KR100293148B1 - Method for monitoring of wireless call data satellite transmission system - Google Patents

Abstract

PURPOSE: A method for monitoring of a wireless call data satellite transmission system is provided to monitor state information of each station within a short time by polling selectively operating stations. CONSTITUTION: A booting state of a network management portion is checked(ST21). An online database name is scanned and a current operating station is stored in a polling buffer(ST22). A standby process is performed to wait an external command(ST23). An erased operating station or an added operating station is erased or added from or to the polling buffer(ST24-ST25). Alarm information is stored into a database when the alarm information for the operating station is generated by polling the operating station(ST26-ST27). The polling process is performed until a network management portion is shut down after the alarm information is stored into the database(ST28).

Description

Terminal station monitoring method of radio call data satellite transmission system

The present invention relates to a radio call data satellite transmission system. In particular, when polling to obtain status information of each terminal station in a radio call data satellite transmission system, only the terminal station in operation is selected and polled. It's about how you can quickly monitor.

In general, a radio call data satellite transmission system (PagerSat) is a system that transmits radio call data through a satellite, and unidirectional data in which a path between terminal stations is replaced by a link using a satellite in a conventional leased line at a TDX-PS. Transmission system.

1 is a block diagram of a general radio call data satellite transmission system.

As shown therein, a Paging Central Interface Block (PCIB) 11 for converting an analog paging signal to digital by a frequency shift keying scheme (hereinafter, abbreviated as "FSK") of a switch 11. )Wow; A multiplexer (MUX) (12) for synchronizing the clocks of the channel input / output data of the subscriber matching unit 11, compensating for the deviation between the system clock and the reception clock, and multiplexing a signal of a digitally converted exchange. Wow; A modulator (MOD) 13 for modulating the multiplexed baseband signal of the multiplexer 12 and outputting the modulated baseband signal as a signal of an intermediate frequency band; The modulator 13 transmits a signal of the intermediate frequency band modulated by the high frequency signal to the satellite, and includes an attenuator, a transmitter, an antenna, a beacon receiver, an upper link power controller (UPC), and the like. A radio frequency (RF) unit 14; The subscriber matching unit 11, the multiplexing unit 12, the modulation unit 13, and the high frequency transmitter 14 are connected to perform respective control, and a network management unit (NMS; Network management system) 16 A Paging Central Control Block (PCCB) unit 15 connected to and reporting control and status; A network management unit (16) connected to the PCCB unit (15) to manage the configuration and state of the entire radio call data satellite transmission system; A demodulator (DEMOD) 17 for low noise amplifying the signal received from the satellite and converting the signal into an intermediate frequency signal and restoring the intermediate frequency signal to an original signal; A demultiplexer (DEMUX; DEMultiplexer) 18 which demultiplexes the data and the voice from the signal demodulated by the demodulator 17 into a digital signal and compensates for the deviation between the system clock and the reception clock; A Paging Remote Interface Block (PRIB) 19 for restoring digital data of the demultiplexer 18 to an FSK analog paging signal; The transmitter 20 is connected to the subscriber access unit 19 and is configured as a transmitter 20 for transmitting a restored radio call signal from the subscriber.

2 is a hardware block diagram of a network management unit in a general wireless call data satellite transmission system.

As shown therein, the workstation 21 controls the network management unit as a whole; A database 22, a floppy disk 23, and a tape driver 24 capable of backing up data processed at the workstation 21; A printer 25 for outputting the result processed by the workstation 21; The workstation 21 is configured with a modem 26 that can inform the operator with alarm information.

The software of the network management unit includes, as shown in FIG. 1, a NMS Maintencance & Control Apploication program for controlling various devices such as an antenna, a beacon receiver, a modulator 13, and the like; A system monitering control program for processing alarms generated by the various devices, a command from a graphical user interface (GUI), and an acknowledgment (ACK) are sent to the network management unit maintenance application program. Subsystem Protocol Handler program, Graphical User Interface program that provides graphical display for the operator to issue commands, Asynchronous protocol that initializes, transmits and receives asynchronous devices. An Async Device Handler program, an Async Device program that enables asynchronous communication, and an Application Database Interface program, which is an interface program configured to access the database 22. And in the 'C' language Provides an ESQL / C Run Time program that provides a library to access the database, a Database On-Line Run Time program that is a database engine that runs the database, and a library that runs the graphics. Commercial programs such as a Graphic Run Time Library; It consists of a Unix Operating System (Unix Operating System) program for operating the workstation 21.

