CN104092571B

CN104092571B - A kind of satellite network remote auto configuration system and method based on the Big Dipper

Info

Publication number: CN104092571B
Application number: CN201410322185.8A
Authority: CN
Inventors: 明园; 宋宇; 汤万刚; 郁冬
Original assignee: CHENGDU CORPRO TECHNOLOGY Co Ltd
Current assignee: Chengdu Orieange Temoray Co Ltd
Priority date: 2014-07-08
Filing date: 2014-07-08
Publication date: 2017-12-05
Anticipated expiration: 2034-07-08
Also published as: CN104092571A

Abstract

The invention discloses a kind of satellite network remote auto based on the Big Dipper to configure system and method, it includes configuration end and one or more is configured to hold, configuration end is connected by local interface with Beidou communication terminal A, Beidou communication terminal A is connected by satellite link with Beidou communication satellite, it is configured end to be connected with Beidou communication terminal B by local interface, Beidou communication terminal B is connected by satellite link with Beidou communication satellite.The present invention utilizes the advantage of the Big Dipper, the Big Dipper is organically fused in satellite communication system, by remote control, allows system before communication link foundation, cumbersome parameter configuration task is automatically and accurately completed, greatly reduces the technical difficulty and cost of the operation and maintenance of each remote station.

Description

Beidou-based satellite network remote automatic configuration system and method

Technical Field

The invention relates to the technical field of satellite communication, in particular to a Beidou-based satellite network remote automatic configuration system and method.

Background

The Beidou satellite system is a satellite system with completely independent intellectual property rights in China, all equipment of the system is localized, and both the equipment supply and the system operation are completely dominated by domestic policies. The system is provided with

The system has the advantages of high bidirectional information transmission speed, strong system concurrency capability, rain attenuation resistance, interference resistance, information confidentiality, small terminal equipment volume, low terminal equipment power consumption, no blind area (continent and most Asia-Pacific regions) covered by the system, perfect communication receipt system, simple installation and maintenance of the field remote station and convenient modification of remote station parameters.

Satellite communication is radio communication between earth stations or between spacecrafts and earth stations by utilizing communication satellites to transmit signals, and mainly comprises four fields of satellite fixed communication, satellite mobile communication, satellite direct broadcasting and satellite relay communication. Satellite communication is an important achievement of modern communication technology and also an important field of aerospace technology application. It has the advantages of large coverage, wide frequency band, large capacity, suitability for various services, stable and reliable performance, flexibility, no limitation of geographical conditions, irrelevant cost and communication distance, and the like. It has been widely used in international communication, domestic communication, national defense communication, mobile communication, broadcast television and other fields for over forty years.

At present, in the satellite communication field of China, a space segment has dozens of static communication satellites for providing services in orbit, and a ground segment has a large number of C-band large and medium-sized earth stations, Ku-band earth stations, various vehicle-mounted mobile stations and extremely many VSAT subscriber stations distributed in various regions in the country. China satellite application covers various industries such as military, public security, bank, petroleum, water conservancy, electric power, traffic, aerospace, sanitation, railways and the like, and the requirements of various satellite communication users in China are well met.

In the satellite communication process, firstly, the satellite network parameters of each communication station are configured to establish a satellite communication channel. At present, the methods for configuring the satellite network parameters in China mainly comprise manual configuration, software platform configuration, network management system configuration and the like.

The manual parameter configuration method has high requirement on the professional performance of operators, low accuracy of parameter configuration and complicated steps; the software platform parameter configuration method has higher requirements on the professional performance of operators and has no remote configuration way; the method for configuring the parameters of the network management system can remotely configure the parameters, but cannot complete the parameter configuration before the satellite link is established.

Disclosure of Invention

The invention aims to overcome the defects of the prior art, provides a Beidou-based satellite network remote automatic configuration system and method, and overcomes the defects that the requirement on the professional performance of manual configuration is high, the accuracy is low, the configuration is complicated, a software platform configuration does not have a remote configuration way, and the configuration of a network management system cannot complete parameter configuration work before a satellite link is established.

The purpose of the invention is realized by the following technical scheme: the utility model provides a long-range automatic configuration system of satellite network based on big dipper, it is held and one or more are disposed the end including disposing, and the configuration end is connected with big dipper communication terminal A through local interface, and big dipper communication terminal A passes through the satellite link and is connected with big dipper communication satellite, is disposed the end and passes through local interface and be connected with big dipper communication terminal B, and big dipper communication terminal B passes through the satellite link and is connected with big dipper communication satellite.

The local interface is a serial communication interface.

A Beidou-based satellite network remote automatic configuration method comprises the following steps:

s1: the configuration end is connected with the Beidou communication terminal A, and converts satellite network parameters to be configured into a short message format according to a preset communication protocol and sends the short message format to the Beidou communication terminal A; receiving receipt information transmitted by the Beidou communication terminal A;

s2: the Beidou communication terminal A sends a satellite network configuration parameter short message to the Beidou communication terminal B through a Beidou communication satellite in a short message mode; receiving receipt information sent by the Beidou communication terminal B;

s3: the Beidou communication terminal B is used for receiving the satellite network parameter configuration short message sent by the Beidou communication terminal A and sending the short message to a configured end; sending the receipt information of the configured end to the Beidou communication terminal A;

s4: the configured end is connected with the Beidou communication terminal B, receives the satellite network parameter configuration short message transmitted by the Beidou communication terminal B, analyzes the configuration parameter according to a communication protocol established in advance, automatically configures the corresponding satellite network parameter of the local end, converts the configuration result into a short message format and transmits the short message format to the Beidou communication terminal B.

