KR100217347B1 - Transmission distance extending apparatus of s-interface in private n-isdn - Google Patents

Abstract

The present invention relates to an extension of a transmission distance of an S interface, and more particularly, to an NISDN (Narrow Band Integrated Services Digital Network) service suitable for high-speed data communication of a PBX (Private Branch Exchange). The present invention relates to a transmission distance extension device of an S interface.

An object of the present invention is to provide a device that has a wider service area by making the network termination equipment (NTE) connecting the S interface and the U interface both accessible between the PBX and the TE (Terminal Equipment). This is to overcome the problem of the transmission distance limitation of the interface.

Accordingly, by applying the NTE that provides the U interface to the PBX, the distance limit of the S interface is extended to enable the provision of NISDN services within a wider premises.

Description

Transmission distance extension device of S interface in premises NISDN service

The present invention relates to an extension of the transmission distance of the S interface, and more particularly, to the transmission distance of the S interface in a narrow band integrated services digital network (NISDN) service suitable for high-speed data communication of a PBX. Relates to an expansion device.

In general, the PBX 1 and the TE (terminal device) 2 are four-wire systems in which a transmitting end and a receiving end are separated while being interconnected by an S interface as in the configuration for the conventional premises NISDN service shown in FIG.

At this time, the transmission code of the S interface is an AMI (Alternative Mark Inversion) method, the maximum transmission distance is 1km.

In the S interface, a process of activating the S interface and deactivating when the call is terminated before establishing a call between TE (2) and PBX (1).

Thus, as shown in Figure 2 shows the signal flow on the S interface for the activation / deactivation process. The signal flow at this time follows the Recommendation of the Consultative Committee for International telegraphy and telephony (CCITT).

That is, when there is no service, the S interface has Info0 as an idle state, and in order to perform the service, the S interface must first undergo an activation process.

The signals for synchronizing the clock between the TE 2 and the PBX 1 are Info1 and Info2. If the synchronization is correct, Info3 and Info4, which are channels for service, exist.

When the service terminates, it enters the idle state by exchanging Info0 signals with each other.

However, as described above, the PBX connected to the NISDN through the S interface is limited to a transmission distance of 1 km, thereby limiting the installation in the premises of a large area.

On the other hand, the NTE, to which the local exchange is connected for NISDN service, uses a U interface having a wide transmission distance, unlike the PBX 1.

Accordingly, the general connection of the NTE is connected to the 4-wire while connecting to the TE through the S interface as shown in FIG. 3, and connected to the 2-line while connecting to the LT (Line termination) via the U interface.

In this way, the NTE is configured as shown in FIG.

That is, the NTE is composed of an S transceiver connected to the S interface and a U transceiver connected to the U interface, and connected to a clock line and a data line.

Each of these transceivers converts the signal coming in through the connected interface into its corresponding interface.

At this time, the synchronization of each transceiver should match.

Accordingly, the U transceiver generates a clock synchronized with the U interface and supplies it to the S transceiver, and the S transceiver receives the clock and drives the S interface so that synchronization is synchronized.

In the end, the U transceiver is the clock master and the S transceiver is the clock slave. From the interface point of view, the U transceiver is the clock slave dependent on the LT clock and the S transceiver is the clock master on the TE side.

If the NTE connecting both the S interface and the U interface is applied to the PBX for NISDN service, the service area of the PBX will be further expanded.

Accordingly, the present invention provides a device that enables a wider service area by allowing an NTE connecting both the S interface and the U interface to be connected between the PBX and the TE as described above, thereby limiting the transmission distance limit of the S interface. The purpose is to overcome.

In the premises NISDN service of the present invention for achieving the above object, the transmission distance extension device of the S interface, the premises NISDN including a PBX and TE connected to the S interface to provide a NISDN service, the transmitter and the receiver are connected in a four-wire manner A service device comprising: a first NTE connected to the PBX and an S interface and connected in four wires to generate a clock and supply the clock to the PBX side; And a second NTE connected to the first NTE while connected via a U interface, and connected to the first NTE through a four wire while transmitting and receiving data according to a clock supplied from the first NTE. .

1 is a configuration diagram for a conventional premises NISDN service,

FIG. 2 is a signal flow diagram on an S interface for activation / deactivation in FIG.

3 is a mounting position diagram of an NTE in a typical NISDN,

4 is a configuration diagram of an NTE in FIG. 3;

5 is a block diagram of a transmission distance extension device of the S interface in the premises NISDN service according to the present invention,

FIG. 6 is a configuration diagram of a first NTE in FIG. 5;

7 is a signal flow diagram for activation / deactivation in the present invention.

