Multi-parameter channel transmission performance evaluation method with improved TCP/IP frame structure

doi:10.11772/j.issn.1001-9081.2023111638

Journal of Computer Applications ›› 2024, Vol. 44 ›› Issue (11): 3540-3547.DOI: 10.11772/j.issn.1001-9081.2023111638

• Network and communications • Previous Articles Next Articles

Multi-parameter channel transmission performance evaluation method with improved TCP/IP frame structure

Fengtao HE, Binghui WANG(), Bin ZHANG, Yi YANG, Yibo FENG

School of Electronic Engineering，Xi'an University of Posts and Telecommunications，Xi'an Shaanxi 710121，China

Received:2023-12-01 Revised:2024-03-25 Accepted:2024-04-10 Online:2024-04-15 Published:2024-11-10
Contact: Binghui WANG
About author:HE Fengtao， born in 1974， Ph. D.， associate professor. His research interests include underwater wireless optical communication， laser high-resolution imaging， laser speckle sensing and detection.
ZHANG Bin， born in 1976， M. S.， engineer. His research interests include communication integrated circuit design， embedded system design.
YANG Yi， born in 1970， M. S.， associate professor. Her research interests include electronics and communication systems， wireless optical communication.
FENG Yibo， born in 1998， M. S. candidate. His research interests include underwater wireless optical communication.
Supported by:
Military Common Information System Technical Foundation Project(514010202-303)

改进TCP/IP帧结构的多参数信道传输性能评估方法

贺锋涛, 王炳辉(), 张斌, 杨祎, 封一博

西安邮电大学电子工程学院，西安 710121

通讯作者: 王炳辉
作者简介:贺锋涛（1974—），男，陕西西安人，副教授，博士，主要研究方向：水下无线光通信、激光高分辨成像、激光散斑传感与检测
张斌（1976—），男，新疆乌鲁木齐人，工程师，硕士，主要研究方向：通信集成电路设计、嵌入式系统设计
杨祎（1970—），女，陕西西安人，副教授，硕士，主要研究方向：电子与通信系统、无线光通信
封一博（1998—），男，陕西西安人，硕士研究生，主要研究方向：水下无线光通信。
基金资助:
全军共用信息系统技术基础项目(514010202?303)

Abstract

Abstract:

At present， the phenomenon of network densification accelerates the degradation of channel transmission performance. And the widely used evaluation methods face significant challenges in evaluating channel transmission performance due to their limited consideration of parameters and constrained applicability. In response to the difficulties in evaluating channel transmission performance， a method for evaluating multi-parameter channel transmission performance through an improved Transmission Control Protocol/Internet Protocol （TCP/IP） frame structure was proposed. Firstly， the standardized test data was generated， including pseudo-random codes， basic curve data， and custom curve data， so as to ensure that the test data follow a uniform standard. Secondly， an improved TCP/IP frame structure was employed to package test data information， including total frame quantity and frame sequences， into the TCP/IP frames. In this way， the sending， receiving and parsing of test data were realized， and the statistics on basic channel transmission variables were completed， such as the number of frames by type， the number of frames by length， the total number of frames， and the volume of effective data. Finally， the received data were analyzed to obtain two types of high-level channel transmission information， namely frame error rate and bit error rate， completing the overall evaluation of the channel transmission performance. The designed method employed six parameters to evaluate channel quality， with the evaluation precision of the method reaching 0.01% and maintaining a minimum error margin of 0.01%. It is compatible with all communication channels using TCP/IP. Experimental results demonstrate that the proposed channel transmission performance evaluation method can perform the statistics and analysis of the six channel communication information， and evaluating the channel transmission performance accurately.

