KR100284319B1 - Time Switch Stabilization Circuit of Aerial Network Matching Device in Satellite Communication System - Google Patents

Abstract

The present invention provides a public network matching device in a satellite communication system that can prevent transmission data from being damaged by stabilizing a function of a time switch for switching data transmitted and received in a public network matching device (TIP) coupled to a public switched network (PSTN) for each channel. It relates to a time switch stabilization circuit of (TIP).

In the present invention, the data shifting unit 21 at the front end of the time switching unit 15 to prevent frequent damage of transmission data through the time switching unit 15 of the TIP combined with the public switching network (PSTN). ), Data transmitted from the system to the public switched network (PSTN) via the bus interface unit 16, or data transmitted from the public switched network (PSTN) to the system is applied to the data shifting unit 21 and After 8-bit shifting through the data shifting unit 21, the switch is transmitted to the corresponding channel through the time switching unit 15.

Therefore, according to the present invention, it is possible to prevent damage to data transmission in communication with a public switched network (PSTN) through a public network matching device in a satellite communication system.

Description

Time Switch Stabilization Circuit of Public Network Matching Device in Satellite Communication System

The present invention relates to a communication system using satellite, and in particular, by stabilizing the function of the time switch for switching the data transmitted and received in the TIP (TIP) coupled to the public switched network (PSTN) for each channel to prevent damage to the transmission data It relates to a time switch stabilization circuit of a TIP in a satellite communication system.

The satellite communication system is composed of a central control station that performs overall system control and a base station that provides a communication function between subscribers connected to the central control station via satellite and coupled through a physical line.

The central control station performs a polling function to check the state of each base station, that is, the available capacity of the communication channel or the communication channel. When there is a call request from a specific base station (calling base station) to a terminal having jurisdiction of another base station (called base station), it is determined whether the corresponding called base station is in a state capable of communication based on the information obtained in the polling process. In the communicable state, the available traffic channels of the satellites are allocated to both base stations to directly communicate with each other.

In addition, the satellite communication system is coupled to the general public switched network (PSTN) through a TIP to provide an incoming call or an outgoing call.

1 is a block diagram showing the configuration of a public network matching device (TIP) for combining with a public switched network (PSTN) in the satellite communication system.

In FIG. 1, reference numeral 10 denotes a public network matching device for coupling with a public switched network (PSTN), 11 is a trunk interface unit capable of interfacing with a public switched network through an E1 trunk, and 12 is a public air via this trunk interface unit 11. A frame adjusting unit for extracting data transmitted from a switching network or adjusting data for transmission to a public switching network to a contracted frame format.

In addition, reference numeral 13 is a Doppler buffer for compensating the Doppler effect caused by the positional shift over time of the satellite, and 14 is a public network based on a predetermined control signal input through the bus interface unit 16 to be described later. Board controller responsible for the overall device control of the matching device 10, 15 is a time switching unit, which is implemented as a switch by a digital method is output from the Doppler buffer 13 in accordance with the control signal of the board controller 14 The predetermined data string is switched for each channel, or the transmission data input through the bus interface unit 16 to be described later is switched for each channel.

In addition, reference numeral 16 is a bus interface unit for interfacing an MPH bus for exchanging voice or data, an UPH bus for performing communication and an audible tone with an HDLC protocol, and the like.

When the network matching device 10 having the above-described configuration generates data to be transmitted from the base station to the public switched network, the data is input to the time switching unit 15 through the bus interface unit 16. 15 switches the data based on the control signal of the board controller 14 and outputs the data to the Doppler buffer 13.

On the other hand, the format of the data transmitted as described above is composed of 32 timeslots per frame, one time slot is composed of 8 bits. In addition, the public network matching device 10 generates a reference clock of 2 MHz through the time switching unit 15 to synchronize with a clock signal provided from the system, and when there is one frame data transmission, start a frame. Data is transmitted in synchronization through a signal (Start Of Frame).

By the way, the time switch called "MT8980D" used as the time switching unit 15 is generally synchronized with the start of the frame data as the XSOF signal, using a clock of 4MHz as a reference clock, Figure 2 As shown in FIG. 8, 8-bit data is normally transmitted only when the falling edge of the XSOF signal is synchronized with the falling edge of the reference 4 MHz at the center of the rising edge.

However, an error always occurs in data transmission in system operation. In view of this point, the public network matching device 15 also synchronizes data without departing from the error limit, but the polling edge of the XSOF. If the reference clock is not located at the center of the rising edge, for example, if the reference clock is delayed and the synchronization is not synchronized, the transmitted data is damaged.

