KR100221845B1 - Parameter update apparatus of channel modem - Google Patents

Abstract

In the present invention, in updating a parameter related to the operation of a channel modem in a satellite communication system, a satellite capable of updating a parameter without affecting the call state of a subscriber currently executing a call through the satellite communication system. A parameter updating apparatus for a channel modem for a communication system, the channel modem for a satellite communication system configured to set a plurality of operation modes and to allocate a transmission / reception frequency according to input control data, wherein the operation mode setting and transmission / reception frequency are performed. Parameter storage means for storing the parameter data associated with the assignment, data storage means for temporarily storing the input parameter updater, and storing the data when the channel modem is set to the idle mode by determining the current operation mode of the channel modem. Stored in Sudan On the basis of the parameter data, characterized in that configured to include a control means for updating the registered parameter storing means.

Description

Parameter update device of channel modem for satellite communication system

The present invention relates to a channel modem for a satellite communication system. In particular, in updating a parameter related to the operation of the channel modem, the present invention relates to a channel modem without affecting the call state of a subscriber currently executing a call through the satellite communication system. The present invention relates to a parameter updating device of a channel modem for a satellite communication system.

Recently, with the rapid development of communication technology, satellite communication, which enables subscribers located at remote sites to perform mutual communication through satellites, has become increasingly common.

1 is a block diagram showing the overall system configuration of a general satellite communication system.

In Fig. 1, reference numeral 1 is a satellite having a plurality of communication channels, 2 is a central control station for controlling the entire satellite communication system, and 3 (3A, 3B) is an exchanger (11A, 11B) or a telephone (12A, 12B). And interface functions for terminals such as data terminals 13A and 13B and facsimile 14A and 14B, such as a computer, and communication between the various terminals through data transmission and reception with the central control station 2. It provides a base station.

In FIG. 1, reference numeral S denotes a service channel for transmitting and receiving control data, and T denotes a traffic channel for transmitting and receiving data or voice.

That is, in the satellite communication system, the central control station 2 first generates packet data for inquiring the status of each base station 3, and transmits the packet data to each base station 3 through the service channel S. And the polling operation of determining the state of each base station 3 based on the state data transmitted from each base station 3 with respect to the packet data.

And, if there is a call request for the subscriber coupled to the other base station 3 from the predetermined base station 3 during the polling operation, the state of the call request base station is determined based on the state information obtained in the polling operation. If a call is possible, the traffic channels are allocated to both base stations 3 so that subscribers connected to both base stations 3 can perform mutual communication.

On the other hand, in the satellite communication system described above, since the central control station 2 and each base station 3 are located at remote locations, software or various operations of the apparatus used in the base station 3 or the central control station 2 are performed. There is a big inconvenience when updating parameters.

Therefore, in the satellite communication system, in general, the base station 3 located at a remote location is reconfigured through a method of transmitting software or parameters to be updated from the central control station 2 to each base station 3.

2 shows the configuration of a ground apparatus (central control station or base station) of a satellite communication system currently commercially available.

In FIG. 2, reference numeral 21 denotes an antenna for transmitting and receiving an uplink signal and a downlink signal with respect to the satellite 1, and 22 denotes an input / output signal by separating signals transmitted and received through the antenna 21 using a polarization property of frequency. Orthogonal mode converter, 23 is a low noise amplifier for low noise amplification of the 12.25 to 12.75 GkHz downlink frequency signal input through the orthogonal mode converter 22, 24 is a frequency signal applied through the low noise amplifier 23 For example, the frequency down converter for converting an intermediate frequency signal IF of 70 MHz, 25 separates and outputs the intermediate frequency signal IF applied from the frequency down converter 24 into a plurality of intermediate frequency signals. And an intermediate frequency combination / distribution unit for combining and outputting the intermediate frequency signals applied from the channel modems 28:28 _{1 to} 28n to be described later.

In the drawing, reference numeral 26 denotes a telephone data card for connecting terminals such as a telephone 12, a data terminal 13, a facsimile 14, or the like as shown in FIG. Trunk Interface Port for connecting to other exchanges.

In the figure, reference numerals 28 (28 _{1 to} 28n) demodulate and decode frequency signals from other base stations or central stations input through the intermediate frequency combination / distributor 25 described above, and the trunk interface port 27 The outgoing signal from the exchange inputted through the switch or the outgoing signal from the terminal inputted from the telephone data card 26 is a channel modem which is encoded, modulated and output.