Key words: Transmission Control Protocol/Internet Protocol (TCP/IP), channel quality, frame structure, frame error rate, bit error rate

摘要：

目前，网络密集化现象加剧了信道传输性能的恶化。而普遍应用的评估方法由于参数考虑有限和适用范围受限，在信道传输性能评估方面面临显著挑战。针对信道传输性能评估困难的问题，提出一种改进传输控制协议/网际协议（TCP/IP）帧结构的多参数信道传输性能评估方法。首先，生成标准化的测试数据，包括伪随机码、基本曲线数据、自定义曲线数据，以确保测试数据遵循统一标准；其次，使用改进的TCP/IP帧结构，将总帧数、帧序号等测试数据信息封装在TCP/IP帧中，并对测试数据进行收发与解析，统计不同帧类型的帧数量、不同帧长度的帧数量、总帧数和有效数据量这4种基础信道传输信息；最后，分析接收数据得到误帧率和误码率这2种高级信道传输信息，完成信道传输性能的整体评估。所设计的方法采用6种不同的参数对信道质量进行评估，方法评估的精度可达0.01%，最小误差为0.01%，且兼容所有使用TCP/IP进行通信的信道。实验结果表明，所提出的信道传输性能评估方法可以完成对6种信道通信信息的统计与分析，准确评估信道传输性能。

关键词: 传输控制协议/网际协议, 信道质量, 帧结构, 误帧率, 误码率

CLC Number:

TN913.3

Fengtao HE, Binghui WANG, Bin ZHANG, Yi YANG, Yibo FENG. Multi-parameter channel transmission performance evaluation method with improved TCP/IP frame structure[J]. Journal of Computer Applications, 2024, 44(11): 3540-3547.

贺锋涛, 王炳辉, 张斌, 杨祎, 封一博. 改进TCP/IP帧结构的多参数信道传输性能评估方法[J]. 《计算机应用》唯一官方网站, 2024, 44(11): 3540-3547.

Figures/Tables 11

Fig. 1 Channel transmission performance evaluation method

Fig. 2 Standard TCP/IP protocol frame structure

Fig. 3 OSI reference model

Fig. 4 Structure of standard IP frame header and its corresponding fundamental channel transmission information