Accordingly, the present invention has been made in view of the above circumstances, and stabilizes the function of a time switch for switching data transmitted / received by a TIP, which is matched with a public switched network (PSTN), for each channel, thereby preventing damage to transmission data. The purpose of the present invention is to provide a time switch stabilization circuit in a TIP of a satellite communication system that can be prevented.

1 is a block diagram showing the configuration of a public network matching device (TIP) for coupling with a public switched network (PSTN) in a satellite communication system.

2 is a clock timing diagram showing a reference clock and a start signal (XSOF) of a data frame of the public network matching device 10 of FIG.

3 is a block diagram showing a time switch stabilization circuit of a public network matching device in a satellite communication system according to an embodiment of the present invention.

4 is a diagram showing an example of a detailed configuration of the data shifting unit 21 of FIG.

FIG. 5 is a diagram illustrating a data shift diagram in which data is shifted according to the operation of each deflip flop of FIG. 4 according to a clock pulse application; FIG.

<Explanation of symbols for main parts of drawing>

10: public network matching device (TIP) 11: trunk interface unit

12 frame adjustment unit 13 Doppler buffer

14: board controller 15: time switching unit

16: bus interface unit 21: data shifting unit

DF1 to DF9: D flip-flop XSOF: Data frame start signal

In the satellite communication system according to the present invention for realizing the above object, the time switch stabilization circuit of the public network matching device includes a trunk interface unit for transmitting and receiving data from the public switched network, and data transmitted and received through the trunk interface unit in a contracted frame format. A frame controller for adjusting, a Doppler buffer for reading and writing transmitted data, a bus interface for transmitting and receiving data from the system, a board controller for controlling the entire apparatus according to a predetermined control signal input through the bus interface, and the bus A data shifting unit for shifting data input through an interface unit or applied through a Doppler buffer from the public switched network; and a time switching unit for switching and outputting the shifted data for each channel through the data shifting unit. Characterized in that configured to include.

In addition, the data shifting unit is composed of a combination of nine consecutive dip-flop, characterized in that the clock input of the other eight de-flip-flops other than the de-flip-flop of the output stage is input through the inverter.

In addition, the data shifting unit is characterized in that a plurality of data input and output is a combination of the nine consecutive dip-flop.

That is, according to the present invention having the above-described configuration is to transfer the data transmitted through the public network matching device coupled to the public switched network by a predetermined shift through the data shifting unit to prevent data from being damaged when the time switching unit is not synchronized You can do it.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.

3 is a block diagram illustrating a time switch stabilization circuit of a public network matching device in a satellite communication system according to an embodiment of the present invention. The same reference numerals will be used to designate the same parts as those shown in FIG.

In FIG. 3, reference numeral 21 denotes a data shifting unit for shifting data received from the public switched network through the Doppler buffer 13 or data received from the system through the bus interface unit 16, for example, by 8 bits. .

The data shifting unit 21 is composed of a combination of a D flip-flop and a logic circuit such as NOT. The detailed configuration of the data shifting unit 21 is illustrated in FIG. 4.

That is, in the data shifting unit 21 illustrated in FIG. 4, the de-flop flops are continuously coupled so that the received data is input to the first de-flop flop DF1, and the output of the de-flop flop DF1 is It is a structure that is input to the next flip-flop (DF2), and this structure is sequentially combined up to the 9th flip-flop (DF9), and the last 9th flip-flop (DF9) is clocked in as it is, The clocks of the flip-flops DF1 to DF8 are configured such that the clock through the inverter IVT is input so that one bit is shifted while passing through one of the flip-flops.

In addition, the above configuration may be configured in plural to receive and shift a plurality of data, and the data received from the public switched network through the Doppler buffer 13 or the data received from the system through the bus interface unit 16. After all are applied to the data shifting unit 21 and shifted 8 bits, the channel is switched by the time switching unit 15.

Next, the operation of the apparatus according to the present invention will be described with reference to a data shift diagram in which data is shifted in accordance with the operation of each flip-flop according to the clock pulse application shown in FIG. 5.

First, the board controller 14 of the public network matching device according to the present invention transmits data from the satellite network to the public switched network (PSTN) and the public switched network (PSTN) based on the reference clock of the system supplied through the bus interface unit 16. Data transmission from the satellite network to the satellite network is controlled. As the reference clock, a 4 MHz clock suitable for data transmission and division is used.