* Explanation of symbols for main parts of the drawings

1: Private Branch Exchange (PBX) 2: Terminal Equipment (TE)

10-1,10-2: First Network Termination Equipment (NTE)

20-1,20-2: 2NTE 11: S Transceiver

12: U transceiver 13: clock generator

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

FIG. 5 is a block diagram of an apparatus for extending a transmission distance of an S interface in an on-premises NISDN service according to the present invention, FIG. 6 is a block diagram of a first NTE in FIG. 5, and FIG.

The configuration of the present invention according to FIG. 5 comprises a first NTE 10-1 10-2 and a second NTE 20-1 20- 20 between PBX 1 and TE 2-1 2-2. 2) is configured for connection.

At this time, the TE (2-1) (2-2) and the second NTE (20-1) (20-2), PBX (1) and the first NTE (10-1) (10-2) is connected by the S interface 4-wire connection.

The first NTE (01-1) 10-2 and the second NTE (20-1) 20-2 are connected by a U interface and are connected in two wires.

Meanwhile, as illustrated in FIG. 6, the first NTE 10-1 and 10-2 include an S transceiver 11, a U transceiver 12, and a clock generator 13.

The S transceiver 11 is connected to the S interface with the PBX 1 to transmit and receive data, and the U transceiver 12 is connected to the S transceiver 11 by a data line and the second NTE 20-1. It is connected to the U interface with (20-2) to transmit and receive data, and the clock generator 13 provides a clock required for the operation of each of the transceivers (11) (12).

Accordingly, since the transceivers 11 and 12 receive the clock when viewed from the inside of the first NTE 10-1 and 10-2, the U transceiver 12 operates as a clock slave. It becomes the clock master of the U interface, and the S transceiver 11 becomes the clock master of the S interface.

In addition, the second NTE 20-1 and 20-2 have the same configuration as the general NTE shown in FIG. 4. Accordingly, the second NTE 20-1 and 20-2 may operate with a clock provided by the first NTE 10-1 and 10-2.

The operation of the present invention configured as described above will be described with a signal flow diagram for activation / deactivation of FIG. The signal flow at this time is in accordance with the CCITT Recommendation.

First, in order to set up a call, each interface must be activated first.

However, since the call is in the idle state before the call setup, as shown in FIG. 7, there are Info0 on the S interface and SL0 and SN0 on the U interface.

If the PBX 1 inputs Info2 to the first NTE 10-1 for call setup, a process for synchronizing between the first NTE 10-1 and the second NTE 20-1 on the U interface is performed. If the synchronization is correct, the SL3T and SN3T signals are present on the U interface.

At this time, synchronization is performed by a clock generated by the clock generator 13 of the first NTE 10-1.

As described above, while the SL3T and SN3T signals are present on the U interface, Info3 and Info4 are present on the S interface.

This is also synchronized to the clocks by the clock generator 13 of the first NTE 10-1.

If all of these synchronizations match, call setup is made and service provided.

After that, when the service is terminated and the call recovery process is performed, Info0 is inputted from the PBX (1) to the first NTE (10-1). As a result, SL0 and SN0 exist on the U interface and become idle, and the S interface. Info0 is also present in the idle state.

As such, the activation / deactivation process by the NTE configured between the PBX and the TE to provide the U interface is enabled, thereby widening the service area of the premises.

As described above, according to the present invention, by applying the NTE providing the U interface to the PBX, the distance limit of the S interface is extended to provide the NISDN service within a wider premises.

Claims (3)

In the premises NISDN service apparatus including a PBX and TE connected to the S interface to provide the NISDN service, connected in a four-wire manner in which the transmitter and the receiver are separated, A first NTE connected to the PBX and an S interface and connected in four wires to generate a clock and supply the clock to the PBX; And a second NTE connected to the first NTE while connected via a U interface, and connected to the first NTE through a four wire while transmitting and receiving data according to a clock supplied from the first NTE. Transmission distance extension device of S interface in premises NISDN service. The method of claim 1, The first NTE includes an S transceiver which is connected to an S interface with the PBX, transmits and receives data, and supplies a clock on the S interface; A U transceiver connected to the S transceiver and a data line, connected to a U interface with the second NTE, to transmit and receive data, and to supply a clock on the U interface; Apparatus for extending the transmission distance of the S interface in the NISDN on-premises, characterized in that it comprises a clock generator for providing a clock required for the operation of each transceiver. The method of claim 1, The second NTE includes an S transceiver connected to an S interface with the TE to transmit and receive data and to supply a clock on the S interface; An on-premises NISDN connected to the S transceiver with a data and clock line, connected to a U interface with the first NTE to transmit and receive data, and a U transceiver for providing a clock provided from the first NTE to the S transceiver. Transmission distance extender of S interface in service.