed asynchronous transmission mode cell and a tenth step of transmitting the extracted video signal to a corresponding subscriber side.

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

2 is a block diagram of a video interface device according to the present invention.

As shown, for transmission / reception SIU (100) (200); It is composed of VMCA 300 which transmits / receives data using the SIU and cell bus lines and is connected to an exchange of an asynchronous transmission mode network.

The video interface device according to the present invention configured as described above has a transparent asynchronous transmitter-receiver interface of 20 Mbps using a 1.544 Mbps T1 interface and UTP5 (Unshielded Twisted Pair Cable Category 5) according to subscriber service characteristics. : Abbreviated as TAXI).

In order to support the two interfaces, the LIF selectively accepts the interface according to the characteristics of the subscriber signal.

The T1 interface is applied to down processing of a video signal, and TAXI is applied to up processing of a video signal. T1 can be used for VOD services and TAXI can be used for digital CATV applications.

The VMCA module 300 is a physical optical interface module that performs an interface function with a transmission path for transmitting an optical signal of an asynchronous transmission mode switching network, and a 155 Mbps Synchronous Transport Module level (STM) -1 class. A Line Interface Unit (LIF) 330 for supporting the interface; A router 320 for distinguishing what kind of cell the asynchronous transmission mode cell received from the asynchronous transmission mode exchanger has and the subscriber's cell using the cell header information to select a corresponding subscriber board and port; ; A demux (DEMUX) 310 having a function of loading the asynchronous transmission mode cell passing through the router 320 on the asynchronous transmission mode cell bus by a timing signal to the subscriber board; A mux (340) for multiplexing the asynchronous transmission mode cells received from the subscriber board via the asynchronous transmission mode cell bus; Asynchronous Transport Mode Layer 5 processing unit and Ethernet traffic, which performs the Operation Administration and Maintenance (hereinafter referred to as OAM) with the Asynchronous Transfer Mode Switch, or handles a network management system (Network Management System). : NMS) and the Ethernet interface unit 350 used for a small uplink channel utilization.

In addition, the VMCA 300 module has one optical interface module, which accommodates 64 1.544 Mbps T1 level interfaces or 20 6Mbps T2 level TAXI interfaces to accommodate 155 Mbps STM-1 interfaces.

The SIU (100) (200) is LIF (110) (210) for each subscriber signal connection; It has an asynchronous transmission mode layer / asynchronous transmission mode module 120 (220) and mux / demux 130 (230).

The demux 130 and 230 receive an asynchronous transmission mode cell from the VMCA 300 through a cell bus line to determine a corresponding output port, and then the asynchronous transmission mode layer / asynchronous transmission mode module 120 on the subscriber side. The asynchronous transmission mode cell is transmitted to the 220 side.

The asynchronous transmission mode layer / asynchronous transmission mode module 120, 220 uses 384 bytes of Common Part Convergence by using two MPEG 1 or MPEG 2 image information composed of 188 bytes at the subscriber side using the asynchronous transmission mode layer protocol. Sublayer) Configures a Protocol Data Unit (PDU) and performs a segmentation and reassembly (SAR) function of dividing the CPCS PDU into a fixed length of 48 bytes.

After the above process, the asynchronous transmission mode layer (120) 220 generates a 53-byte asynchronous transmission mode cell by attaching a header to the 48-byte SAR PDU and transmits to the mux (130) (230).

On the contrary, the asynchronous transmission mode cell received from the asynchronous transmission mode network through the demux 310 in the VMCA 300 removes all the headers of the cells, reassembles the video stream, and transmits the video stream to the LIF side.

The MUX 340 functions to multiplex the video signal received from the subscriber side into the asynchronous transmission mode cell bus by the synchronous signal after multiplexing the asynchronous transmission mode cell composed of the asynchronous transmission mode cell.

The operation of the multiplexing device composed of the above components will be described in detail as follows.

When the asynchronous transmission mode cell information is received from the asynchronous transmission mode switch via the LIF 330, the router 320 analyzes the type of the asynchronous transmission mode cell using the header information of the asynchronous transmission mode cell.

That is, the input cell is distinguished from a subscriber cell, a multicast cell, or a maintenance cell.

If the input cell is a subscriber cell, the demux 310 transmits the asynchronous transmission mode cell on the asynchronous transmission mode cell bus.

The asynchronous transmission mode cell is transmitted to a corresponding subscriber board through an asynchronous transmission mode cell bus.

The demux 130, 230 of the subscriber board SIU 100, 200 received through the asynchronous transmission mode cell bus selects an output port and transmits the asynchronous transmission mode cell to the port side of the subscriber.

After extracting the image information from the asynchronous transmission mode cell in the asynchronous transmission mode layer / asynchronous transmission mode (120, 220) of the port receiving the asynchronous transmission mode cell and accepts the T1 interface transmission path through the LIF (110) (210) The video signal is transmitted to the subscriber.

Conversely, when the video signal encoded in the digital CATV system is input to the LIF 110 and 210, the asynchronous transmission mode layer processing unit 120 and 220 configures the input 188 bytes of MPEG image information into a CPCS PDU and then, Split the CPCS PDU into 48-byte fixed length SAR PDUs.

The asynchronous transmission mode processing unit 120 or 220 adds a unique virtual path identifier (VPI) / virtual channel identifier (VCI) of a corresponding port to the SAR PDU and converts the asynchronous transmission mode cell.