In the drawing, reference numeral 29 denotes a frequency up-converter for generating an uplink frequency signal by converting an intermediate frequency signal of 70 MHz from the intermediate frequency combination / distributor 25 into a frequency of 14.0 to 14.5 GHz, for example. 30 is a high output amplifier for amplifying the uplink frequency signal output from the frequency up-converter 29.

In the drawing, reference numeral 31 denotes a network control unit that provides a communication function to a satellite communication subscriber through communication with another base station (or a central station) and performs a parameter updater function for the channel modem 28. .

FIG. 3 is a block diagram showing the configuration of the network control unit 31. The processor 311 controls the entire system of the central control station 2 or the base station 3, and the channel modem 28 in FIG. A service channel controller (SCC: Service Channel Controller) 312 for extracting and generating a message of a time division multiplex (TDM) stream and a S-ALOHA message transmitted and received through the processor 311 and the service channel controller 312 Dual port RAM 313 for data transmission and reception between the two, a program memory 315 that stores a predetermined operating program for the processor 311, and a data memory 314 that stores a variety of data related to the operation of the device ) Is configured to include.

However, the network control unit 31 distinguishes the control operation depending on whether the corresponding device is installed in the central control station 2 or in the base station 3.

That is, the network control unit installed in the central control station 2 controls the polling function for each base station, and executes call control based on the data obtained in the polling process, and a network management system (not shown). The control operation for the central control station 2 and the entire satellite communication system is executed in accordance with the control data applied from the system.

In addition, the network control unit provided in the base station 3 transmits the status information of the base station in response to the status inquiry message from the central control station 2, and also responds to the call control of the central control station 2. Assignment control of is executed.

Next, the parameter update operation for the channel modem 28 in the above configuration will be described.

First, in the central control station 2, when the system administrator outputs parameter update command data and parameter data to be updated to the network control unit 31 through the network management system, the network control unit 31 outputs the inputted parameter data. It is stored in the memory 314.

Then, when a system reset operation is executed by a system administrator operating a reset switch (not shown) or the like, the processor 311 transmits the parameter data stored in the data memory 314 to a service channel controller ( 312) and UPH 32 transmit all channel modems 28 to each channel modem 28 to update all channel modems 28 with new parameters.

On the other hand, when the system manager outputs parameter update command and update data for a specific base station by using the network management system installed in the central control station 2, the processor 311 of the central control station 2 receives the corresponding control command. And the data is transmitted to the service channel controller 312 through the dual port RAM 313, and the service channel controller 312 generates a message of a predetermined TDM stream based on the input data to generate a UPH 32 message. Will output via

As described above, the TDM message output from the network controller 31 includes a predetermined channel modem 28, an intermediate frequency combination / distributor 25, a frequency up-converter 29, a high power amplifier 30, and an orthogonal mode. It is output through the transducer 22 and the antenna 21.

On the other hand, in the base station 3, when the TDM message transmitted from the central control station 2 is received through the antenna 21, the message is transmitted to the quadrature mode converter 22, the low noise amplifier 23, and the frequency down converter ( 24, the intermediate frequency combination / distributor 25 and the predetermined channel modem 28 are applied to the network control unit 31, the network control unit 31 receives the update data applied from the service channel controller 312 The data is stored in the data memory 314.

Also in this case, when a system reset is executed by a system administrator operating a reset switch or the like, the processor 311 transmits data stored in the data memory 314 to all channel modems (UPHs 32). 28) to execute the update operation for each channel modem 28.

Therefore, in the above configuration, the network manager existing in the central control station 2 can load parameter data for the entire satellite communication system through the network management system, thereby making the system easy to maintain.

However, in the above-described satellite communication system, in updating the parameter data stored in the data memory 314 of the network controller 31 with respect to the channel modem 28, the system is reset. If set, the service function of the base station 3 or the central control station 2 is lost at the time of system reset.

Accordingly, a problem occurs that the call state is abruptly interrupted in the case of the subscriber who is conducting the call at the moment of system reset.

Accordingly, the present invention has been made in view of the above circumstances, and provides a parameter update apparatus for a channel modem for a satellite communication system capable of executing a parameter update for a channel modem without affecting a call state of a satellite communication subscriber. The purpose is.

1 is a system configuration diagram showing a configuration of a satellite communication system to which the present invention is applied.