In the conventional radio call data satellite transmission system configured as described above, the central station converts the FSK analog paging signal transmitted from the TDX (Time Division Multiplexing) -PS exchanger, which is a paging data exchanger, into a digital signal in the subscriber matching unit 11 and multiplexes the multiplexer 12. To be entered). Then, the multiplexer 12 synchronizes the clocks of the channel input / output data, compensates for the deviation between the system clock and the reception clock, and processes data and voice between the channel module and the intermachine link. The modulator 13 then bases the baseband signal (64 Kbps / 128 Kbps) input from the multiplexer 12 on the V.35 scrambling and discrete (International Telegraph and Telephone Consultative Committee). ) Modulation and R = 1/2 k = 7 convolutional coding and binary phase shift keying (hereinafter, abbreviated as "BPSK") to modulate an intermediate frequency of 52 MHz to 88 MHz (70 ± 18 MHz) IF (Intermediate Frequency) band is converted into a signal of the intermediate frequency band having a bandwidth of 250KHz / 500KHz. The high frequency transmitter 14 then inputs the intermediate frequency signal to the attenuator to be adjusted by the beacon receiver, performs the redundancy control, and transmits the signal to the outdoors. The signal transmitted to the outdoors is distributed by the outdoor power distributor and transmitted to the transmitter. do. Then, the transmitter is amplified to a predetermined uplink frequency and power level, and the signal of the outdoor transmitter selected by the waveguide switch is connected to the feeder of the antenna to emit radio waves to the satellite.

Accordingly, in the plurality of terminal stations of the radio calling satellite transmission system, low-noise amplification of the small signal of 12.25 to 12.75 GHz from the satellite is performed by the demodulator 17, and then converted into an intermediate frequency signal of 950 to 1450 MHz. The original data is restored by scrambling, discrete decoding and R = 1/2 k = 7 Viterbi decoding. The restored data is demultiplexed by the demultiplexer 18 and transferred to the subscriber access unit 19. Then, the subscriber access unit 19 restores the demultiplexed digital data from the demultiplexer 18 to the FSK analog paging signal, and transmits the radio caller through the transmitter 20 so that the user's wireless pager can receive the radio call signal.

Here, the monitoring and control operations of the central station and the terminal station are performed through the PCCB unit 15. That is, the PCCB unit 15 periodically polls all devices of the central station, stores the state as a message, reports it to the network manager 16, and distributes the commands of the network manager 16 to each device. In addition, it performs communication between the central station and the terminal station to report the terminal station status to the network management unit 16. Accordingly, the network management unit 16 manages the configuration and state of the entire radio calling data satellite transmission system, adjusting the central station multiplexer 12 components, adjusting the output frequency of the modulator 13, and transmitting the high frequency transmitter 14. The GUI provides the user with a role of controlling the central station by controlling the output, adjusting the antenna orientation angle, and controlling the terminal station by adjusting the reception channel frequency of the demodulator 17 and controlling the components of the demultiplexer 18. It worked.

4 is a flowchart illustrating a method for monitoring a terminal station in a conventional radio call data satellite transmission system.

As shown in the figure, when a polling timer is completed, a step of polling by selecting one terminal station from a polling buffer (ST11) (ST12); Selecting and polling one terminal station from the polling buffer and increasing the location pointer of the polling buffer to confirm whether the location pointer of the polling buffer indicates the end of the polling buffer (ST13); If the location pointer of the polling buffer points to the end of the polling buffer, setting the polling buffer to the first state, moving the polling buffer's location pointer to the beginning of the polling buffer, and waiting for the polling timer for polling the terminal to complete. (ST15); If the location pointer of the polling buffer does not point to the end of the polling buffer, then wait until the polling timer for polling the next station terminal is completed.

In the conventional method of monitoring the terminal station in the radio call data satellite transmission system, the radio call satellite transmission system can be configured to operate up to 240 terminal stations, the operation of the terminal station when polling each terminal station Irrespective of this, 240 terminals were sequentially polled from 1 to 240 in sequence (ST11 to ST15).

Therefore, assuming that it took 1 second to get the status information of one terminal station, it takes at least 4 minutes to get the status information of the current terminal station from the current terminal station again. That is, the conventional method takes a lot of time to determine the current state of the terminal station because it polls in order regardless of whether the terminal station is operating, there is a problem that can not determine the state of the terminal station in real time.

Accordingly, the present invention has been proposed to solve the conventional problems as described above, and an object of the present invention is to select only the terminal station in operation when polling to obtain status information of each terminal station in a radio call data satellite transmission system. The present invention provides a method for monitoring a terminal station of a radio call data satellite transmission system capable of quickly monitoring status information of a terminal station.

Terminal station monitoring method of a radio call data satellite transmission system according to the present invention to achieve the above object,

Scanning the on-line database name when the network manager is booted, and storing a currently operating terminal station in a polling buffer; Storing the currently operating terminal station in a polling buffer, waiting for an external command or information, and then adding or deleting the added or deleted terminal station to the polling buffer and polling the terminal station; Polling the terminal station, if there is alarm information for terminal station polling, storing the alarm information for terminal station polling in a database; The method comprises the step of storing the alarm information on the polling of the terminal station in a database, and then performing the terminal station polling until the network management unit is suspended.