The communication protocol comprises an instruction type, a content length, a target number, a configuration parameter, a receipt mark and a checksum, wherein the instruction type comprises a configuration bandwidth, a configuration frequency point and a configured network type; the content length refers to the length of the content from the byte including the byte to the checksum, and the unit is bit; the target number refers to the number of the configured station; the configuration parameters refer to corresponding parameter descriptions; the receipt flag is '0' or '1', '0' indicating that the configured end is not required to send the receipt information, and '1' indicating that the configured end is required to send the receipt information; the checksum refers to a checksum from the command type to all communication content prior to the checksum.

The invention has the beneficial effects that: by utilizing the advantages of the big dipper, the big dipper is organically integrated into a satellite communication system, and the system automatically and accurately completes a fussy parameter configuration task before a communication link is established through remote control, so that the technical difficulty and the cost of operation and maintenance of each remote station are greatly reduced.

Drawings

FIG. 1 is a block diagram of the system architecture of the present invention;

FIG. 2 is a flow chart of a remote auto-configuration of a satellite network;

FIG. 3 is a block diagram of the system of embodiment 1 of the present invention;

fig. 4 is a block diagram of the system structure of embodiment 2 of the present invention.

Detailed Description

The technical solutions of the present invention are further described in detail below with reference to the accompanying drawings, but the scope of the present invention is not limited to the following.

As shown in figure 1, a long-range automatic configuration system of satellite network based on big dipper, it is including configuration end and one or more by the configuration end, the configuration end is connected with big dipper communication terminal A through local interface, big dipper communication terminal A passes through the satellite link and is connected with big dipper communication satellite, is connected with big dipper communication terminal B through local interface by the configuration end, big dipper communication terminal B passes through the satellite link and is connected with big dipper communication satellite.

The local interface is a serial communication interface.

As shown in fig. 2, a Beidou-based satellite network remote automatic configuration method includes the following steps:

The following examples illustrate specific embodiments of the present invention.

As shown in fig. 3, in embodiment 1, the configuration end is a satellite main station, and the configuration end is a satellite small station.

The satellite master station encodes the satellite network configuration parameters according to a communication protocol established in advance according to specific configuration requirements and sends the encoded satellite network configuration parameters to the Beidou communication terminal A through a serial port;

the Beidou communication terminal A sends the satellite network configuration parameters to a Beidou communication terminal B deployed in a satellite small station through a Beidou communication satellite in a Beidou short message mode to complete the transmission of the satellite network configuration parameters;

the Beidou communication terminal B receives a Beidou short message sent by the Beidou communication terminal A deployed in the satellite main station and then sends the Beidou short message to the satellite small station through a serial port;

a data processing unit in the satellite small station decodes the Beidou short message sent by the Beidou communication terminal B according to a communication protocol established in advance to obtain satellite network configuration parameters;

the satellite small station automatically configures corresponding parameters of a local terminal according to the satellite network configuration information, determines whether to respond to the receipt according to the receipt mark, and codes a configuration result and sends the configuration result to the Beidou communication terminal B through a serial port if the receipt mark is '1';

and the Beidou communication terminal B sends a configuration result to the Beidou communication terminal A through the Beidou communication satellite in a Beidou short message mode, and then feeds the configuration result back to the satellite master station.

As shown in fig. 4, in embodiment 2, the configuration end is a satellite master station, the configured end is a plurality of satellite substations, and the beidou communication terminal of the configuration end is a beidou director.

The satellite master station encodes specific satellite network configuration parameters according to specific communication requirements and a preset communication protocol, and transmits the encoded specific satellite network configuration parameters to the Beidou commander through a serial port;

the Beidou commanding machine sends the satellite network configuration parameters to Beidou communication terminals deployed at each satellite substation through a Beidou communication satellite in a broadcast mode to complete the transmission of the satellite network configuration parameters;

each Beidou communication terminal receives broadcast information sent by a Beidou command machine deployed in a satellite main station and then sends the broadcast information to a corresponding satellite small station through a serial port;

the data processing unit in each satellite small station analyzes the broadcast information sent by the corresponding Beidou communication terminal according to a preset communication protocol to obtain the satellite network configuration parameter information of the local terminal;

each satellite small station automatically configures corresponding parameters of each end according to the satellite network configuration information, determines whether to respond to the receipt according to the receipt mark, and codes a configuration result and sends the configuration result to a corresponding Beidou communication terminal through a serial port if the receipt mark is '1';

each Beidou communication terminal sends a configuration result to the Beidou commander through the Beidou communication satellite in a Beidou short message mode, and then feeds the configuration result back to the satellite master station.

Claims

1. A remote automatic configuration method based on a Beidou satellite network remote configuration system is characterized by comprising the following steps: the system comprises a configuration end and one or more configured ends, wherein the configuration end is connected with a Beidou communication terminal A through a local interface, the Beidou communication terminal A is connected with a Beidou communication satellite through a satellite link, the configured end is connected with a Beidou communication terminal B through a local interface, and the Beidou communication terminal B is connected with the Beidou communication satellite through a satellite link; the method comprises the following steps:

2. The remote automatic configuration method based on the Beidou satellite network remote configuration system according to claim 1, characterized in that: the local interface is a serial communication interface.

3. The remote automatic configuration method based on the Beidou satellite network remote configuration system according to claim 1, characterized in that: the communication protocol comprises an instruction type, a content length, a target number, a configuration parameter, a receipt mark and a checksum; wherein,

the instruction type comprises a configuration bandwidth, a configuration frequency point and a configured network type; the content length is the length of the content from the byte including the byte to the checksum, and the unit is bit;

the target number is the number of the configured station;

configuring parameters as corresponding parameter descriptions;

the receipt flag is '0' or '1', '0' indicating that the configured end is not required to send the receipt information, and '1' indicating that the configured end is required to send the receipt information;

the checksum is the checksum from the instruction type to all the communication content prior to the checksum.