Fig. 5 Improved TCP/IP frame structure

Fig. 6 Flow of frame error rate analysis

Fig. 7 Flow of bit error rate analysis

Fig. 8 Schematic diagram of software fault injection experimental system

Fig. 9 Test results of software fault injection experiment

Fig. 10 Schematic diagram of hardware fault injection experimental system

Fig. 11 Test results of hardware fault injection experiment

References 22

1	顾晓丹，吴文甲，凌振.用户密集环境下基于边缘智能的直播视频传输优化机制［J］.通信学报，2023，44（11）：55-66.
	GU X D， WU W J， LING Z. Live video transmission optimization mechanism based on edge intelligence in high client-density environment［J］. Journal on Communications， 2023， 44（11）： 55-66.
2	NGUYEN M T， LE L B. Adjacent channel interference cancellation for robust spectrum sharing in satellite communications systems［C］// Proceedings of the IEEE 28th Annual International Symposium on Personal， Indoor， and Mobile Radio Communications. Piscataway： IEEE， 2017：1-5.
3	YANG L， DING D， SHEN Z， et al. Parallel combinatory spread spectrum system based on single carrier frequency domain equalization in multipath fading channels［C］// Proceedings of the 8th International Conference on Communication， Image and Signal Processing. Piscataway： IEEE， 2023： 528-533.
4	SANDHYA S V， JOSHI S M. The performance evaluation and analysis of QoS metrics on routing protocols using multimedia traffic in Mobile Adhoc NETwork［C］// Proceedings of the 2022 International Conference for Advancement in Technology. Piscataway： IEEE， 2022： 1-6.
5	CHEN S， FANG W， JIA G， et al. Evaluation methods of service transmission path selection in IMT-A complex network environment［C］// Proceedings of the 6th International Conference on Intelligent Human-Machine Systems and Cybernetics. Piscataway： IEEE， 2014：346-348.
6	QUANG P M， DUY T T， BAO V N Q. Performance evaluation of radio frequency energy harvesting-aided multi-hop cooperative transmission networks［C］// Proceedings of the 25th Asia-Pacific Conference on Communications. Piscataway： IEEE， 2019：521-526.
7	ZHOU Y， WANG Y， GUI G， et al. Deep learning-based channel quality estimation in adaptive shortwave communication systems［C］// Proceedings of the 2020 International Conference on Wireless Communications and Signal Processing. Piscataway： IEEE， 2020： 363-368.
8	PANG J， XU X， ZHANG N. Demand quality evaluation of satellite mobile communication system based on cloud model［C］// Proceedings of the IEEE 5th Advanced Information Technology， Electronic and Automation Control Conference. Piscataway： IEEE， 2021： 1814-1820.
9	郑涛，蒙祖尧，张宏科.基于多信道绑定的应急终端协同方法［J］.电子学报，2022，50（11）：2645-2652.
	ZHENG T， MENG Z Y， ZHANG H K. Emergency terminals coordination method based on multi-channel bonding［J］. Acta Electronica Sinica， 2022， 50（11）： 2645-2652.
10	李宪鹏，王海斌，汪俊，等.水声多途信道的维纳误差限信道质量量化分析方法［J］.声学学报，2023，48（4）：843-857.
	LI X P， WANG H B， WANG J， et al. Quality quantitative analysis method for underwater acoustic multipath channel using Wiener error boundary［J］. Acta Acustica， 2023， 48（4）： 843-857.
11	KABAOU M O， ZOGHLAMI N， HAFIDHI I. Performance analysis and capacity evaluation of MIMO propagation channels： application to 5G radio mobile networks［C］// Proceedings of the 2023 IEEE International Conference on Advanced Systems and Emergent Technologies. Piscataway： IEEE， 2023：1-6.
12	刘煜鑫，何丹萍，单馨漪，等.基于智能射线追踪的信道计算与半实物仿真［J/OL］.电波科学学报，2023 ［2024-01-10］. .
	LIU Y X， HE D P， SHAN X Y， et al. Intelligent ray-tracing-based simulation and emulation of channels［J/OL］. Chinese Journal of Radio Science， 2023 ［2024-01-10］ .
13	姚媛媛，刘忆秋，黄赛，等.无蜂窝大规模MIMO网络下基于联邦学习的用户接入策略及能耗优化［J］.通信学报，2023，44（10）：112-123.
	YAO Y Y， LIU Y Q， HUANG S， et al. Federated learning-based user access strategy and energy consumption optimization in cell-free massive MIMO network［J］. Journal on Communications， 2023， 44（10）： 112-123.
14	BANDA-SAYCO， LAURA-CHOQUEHUANCA， ZEA-VARGAS， et al. Development of an indoor hybrid PLC/VLC/IR communication system based on TCP/IP model［C］// Proceedings of the 2020 IEEE Congreso Bienal de Argentina. Piscataway： IEEE， 2020： 1-7.
15	DMELLO A， FOO E， REID J， et al. On the enhancement of TCP/IP protocol for use in high frequency communication systems［C］// Proceedings of the 2020 Military Communications and Information Systems Conference. Piscataway： IEEE， 2020：1-7.
16	竹下隆史，村山公保，荒井透，等.图解TCP/IP［M］.5版.乌尼日其其格，译.北京：人民邮电出版社，2013：51-74.
	TAKESHITA T， MURAYAMA Y， ARAI T， et al. Mastering TCP/IP ［M］. UNURJARGAL J， translated. 5th ed. Beijing： Posts and Telecommunications Press， 2013： 51-74
17	冷峰，张翠玲，陈闻宇，等. 从Snort规则的协议信息分析攻击［J］. 计算机应用， 2022， 42（S1）：173-177.
	LENG F， ZHANG C L， CHEN W Y， et al. Attack analysis based on protocol information of Snort rules［J］. Journal of Computer Applications， 2022， 42（S1）： 173-177.
18	祝永晋，尹飞，豆龙龙，等. 基于前向纠错的自适应网络传输机制［J］. 计算机应用， 2021， 41（3）：825-832.
	ZHU Y J， YIN F， DOU L L， et al. Adaptive network transmission mechanism based on forward error correction［J］. Journal of Computer Applications， 2021， 41（3）： 825-832.
19	聂熙雅.基于TCP/IP协议的机场跑道监测系统［J］.国外电子测量技术，2021，40（2）：139-143.
	NIE X Y. Airport runway monitoring system based on TCP/IP protocol［J］. Foreign Electronic Measurement Technology， 2021， 40（2）： 139-143.
20	夏羽，廖苹秀，崔雷.数据中心中TCP连接建立过程的优化方法［J］.计算机应用，2017，37（8）：2157-2162.
	XIA Y， LIAO P X， CUI L. Optimization of the TCP connection initiating process in data centers［J］. Journal of Computer Applications， 2017， 37（8）： 2157-2162.
21	黄云婷，江南，杜承烈.一种跨平台的实时TCP/IP协议栈设计［J］.计算机工程，2014，40（9）：134-137.
	HUANG Y T， JIANG N， DU C L. A design of cross-platform real-time TCP/IP protocol stack［J］. Computer Engineering， 2014， 40（9）：134-137.
22	西安邮电大学.通信信道质量测试方法、系统、存储介质、设备及终端：202311195969.4［P］.2023-11-24.
	Xi'an University of Posts and Telecommunications. Communication channel quality testing methods， systems， storage media， equipment， and terminals： 202311195969.4［P］. 2023-11-24.