The asynchronous transmission mode cells in each port are multiplexed by the mux 130 and 230 in the SIU 100 and 200 and then transmitted to the VMCA 300 side through the asynchronous transmission mode cell bus.

The mux 340 of the VMCA 300 receiving the asynchronous transmission mode cell takes asynchronous transmission mode cells on the asynchronous transmission mode cell bus using a timing signal and multiplexes them.

The mux 340 distinguishes whether the asynchronous transmission mode cell received from the asynchronous transmission mode cell bus is a cell transmitted from the SIU 100, 200 to the VMCA 300 side or a cell transmitted from the subscriber side.

When the asynchronous transmission mode cell is a subscriber cell, it transmits to the optical interface module via the asynchronous transmission mode layer 5 processor 350 and the LIF 330.

After the information transmitted to the VMCA 300 through the Ethernet port is analyzed by the processor of the VMCA 300, the information to be sent to the asynchronous transmission mode switch or the SIU 100 (200) is sent to the asynchronous transmission mode layer 5 processor 350. After asynchronous transmission mode cell is made and transmitted.

As described above, the present invention can provide various multimedia services because high-speed bidirectional communication is possible by transmitting video signals through an asynchronous transmission mode network, and various services and subscribers can be provided by mounting a subscriber board according to a service request of a user. Depending on the shape of the can be flexible. In addition, the Ethernet port enables the use of Network Management System (NMS) and small uplink channels, and enables efficient network usage and remote subscribers.

The video interface device according to the present invention can support a two-way service using a conventional communication line to accommodate a conventional telephone and data service, and can be used with a transmission technology of an Asynchronous Digital Subscriber Line (ADSL) method. Since the conventional telephone line can be used as it is, the cost can be greatly reduced.

Claims (6)

Asynchronous transfer mode cells received from an asynchronous transfer mode (ATM) exchange are demultiplexed to transmit asynchronous transfer mode cells to each subscriber interface device, and multiplexed asynchronous transfer mode cells received from each subscriber interface device. An image multiplexing control module for performing the operation; Receives video information from subscribers, configures asynchronous transmission mode cells, transmits them to the video multiplexing control module, receives the asynchronous transmission mode cells from the video multiplexing control module, extracts video signals, and distributes cells to each subscriber. And a subscriber interface device for doing so; And an asynchronous transmission mode cell bus configured to carry an asynchronous transmission mode cell between the subscriber interface device and the video multiplexing control module. The image multiplexing control module according to claim 1, A physical optical interface module that interfaces with a transmission path for transmitting the optical signal of the asynchronous transmission mode switching network; A line interface device for supporting a synchronization module level 1 STM-1 class interface; A router configured to distinguish which type of cell the asynchronous transmission mode cell received from the asynchronous transmission mode exchanger is, and to select a corresponding subscriber board and a port by using header information of the cell when the cell is a subscriber cell; A demux for loading an asynchronous transmission mode cell onto a subscriber board; A mux for multiplexing the asynchronous transmission mode cells received from the subscriber board from the asynchronous transmission mode cell bus; And an asynchronous transmission mode layer 5 processing unit / ethernet interface unit for providing a maintenance management (OAM) function with an asynchronous transmission mode switching unit. The method of claim 1, wherein the subscriber interface device, A demux for receiving an asynchronous transmission mode cell from the image multiplexing control module and determining a corresponding output port; An asynchronous function that extracts a video signal by removing a header from an asynchronous transmission mode cell received by demultiplexing from the demux, or generates a 53-byte asynchronous transmission mode cell by receiving video information of a subscriber and pasting header information. Transmission mode layer / asynchronous transmission mode module; A mux for multiplexing the asynchronous transmission mode cells received by the asynchronous transmission mode layer / asynchronous transmission mode module and transmitting the multiplexed asynchronous transmission mode cell buses; And a line interface device (LIF) that performs a function of receiving video information from a subscriber line providing a T-one interface. The method of claim 1, In accordance with the characteristics of the subscriber service, only the subscriber interface device is replaced to support the flow of the cell, the video interface device of the asynchronous transmission mode network, characterized in that to apply the T-one (T1) interface for video on demand (VOD) service. The method of claim 1, A video interface device of a video interface device of an asynchronous transmission mode network, characterized by applying a transparent asynchronous transmission / reception interface (TAXI) to a digital cable service (CATV). Receiving a video signal from a subscriber and adding a header to configure an asynchronous transmission mode cell; Multiplexing the configured asynchronous transmission mode cells and transmitting them to an image multiplexing control module using a cell bus; Multiplexing the cells received by the image multiplexing control module; A fourth step of performing traffic processing and channel management for the multiplexed cell and transmitting it to an asynchronous transmission mode switch; A fifth step of receiving an asynchronous transmission mode cell from an asynchronous transmission mode switch; Analyzing a type of the received asynchronous transmission mode cell and selecting a corresponding subscriber board and a port in the case of a subscriber cell and ignoring it when not in the subscriber cell; A seventh step of delivering the selected asynchronous transmission mode cell to the corresponding subscriber board via the cell bus; An eighth step of demultiplexing an asynchronous transmission mode cell for the subscriber; Extracting a video signal by removing a header from the demultiplexed asynchronous transmission mode cell; And a tenth step of transmitting the extracted video signal to a corresponding subscriber.

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