FIG. 2 is a block diagram showing the configuration of a central control station and a base station in FIG.

3 is a block diagram showing the configuration of a network control unit in FIG.

Figure 4 is a block diagram showing a parameter updating apparatus for a channel modem for a satellite communication system according to an embodiment of the present invention.

* Brief description of the main parts of the drawing

40: network control unit, 50: channel modem,

51: voice / data processor, 52: channel unit processor,

53: transmit frequency synthesizer, 54: intermediate frequency synthesizer,

55 is a modulator, 56 is an intermediate frequency signal generator,

57: intermediate frequency signal receiver, 58: demodulator,

59: lookup table, 60: parameter storage,

61: data memory.

The parameter update apparatus of the channel modem for satellite communication system according to the present invention for realizing the above object is possible in the channel modem for satellite communication system to be able to set a plurality of operation modes and to allocate the transmission and reception frequency according to the input control data. A parameter storage means for storing parameter data related to the operation mode setting and transmission / reception frequency allocation, a data storage means for temporarily storing an input parameter updater, and a current mode of the channel modem to determine the idle mode of the channel modem. If it is set to, characterized in that it comprises a control means for updating and registering the parameter storage means based on the parameter data stored in the data storage means.

In addition, the satellite communication system parameter updating apparatus according to the second aspect of the present invention comprises a plurality of channel modems and network control means for controlling the operation mode of the channel modem, the network control means is Memory means for storing the input parameter data, characterized in that for determining the idle state of the channel modem to execute and control the parameter update operation for the channel modem set to the idle state.

According to the present invention having the above-described configuration, the update operation is executed when the channel modem is set to the idle mode. Therefore, since the parameter update operation is performed within the range not affected by the operation of the channel modem, the subscriber who is currently performing communication by the parameter update operation can prevent the damage.

Hereinafter, an embodiment according to the present invention will be described with reference to the drawings.

4 is a block diagram illustrating a parameter updating apparatus of a channel modem for a satellite communication system according to an embodiment of the present invention.

In FIG. 4, reference numeral 40 denotes a network controller for controlling the entire apparatus of the ground station (central control station, base station) as described in FIG. 3, and 50 denotes a channel modem.

In addition, reference numeral 51 in the channel modem 50 performs an interface function between the UPH bus 32 and the MPH bus 33 and the channel unit processor 52 to be described later. Speech and Data Processor (hereinafter referred to as SDP) for processing voice and data, 52 is a channel unit processor (hereinafter referred to as CUP) that controls the overall configuration of the channel modem 50, 53 is this channel A transmission frequency synthesizer for synthesizing and outputting a predetermined frequency signal for generating an intermediate frequency signal according to the control data from the unit processor 52, for example, a frequency signal of 112.512 MHz ± 20 MHz, 54 is the channel unit processor 52. Receiving frequency adder for synthesizing and outputting a predetermined frequency signal for receiving an intermediate frequency signal, for example, 112.384 MHz ± 20 MHz according to control data from The.

In the drawing, reference numeral 55 denotes a modulator for outputting a 512 kHz modulated signal by BPSK or QPSK modulation on the I and Q channel data output from the SDP 51, and 56 is output from the modulator 55. Generating an intermediate frequency signal of 70 MHz ± 20 MHz based on a 512 kHz modulation signal and a frequency of 112.512 MHz ± 20 MHz and a reference frequency of 42 MHz applied from the transmission frequency synthesizer 53 It is wealth.

In the figure, reference numeral 57 denotes 384 kHz modulation based on the received 70 MHz ± 20 MHz intermediate frequency signal, the frequency of 112.384 MHz ± 20 MHz and the reference frequency of 42 MHz applied from the receiving frequency synthesizer 54. An intermediate frequency signal receiving unit for outputting a signal, and 58 is a demodulating unit for demodulating and outputting I and Q channel data from a 384 kHz modulation signal applied by the intermediate frequency signal receiving unit 57.

In the drawing, reference numeral 59 denotes a look-up table in which frequency data for each frequency ID is stored, 61 denotes a data memory in which various data, particularly updated parameters, are stored. Is a parameter storage unit that stores various operation data (parameters) related to this channel modem.

In the above configuration, in the normal operation state, the CUP 52 controls the SDP 51 according to the control data applied from the network control unit 40 to execute the operation mode control of the corresponding channel modem.