In addition, when the data shifting unit 21 is operated based on the system reference clock supplied through the bus interface unit 16 as described above, when the falling edge of the reference clock 4 MHz is located at the center of the XSOF signal. The input of the data frame begins. In addition, both the data transmitted from the system through the bus interface unit 16 and the data transmitted from the public switched network through the trunk interface unit 11 are input to the data shifting unit 21.

Therefore, as shown in FIG. 4, the data input to the data shifting unit 21 is first applied to the input of the first deflip-flop DF1, and the clock pulse is applied only to the ninth deflip-flop DF9. Since the rest DF1 to DF8 are applied through the inverter IVT, they are operated at the rising edge of the reference clock 4 MHz, so that the first bit of the input data framing is shifted by a half clock.

Subsequently, data input and output to the first deflip-flop DF1 is shifted by 1 bit, and the 1-bit shifted data is applied to the next second flip-flop DF2 and its output is shifted by 2 bits. Will be output.

The 2-bit shifted data of the second flip-flop DF2 is input to the third flip-flop DF3, and then the output thereof is shifted 3-bit and then applied to the fourth flip-flop DF4.

The output data through the fourth deflip-flop DF4 is output by being shifted 4 bits, and the data is shifted into the next fifth flip-flop DF5 to output 5-bit shifted data.

Subsequently, the 5-bit shifted data is applied to the input of the next sixth flip-flop DF6, through which 6-bit shifted data is output, and the 6-bit shifted data is the seventh flip-flop DF7. 7-bit shifted data is outputted, and 8-bit shifted data is output through the next eighth flip-flop (DF8).

The 8-bit shifted data is input to the last ninth deflip-flop DF9. The ninth de-flip-flop DF9 receives a clock without passing through the inverter IVT at the falling edge of the reference clock 4 MHz. Since the operation is performed, the output of the data through this flip-flop DF9 is shifted by a half clock so that the output data of the data shifting unit 21 is 8-bit shifted data as a whole and the next data is continued.

As described above, the 8-bit shifted data is transmitted to the corresponding channel connected to the time switching unit 15.

For example, data transmitted from the system through the bus interface unit 16 is applied to the data shifting unit 21 to output 8-bit shifted data, and the 8-bit shifted data is transferred to the time switching unit 15. Transmitted to the next Doppler buffer 13 through the corresponding channel.

In addition, the data transmitted from the public switched network (PSTN) through the trunk interface unit 11 is recorded in the Doppler buffer 13, read again by the control of the board controller 14 and applied to the data shifting unit 21. do. Accordingly, the data shifting unit 21 shifts the data 8 bits by the above process, and the 8-bit shifted data is applied to the bus interface unit 16 to the corresponding channel by switching of the time switching unit 15. Will be sent to the system.

In addition, the data applied to the data shifting unit 21 may be composed of a plurality of data lines instead of a single line, and thus a plurality of shifted outputs may be obtained by combining a flip-flop as described above for each input data line. have.

That is, according to the above embodiment, the data transmitted to the public switched network through the public network matching device is shifted by a predetermined value through the data shifting unit, thereby preventing damage to the transmitted data.

In addition, this invention is not limited to the said Example, It can variously deform and implement within the range which does not deviate from the technical summary of this invention.

As described above, according to the present invention, the time switch stabilization circuit of the public network matching device can be realized in a satellite communication system that can prevent data corruption in data transmission through the public network matching device combined with the public switched network.

Claims (3)

Trunk interface unit for transmitting and receiving data from the public switched network, A frame adjusting unit for extracting data received through the trunk interface unit and adjusting data transmitted to the public switching network to a contracted frame format; A Doppler buffer connected to the frame adjusting unit to compensate for the Doppler effect on the received data; A bus interface unit for supplying a reference clock of the system and providing an interface of an MPH bus and an UPH bus for input and output of data transmitted and received; A data shifting unit connected between the Doppler buffer and a bus interface unit to shift data transmitted and received by a predetermined bit; A time switching unit which is connected to the data shifting unit and transmits the shifted transmission data and the reception data for each channel, and then transmits the transmission data to the Doppler buffer and the reception data to the bus interface unit; And a board controller for controlling the data shifting unit and the entire device to perform data transmission and reception based on a reference clock supplied from the bus interface. The method of claim 1, The data shifting unit is composed of nine flip-flops that are sequentially coupled, and the clock inputs of eight other dip-flops except for the flip-flop of the output terminal are input through an inverter. Time switch stabilization circuit. The method of claim 2, The data shifting unit is a time switch stabilization circuit of the public network matching device in the satellite communication system, characterized in that provided with a plurality of the sequential coupled nine flip-flops.

Images