[1]	Zhi REN, Jindong GU, Yang LIU, Chunyu CHEN. High-efficiency dual-LAN Terahertz WLAN MAC protocol based on spontaneous data transmission [J]. Journal of Computer Applications, 2024, 44(2): 519-525.
[2]	Chenghao YU, Runhe QIU. Performance analysis of bit error rate on RIS assisted index modulation cooperative system [J]. Journal of Computer Applications, 2023, 43(11): 3559-3567.
[3]	LI Tong, QIU Runhe. Relay selection and performance analysis of multi-relay cooperative spatial modulation [J]. Journal of Computer Applications, 2021, 41(7): 2019-2025.
[4]	HE Lifang, CHEN Jun, ZHANG Tianqi. Correlation delay-DCSK chaotic communication scheme without inter-signal interference [J]. Journal of Computer Applications, 2019, 39(7): 2014-2018.
[5]	ZHANG Gang, HUAGN Nanfei, ZHANG Tianqi. Performance analysis of multi-user orthogonal correlation delay keying scheme [J]. Journal of Computer Applications, 2019, 39(5): 1425-1428.
[6]	DAI Cuiqin, WANG Wenhan. Multi-attribute spatial node selection algorithm based on subjective and objective weighting [J]. Journal of Computer Applications, 2018, 38(4): 1089-1094.
[7]	ABDURAHMAN Kadir, MUTALLIP Sattar, MIREGULI Aili. Asynchronous hexadecimal digital secure communication system based on shift keying of coupled hyperchaotic systems [J]. Journal of Computer Applications, 2018, 38(3): 780-785.
[8]	LIU Wenzhi, LIU Zhaobin. Energy consumption-reducing algorithm based on WiMAX networks [J]. Journal of Computer Applications, 2017, 37(7): 1866-1872.
[9]	WANG Youguo, DONG Hongcheng, LIU Jian. Using noise to improve information transmission in optimal matching array stochastic resonance system [J]. Journal of Computer Applications, 2016, 36(8): 2192-2196.
[10]	GUO Qiang, QIN Yue. Improved relay forwarding scheme based on network coding [J]. Journal of Computer Applications, 2016, 36(1): 61-65.
[11]	ZHANG Guangyu, CHEN Hong, CAI Xiaoxia. Blind source separation method for mixed digital modulation signals based on RobustICA [J]. Journal of Computer Applications, 2015, 35(8): 2129-2132.
[12]	ZHAO Hui, FANG Gaofeng, WANG Qin. Deep space data delivery strategy based on optimized LT code [J]. Journal of Computer Applications, 2015, 35(4): 925-928.
[13]	XU Yuanfei. Multi-user multi-input multi-output multi-hop relay system based on likelicooperative hood detection and sphere decoding [J]. Journal of Computer Applications, 2015, 35(10): 2848-2851.
[14]	ZHAO Yuli, GUO Li, ZHU Zhiliang, YU Hai. Design of relay node selection scheme for cooperative communication [J]. Journal of Computer Applications, 2015, 35(1): 1-4.
[15]	LIU Jing TANG Guangming. Game-theoretic model of active attack on steganographic system [J]. Journal of Computer Applications, 2014, 34(3): 720-723.

Multi-parameter channel transmission performance evaluation method with improved TCP/IP frame structure

改进TCP/IP帧结构的多参数信道传输性能评估方法

RichHTML

PDF

Knowledge

Abstract

Cite this article

share this article

Figures/Tables 11

References 22

Related Articles 15

Recommended Articles

Metrics