KR100349726B1 - Apparatus for advanced signal transfer between PABX - Google Patents

Abstract

The present invention relates to an apparatus for improved signal transmission implementing an ISDN Primary Rate Interface (PRI) module supporting QSIG, which is a communication protocol of heterogeneous private switching periods.

A feature of the present invention is an apparatus for improved signal transmission in a private exchange period, wherein data having one frame structure is transmitted / received to a heterogeneous private exchange using E1 / T1 used in a first layer, which is a physical layer. (Tx / Rx) in the form of a frame unit that receives or receives data of a predetermined channel (ch) through the frame unit transmitted or received, and a highway transmission signal (Tx) transmitted from the frame unit to form a frame structure again The time switching unit for switching to the frame unit, the main controller unit and the predetermined highway to generate the appropriate D channel (ch) through the predetermined number of built-in D channel (ch) controller and send it to the time switching unit in the form of predetermined serial data And an FPGA configured to convert a conversion module therein to transmit the serial data to the frame part and the main control part.

The present invention not only provides all of the ISDN PRI protocols, but also can effectively support the QSIG protocol, thereby providing the advantage of integrating all ISDN PRI-based services into one module.

Description

Apparatus for advanced signal transfer between PABX}

The present invention relates to an apparatus for improved signal transmission in a private exchange period, and more particularly, to an improved signal transmission that implements an ISDN Primary Rate Interface (PRI) module supporting QSIG, which is a communication protocol of a heterogeneous private exchange period. It is about a device.

In general, QSIG, a communications protocol for heterogeneous private exchanges, cannot work with ISDN and thus cannot provide ancillary services across a virtual private network (VPN). In order to discover the possibility of a public Integrated Services Digital Network (ISDN), the ISDN Packet Mode Bearer Service (PMBS) must be used to enable the transmission of the signaling traffic required for additional services.

In addition, network connection with a digital communication network such as ISDN is performed according to the Open Systems Interconnection (OSI) model. The OSI model includes a physical layer as the first layer, a data link layer as the second layer, a network layer as the third layer, a transport layer as the fourth layer, a session layer as the fifth layer, and a presentation layer as the sixth layer. And an application layer which is a seventh layer. The PRI of ISDN has one frame structure of 30B + 1D, that is, it is composed of 30 B channels and 1 D channel, which is a data channel, and allows T1 and E1 to be used in the first layer, which is a physical layer.

1 is a block diagram of an apparatus for signal transmission in a private exchange period according to the prior art.

In FIG. 1, the frame unit 10 into which the reception signal Rx transmitted from the heterogeneous private exchange is input has a form of 30B + D channel (ch) using E1 and T1 used in the first layer, which is a physical layer. The data is transmitted to the time switching unit 20. The time switching unit 20 sends 1 to 15 channels (ch) and 17 to 31 channels (ch) of the data transmitted from the frame unit 10 as a highway transmission signal (Tx), which is 16 channels (ch). The D channel ch is separately selected and transmitted to the main controller 30. Main controller 30 has a built-in D channel (ch) controller can interpret the D channel (ch), through which implements the ISDN PRI protocol.

Meanwhile, when the transmission signal Tx is transmitted to the heterogeneous private exchange, the main controller 30 generates an appropriate D channel ch through the built-in D channel controller 31, and then the time switching unit 20. Send to). The time switching unit 20 receives the data of 1-15 channels (ch) and 17-31 channels (ch) through the highway reception signal Tx and transmits the D channel (ch) transmitted from the main controller 30. The sum is made into one frame structure and then transmitted to the frame unit 10.

The frame unit 10 transmits data having one frame structure transmitted from the time switching unit 20 using E1 / T1 used in the first layer, which is a physical layer, to a heterogeneous private exchange in the form of a reception signal Rx. send.

The clock generator 40 receives a FOI signal synchronized with a clock of the system and a 4MHz signal to generate a signal for controlling the D channel (ch) controller built in the main controller 30. The FOI signal is a frame signal every 125us. It has a low pulse of 244ns and is input to the frame unit 10 and the time switching unit 20 together with the 4MHz signal.

However, according to the conventional apparatus for signal transmission in the private exchange period, the following problem occurs.

There is a limit to the control of the D channel from the main control part. According to the ISDN PRI's recommendation, the QSIG protocol is not supported because one or two of the 30 B channels are dedicated to the D channel to use various additional services. can not do it.

Accordingly, an object of the present invention is to solve this problem, and an object of the present invention is to provide an improved signal transmission for a private exchange period based on an ISDN PRI and adding up to three D channel handing functions required for the QSIG protocol. To provide.