Here, the operation mode of the channel modem 50 is a traffic channel mode (VOX, CTCR) for transmitting and receiving voice or data through the corresponding channel modem, and a service channel mode for transmitting and receiving control data with a base station or a central station ( STTR, TTSR), No Transmission TDM Receive (NTTR) mode for receiving messages of TDM streams only, No Transmission S-ALOH Receive (NTSR) mode for receiving S-ALOH packet data, and Idle mode There are seven modes of the CUP 52. When the predetermined mode control data is input from the network controller 40, the CUP 52 controls the SDP 51 to set the channel modem to the corresponding operation mode.

In addition, in the operation mode other than the traffic channel mode in the operation mode, the intermediate frequency value is set in advance, and the corresponding frequency value is stored in the parameter storage unit 60 as the frequency ID value. When the channel modem is set to the predetermined operation mode, the SCU 52 reads out the channel ID corresponding to the operation mode from the parameter storage unit 60 and then looks up the table 59 based on the channel ID. Is then retrieved to obtain predetermined frequency data.

Then, the frequency data transmitted and received are transmitted to the transmission frequency synthesizer 53 and the reception frequency synthesizer 54 to set the frequency signals transmitted and received.

Further, when the channel modem is set to the traffic channel mode, predetermined frequency data is obtained by searching the lookup table 59 based on the frequency ID applied from the network controller 40. The frequency data is then used as a transmission frequency synthesizer. By transmitting to 53 and the receiving frequency synthesizer 54, a frequency signal transmitted and received is set.

On the other hand, if the update data is input from the network management system or the central control station together with the parameter update command in the above operating state, the network control unit 40 first stores it in the data memory 314 shown in FIG. .

When the reception of the update data is completed, the update data is applied to the CUP 52 of the channel modem 50 through the UPH bus 32.

Meanwhile, when the parameter update command and the update data are applied from the network controller 40, the CUP 52 first stores the parameter update command and the update data in the data memory 61. When the parameter data is finished, the current channel modem 50 is stored. The operation mode of is determined.

When the operation mode of the current channel modem 50 is the idle mode, the update operation is executed by updating and registering the parameter storage unit 60 based on the update data stored in the data memory 61. If the mode is set to another operation mode, the current mode operation is executed without executing the parameter update operation.

Subsequently, when the operation mode ends and the control data for setting the idle mode is received from the network controller 40, the CUP 52 first controls the SDP 51 to change the operation mode of the channel modem 50 to the idle mode. After setting to, the parameter update operation is executed by updating and registering the parameter storage unit 60 based on the update data stored in the data memory 61.

That is, in the above embodiment, when parameter update data is input, the network control unit 40 immediately transmits the input parameter data to each channel modem. In the channel modem, the input parameter data is first stored in the data memory 61, and the update operation is executed when the corresponding channel modem is set to the idle mode.

Therefore, in the above embodiment, since the parameter update operation is executed within the range not affected by the operation of the channel modem, the subscriber who is currently performing communication by the parameter update operation can prevent the damage. .

In addition, the present invention is not limited to the above embodiments, and various modifications can be made without departing from the technical scope of the present invention.

That is, for example, in the above embodiment, the network control unit 40 sends the input parameter data to each channel modem 50, and the channel modem 50 determines that each of them is set to the idle mode. Although it is configured to execute the update, the network controller 40 stores the input parameter data and transmits the parameter data to the channel modem 50 set to the idle mode. It can also be configured to execute a parameter update immediately upon entry of a parameter update command.

As described above, according to the present invention, it is possible to realize the parameter update apparatus for the channel modem for the satellite communication system, which can execute the parameter update for the channel modem without affecting the call state of the satellite communication subscriber.

Claims (2)

In the channel modem for a satellite communication system that can be set to a plurality of operating modes and to assign a transmission and reception frequency in accordance with the input control data, A parameter storage means for storing parameter data related to the operation mode setting and transmission / reception frequency allocation, a data storage means for temporarily storing an input parameter updater, and a current mode of the channel modem to determine a channel modem in an idle mode And a control means for updating and registering the parameter storing means on the basis of the parameter data stored in the data storing means when set. A satellite communication system comprising a plurality of channel modems and network control means for controlling an operation mode of the channel modem, wherein the network control means includes memory means for storing input parameter data, and an idle state of the channel modem. And executing the parameter update operation for the channel modem set to the idle state by determining the control unit.