1 is a block diagram of a general wireless data satellite transmission system;

2 is a hardware block diagram of a general network management unit;

3 is a software configuration diagram of a general network management unit,

4 is a flowchart illustrating a conventional terminal station monitoring method;

5 is a flowchart showing a terminal station monitoring method according to the present invention;

<Explanation of symbols for main parts of drawing>

11: subscriber matching unit 12: multiplexing unit

13: Modulator 14: High Frequency Transmitter

15: PCCB Part 16: Network Management Unit

17: demodulator 18: demultiplexer

19: subscriber connection 20: transmitter

21: Workstation 22: Database

23: floppy disk 24: tape driver

25: Printer 26: Modem

Hereinafter, an embodiment according to the technical concept of the terminal station monitoring method of the present invention, the wireless call data satellite transmission system configured as described above will be described in detail.

First, the configuration and operation of hardware and software of the radio call data satellite transmission system and the network management unit are the same as those described above with reference to FIGS.

5 is a flowchart illustrating a terminal station monitoring method according to the present invention.

As shown in the figure, when the network management unit 16 boots, scanning the online database name and storing the currently operating terminal station in the polling buffer (ST21) (ST22); Storing the currently operating terminal station in a polling buffer, waiting for an external command or information, and then adding or deleting the added or deleted terminal station to the polling buffer and polling the terminal station (ST23 to ST25); Polling the terminal station and if there is alarm information for terminal station polling, storing the alarm information for terminal station polling in a database (ST26-ST28); And storing the alarm information on the polling of the terminal station in a database, and then performing the terminal station polling until the network management unit 16 is shortened (ST29).

The step of adding or deleting the terminal station added or deleted to the polling buffer (ST24) (ST25) comprises: storing the newly added terminal station in the polling buffer and polling the terminal station; Polling the terminal station to maintain the number of terminal stations currently in operation and confirming the deleted terminal station; If the deleted terminal station exists, deleting the deleted terminal station from a polling buffer and polling the terminal station; Polling the terminal station to maintain the number of terminal stations currently in operation, and polling the terminal stations in order.

Operation of the terminal station monitoring method of the radio call data satellite transmission system according to the present invention configured as described above will be described in detail with reference to the accompanying drawings.

First, in a radio call data satellite transmission system, a central station of an area can operate a maximum of 240 terminal stations. Thus, the central station scans the online database name when the network management unit 16 boots (ST21). When the central station polls each terminal station to monitor each terminal station status in real time, the central station selects only the terminal stations currently operating from 240 terminal stations and stores them in the polling buffer. The selected terminal station is stored in the polling buffer to poll in order, and the result is the central station (ST22).

After waiting for an external command or information, the newly added or deleted terminal station information is stored in the polling buffer. That is, the newly added terminal station is stored in the polling buffer, and the terminal station is polled to maintain the number of terminal stations currently in operation. If the terminal station is deleted and the terminal station is deleted, the terminal station is deleted from the polling buffer and the terminal station is polled. Thus, the terminal station is polled to maintain the number of currently operating terminal stations as they are, and the terminal stations are polled in order to add / delete the newly added / deleted terminal stations from the polling buffer (ST23 to ST25).

Furthermore, if there is an alarm information for the terminal station polling by polling the terminal station, the alarm information for the terminal station polling is stored in the database. If there is no alarm information for the terminal station polling, the terminal station polling result is normal. After that, the next terminal station is polled (ST26 to ST28). Then, the alarm information for the polling of the terminal station is stored in the database, and the terminal station polling is performed until the network management unit 16 is shortened (ST29).

As such, it is possible to monitor the terminal station status information by polling only the currently operating terminal station.

As described above, the terminal station monitoring method of the radio call data satellite transmission system according to the present invention monitors the terminal station in real time by selecting and polling only the terminal station in operation, and monitors the terminal station added or deleted in real time. You will notice the effect.

Claims (2)

Scanning the online database name when the network manager is booted, and storing the currently operating terminal station in a polling buffer; Storing the currently operating terminal station in a polling buffer, waiting for an external command or information, and then adding or deleting the added or deleted terminal station to the polling buffer and polling the terminal station; Polling the terminal station, if there is alarm information for terminal station polling, storing the alarm information for terminal station polling in a database; And storing the alarm information on the polling of the terminal station in a database, and performing polling of the terminal station until the network management unit is shorted down. The method of claim 1, wherein adding or deleting the added or deleted terminal station to the polling buffer comprises: Storing the newly added terminal station in a polling buffer and polling the terminal station; Polling the terminal station to maintain the number of terminal stations currently in operation and confirming the deleted terminal station; If the deleted terminal station exists, deleting the deleted terminal station from a polling buffer and polling the terminal station; And polling the terminal station to maintain the number of terminal stations currently in operation, and polling the terminal stations in order.

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