1 is a block diagram showing a configuration of an apparatus for signal transmission in a private exchange period according to the prior art;

2 is a block diagram showing a configuration of an apparatus for improved signal transmission in a private exchange period according to the present invention;

A feature of the present invention for achieving the above object is, in the apparatus for signal transmission in the private exchange period, E1 used in the first layer which is a physical layer and has a D channel controller to process the D channel data itself Frame part that transmits or receives data having one frame structure in the form of transmit / receive signal (Tx / Rx) to heterogeneous private exchange using / T1, and highway receive signal (Tx) transmitted from the frame part Generates an appropriate D channel (ch) through a time switching unit for receiving data of a predetermined channel (ch) through a single frame structure and then switching back to the frame unit, and a predetermined number of D channel (ch) controllers. After that, the conversion module is configured inside so that the main control part and the predetermined highway which are sent to the time switching unit are converted into a predetermined serial data form. There comprises an FPGA that transferred to the frame part and the main control group.

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

2 is a block diagram showing a configuration of an apparatus for improved signal transmission in a private exchange period according to the present invention.

In FIG. 2, when the ISDN PRI protocol is applied, the frame unit 100 plays a role of controlling one existing D channel (ch) using the built-in D channel controller 110. It uses T1 trunk, which is an analog network interface, for the network connection with the Public Switched Telephone Network, and T1 / E1, which is used in the physical layer, the first layer, for the E1 PRI, the digital network interface for the network connection with ISDN. Thus, data having one frame structure is transmitted to a heterogeneous private exchange in the form of an outgoing signal Rx. PRI of ISDN has one frame structure of 30B + 1D, that is, it consists of total 30 B channels (ch) and 1 D channel (ch) which is a data channel and 1 or 2 B channels (ch) It is dedicated to this D channel ch.

The main controller 300 directly accesses the D channel controller 110 embedded in the frame unit 100, reads data interpreted by the D channel controller 110, and controls the frame unit 100. This allows D channel (ch) transmission.

The frame unit 100 can directly interpret the D channel (ch) through the built-in D channel controller 110, and transmits 30 B channel transmission signals (Rx) to the time switching unit 200, and time switching. The unit 200 switches the transmission signals Rx of the 30 B channels and immediately sends them to the highway.

On the other hand, in order to process the QSIG protocol, the transmission signal Tx from the heterogeneous private exchange enters the frame part 100 and starts with the ISDN PRI processing. That is, the frame unit 100 processes the D channel ch and transmits 30 B channels ch through the time switching unit 200 to the highway.

Once the ISDN PRI is setup, the heterogeneous private exchanges connected to each other determine one or two B channels (ch) to dedicate to additional D channels (ch). According to this determination, the B channel ch to be converted to the D channel ch among the 30 B channels ch transmitted from the frame unit 100 to the time switching unit 200 is a highway in the time switching unit 200. It is transmitted to the D channel controllers 310 and 320 of the main controller 300 in the form of D channel reception signals D-ch 2 Rx and D-ch 3 Rx.

When the transmission signal Rx is transmitted to the heterogeneous private exchange, the main controller 300 generates two D channel data through the built-in D channel controllers 310 and 320 and transmits the two D channel data to the time switching unit 200. The time switching unit 200 forms a 30B channel (ch) in order to match the transmission signal transmitted in the form of D channel transmission signals (D-ch 2 Tx and D-ch 3 Tx) to the frame unit 100. send. The frame part 100 combines the transmitted 30B channel (ch) and one D channel (ch) and finally generates a structure of 30B + D and transmits the heterogeneous private exchange.

The FPGA (Fieid Programmable Gate Array) 400 receives a FOI signal and a 4 MHz signal to control the D channel controllers 110, 310, and 320 embedded in the frame unit 100 and the main controller 300, respectively. The FPGA 400 has a module configured to convert a 2 Mbps highway into a 4 Mbps serial data (31 channel) highway. The FOI signal and the 4MHz signal are network clocks, and the FOI signal is supplied from a synchronous frequency generator (not shown) that receives a synchronous frequency (FS) and a system frequency (4.096 MHz) from a private exchange and generates an FOI signal. It is a predetermined frame signal.

As described above, in the detailed description of the present invention, specific embodiments have been described, but various modifications are possible without departing from the scope of the present invention. Therefore, the scope of the present invention should not be limited to the described embodiments, but should be defined by the claims below and equivalents thereof.

As a result, according to the apparatus for improved signal transmission according to the present invention the following advantages occur.

In other words, it not only provides all of ISDN PRI's protocols but also can effectively support QSIG protocol, so all ISDN PRI-based services can be integrated into one module.

Claims (2)

An apparatus for signal transmission in a private exchange period, A D channel controller is provided to process D channel data by itself, and transmits / receives a signal of one frame structure to a heterogeneous private exchange using E1 / T1 used in the first layer, which is a physical layer (Tx / Rx). Frame part transmitted or received in the form of), A time switching unit which receives data of a predetermined channel (ch) through a highway transmission signal Tx transmitted from the frame unit, forms a frame structure, and then switches back to the frame unit; The main control unit generates an appropriate D channel (ch) through a predetermined number of built-in D channel (ch) controller and sends it to the time switching unit; And an FPGA configured therein to convert a predetermined highway into a predetermined serial data format and transmit the serial data to the frame unit and the main controller unit. delete