[1]宋玲,蔡祥宝. 雷达主机与雷达伺服通信接口设计[J].计算机技术与发展,2017,27(09):197-200.
 SONG Ling,CAI Xiang-bao. Design of Communication Interface between Radar Center and Radar Servo[J].,2017,27(09):197-200.
点击复制

 雷达主机与雷达伺服通信接口设计()
分享到:

《计算机技术与发展》[ISSN:1006-6977/CN:61-1281/TN]

卷:
27
期数:
2017年09期
页码:
197-200
栏目:
应用开发研究
出版日期:
2017-09-10

文章信息/Info

Title:
 Design of Communication Interface between Radar Center and Radar Servo
文章编号:
1673-629X(2017)09-0197-04
作者:
 宋玲蔡祥宝
 南京邮电大学 电子科学与工程学院
Author(s):
 SONG LingCAI Xiang-bao
关键词:
 雷达伺服雷达主机RS-422通信协议
Keywords:
 radar servoradar centerRS-422communication protocol
分类号:
TP31
文献标志码:
A
摘要:
 
伺服控制系统是雷达系统的核心部件,具有随动性,而在恶劣环境下,伺服控制系统的通信难度显著提高,使得其设计复杂度及实现难度也相应增加,因此设计一种简单稳定且可靠性高的雷达主机与雷达伺服的通信接口就显得尤为重要.通信接口主要由相应的软硬件及通信协议组成,其通信协议采用雷达主机与雷达伺服间的控制报文和回复报文来实现,运用TI公司生产的专用控制芯片TMS320F28335充当控制器,通过串行通信方式来实现数据传输.利用C语言在Code Composer Studio(CCS)3.3平台上编写相应的程序代码进而实现了通信接口的逻辑控制与通信.该通信接口的设计对进一步提高伺服控制系统的稳定性、可靠性具有重要作用,同时也在一定程度上降低了生产成本.
Abstract:
 Servo control is the core component of the radar system which has the following characteristics. In harsh environment,the diffi-culty of communication of the servo control system is improved significantly,which makes its design complexity and realization difficulty increased. Thus it is particularly important to design a simple,stable and highly reliable communication interface between radar center and radar servo system. It consists of hardware and software and corresponding communication protocol which relies on controlling and repl-ying messages between radar center and radar servo to achieve and uses special control chip named TMS320F28335 produced by the com-pany TI to act as controllers,which transmits data through serial communication mode. By using C language on the CCS3. 3 platform to write the matching program code,it can realize the logic control and the transmitting of the interface. The design of the communication in-terface plays an important role in improving its stability and reliability,and to some extent can reduce the cost of the production.

相似文献/References:

[1]张志宏,吴庆波,邵立松,等.基于飞腾平台TOE协议栈的设计与实现[J].计算机技术与发展,2014,24(07):1.
 ZHANG Zhi-hong,WU Qing-bo,SHAO Li-song,et al. Design and Implementation of TCP/IP Offload Engine Protocol Stack Based on FT Platform[J].,2014,24(09):1.
[2]梁文快,李毅. 改进的基因表达算法对航班优化排序问题研究[J].计算机技术与发展,2014,24(07):5.
 LIANG Wen-kuai,LI Yi. Research on Optimization of Flight Scheduling Problem Based on Improved Gene Expression Algorithm[J].,2014,24(09):5.
[3]黄静,王枫,谢志新,等. EAST文档管理系统的设计与实现[J].计算机技术与发展,2014,24(07):13.
 HUANG Jing,WANG Feng,XIE Zhi-xin,et al. Design and Implementation of EAST Document Management System[J].,2014,24(09):13.
[4]侯善江[],张代远[][][]. 基于样条权函数神经网络P2P流量识别方法[J].计算机技术与发展,2014,24(07):21.
 HOU Shan-jiang[],ZHANG Dai-yuan[][][]. P2P Traffic Identification Based on Spline Weight Function Neural Network[J].,2014,24(09):21.
[5]李璨,耿国华,李康,等. 一种基于三维模型的文物碎片线图生成方法[J].计算机技术与发展,2014,24(07):25.
 LI Can,GENG Guo-hua,LI Kang,et al. A Method of Obtaining Cultural Debris’ s Line Chart Based on Three-dimensional Model[J].,2014,24(09):25.
[6]翁鹤,皮德常. 混沌RBF神经网络异常检测算法[J].计算机技术与发展,2014,24(07):29.
 WENG He,PI De-chang. Chaotic RBF Neural Network Anomaly Detection Algorithm[J].,2014,24(09):29.
[7]刘茜[],荆晓远[],李文倩[],等. 基于流形学习的正交稀疏保留投影[J].计算机技术与发展,2014,24(07):34.
 LIU Qian[],JING Xiao-yuan[,LI Wen-qian[],et al. Orthogonal Sparsity Preserving Projections Based on Manifold Learning[J].,2014,24(09):34.
[8]尚福华,李想,巩淼. 基于模糊框架-产生式知识表示及推理研究[J].计算机技术与发展,2014,24(07):38.
 SHANG Fu-hua,LI Xiang,GONG Miao. Research on Knowledge Representation and Inference Based on Fuzzy Framework-production[J].,2014,24(09):38.
[9]叶偲,李良福,肖樟树. 一种去除运动目标重影的图像镶嵌方法研究[J].计算机技术与发展,2014,24(07):43.
 YE Si,LI Liang-fu,XIAO Zhang-shu. Research of an Image Mosaic Method for Removing Ghost of Moving Targets[J].,2014,24(09):43.
[10]余松平[][],蔡志平[],吴建进[],等. GSM-R信令监测选择录音系统设计与实现[J].计算机技术与发展,2014,24(07):47.
 YU Song-ping[][],CAI Zhi-ping[] WU Jian-jin[],GU Feng-zhi[]. Design and Implementation of an Optional Voice Recording System Based on GSM-R Signaling Monitoring[J].,2014,24(09):47.

更新日期/Last Update: 2017-10-26