Computer Science

Computer Science ›› 2021, Vol. 48 ›› Issue (11A): 446-451.doi: 10.11896/jsjkx.201200209

• Network & Communication • Previous Articles     Next Articles

Real Time Wireless Connection Scheme for Multi-nodes

QIAN Guang-ming, YI Chao   

  1. College of Information Science and Engineering,Hunan Normal University,Changsha 410081,China
  • Online:2021-11-10 Published:2021-11-12
  • About author:QIAN Guang-ming,born in 1963,professo.His main research interests include wireless networks for embedded and real-time systems,etc.
    YI Chao,born in 1995,graduate student.His main research interests include real-time wireless network.

PDF (PC)

535

Abstract: A wireless connection scheme,named six synchronous successive transmission (SSST),is presented.The network using this scheme is called SSST network.It is mainly used for the real time radio scenario where multiple slave nodes request to send data to a master node.It has the same working frequency band with the Bluetooh.Based on SSST,slave nodes are allowed to send data transmission requests after synchronous packets are received from the master only.Slaves send their requests in an arranged way.The master transmits six synchronous packets continuously,each of which has a different index.The SSST protocol is collision free when multiple slaves require connecting the master simultaneously.The slave with the higher priority can be selected to access the network first,and the response time of each consecutive stage is easy to predict.All these are just the important features that real-time applications should have.The related theories are demonstrated and verified with experiments,and compared with the advertising and scanning of the Bluetooth.

Key words: Master node, Priority, Real time wireless network, Six synchronous successive transmission, Slave node, Slot

CLC Number: 

  • TP316.2
[1]CHIH-LIN I,SHUANGFENG H,SEN B.Energy-efficient 5G for a greener future[J].Nature Electronics,2020,3(4):182-184.
[2]HART Field Communication Protocol Specification,Revision 7.7[OL].https://www.fieldcommgroup.org.
[3]Wireless Systems for Industrial Automation:Process Control and Related Applications[S].ISA-100.11a-2009 Standard,2009.
[4]IEEE Standard for Low-Rate Wireless Personal Area Networks(LRWPANs) [S].IEEE Std 802.15.4-2015 (Revision of IEEE Std 802.15.4-2011),April 2016.
[5]COSTA R,LAU J,PORTUGAL P,et al. Handling Real-Time Communication in Infrastructured IEEE 802.11 Wireless Networks:The RT-WiFi Approach[J].Journal of Communications and Networks,2019,21(3):319-334.
[6]IEEE Standard for Low-Rate Wireless Personal Area Networks (LR-WPANs)[S].IEEE Std 802.15.4-2006,2006.
[7]Bluetooth Core Specification Version 4.2[OL].https://www.bluetooth.com/specifications.
[8]Bluetooth Core Specification Version:5.2[OL].https://www.bluetooth.com/specifications.
[9]KARALIS A,ZORBAS D,DOULIGERIS C.Collision-Free Advertisement Scheduling for IEEE 802.15.4-TSCH Networks[J].Sensors,2019,19(8):1-22.
[10]ZORBAS D,PAPADOPOULOS G Z,DOULIGERIS C.Local or Global Radio Channel Blacklisting for IEEE 802.15.4-TSCH Networks? [C]//IEEE International Conference on Communications.IEEE,2018:1-6.
[11]LEENTVAAR K,FLINT J.The capture effect in FM receivers[J].IEEE Transactions on Communications,1976,24(5):531-539.
[12]FERRARI F,ZIMMERLING M,THIELE L,et al.Efficientnetwork flooding and time synchronization with glossy [C]//Proceedings of the 10th ACM/IEEE International Conference on Information Processing in Sensor Networks.IEEE,2011:73-84.
[13]ZIMMERLING M,MOTTOLA L,KUMAR P,et al.Adaptive real-time communication for wireless cyber-physical systems[J].ACM Transactions on Cyber-Physical Systems,2017,1(2):8:1-29.
[14]BOR M,VIDLER J E,ROEDIG U.Lora for the Internet ofThings [C]//Proceedings of the 2016 International Conference on Embedded Wireless Systems and Networks.TU Graz,2016:361-366.
[15]STM32F103xC STM32F103xD STM32F103xE Datasheet production data[OL].https://www.st.com.
[16]nRF24L01+Single Chip 2.4GHz Transceiver Product Specification v1.0[OL].https://infocenter.nordicsemi.com.
[17]nRF52840 Product Specification v1.1[OL].https://infocenter.nordicsemi.com.
[1] GUO Peng-jun, ZHANG Jing-zhou, YANG Yuan-fan, YANG Shen-xiang. Study on Wireless Communication Network Architecture and Access Control Algorithm in Aircraft [J]. Computer Science, 2022, 49(9): 268-274.
[2] ZHANG Jia-neng, LI Hui, WU Hao-lin, WANG Zhuang. Exploration and Exploitation Balanced Experience Replay [J]. Computer Science, 2022, 49(5): 179-185.
[3] SHEN Hao-xi, NIU Bao-ning. Gating Mechanism for Real-time Network I/O Requests Based on Para-virtualization Virtio Framework [J]. Computer Science, 2022, 49(2): 368-376.
[4] ZHANG Yi-wen, LIN Ming-wei. Devices Low Energy Consumption Scheduling Algorithm Based on Dynamic Priority [J]. Computer Science, 2021, 48(11A): 471-475.
[5] ZHANG Yu-shuai, ZHAO Huan, LI Bo. Semantic Slot Filling Based on BERT and BiLSTM [J]. Computer Science, 2021, 48(1): 247-252.
[6] XIA Chun-yan, WANG Xing-ya, ZHANG Yan. Test Case Prioritization Based on Multi-objective Optimization [J]. Computer Science, 2020, 47(6): 38-43.
[7] TAO Yang,JI Rui-juan,YANG Li,WANG Jin. Study on Dynamic Priority Admission Control Algorithm in Heterogeneous Wireless Networks [J]. Computer Science, 2020, 47(3): 242-247.
[8] LIU Zhi, CAO Shi-peng, SHEN Yang, YANG Xi. Signal Control of Single Intersection Based on Improved Deep Reinforcement Learning Method [J]. Computer Science, 2020, 47(12): 226-232.
[9] ZHAI Yong, LIU Jin, LIU Lei, CHEN Jie. Analysis of Private Cloud Resource Allocation Management Based on Game Theory in Spatial Data Center [J]. Computer Science, 2020, 47(11A): 373-379.
[10] XUE Ling-ling, FAN Xiu-mei. Cognitive Spectrum Allocation Mechanism in Internet of Vehicles Based on Clustering Structure [J]. Computer Science, 2019, 46(9): 143-149.
[11] XU Yong, ZHANG Xiao-rong, ZHU Yu-jun. High Speed Joining Scheme Based on Channel Evaluation for IEEE 802.15.4e TSCH [J]. Computer Science, 2019, 46(6A): 332-335.
[12] LIU Jing-fa, LI Fan, JIANG Sheng-yi. Focused Annealing Crawler Algorithm for Rainstorm Disasters Based on Comprehensive Priority and Host Information [J]. Computer Science, 2019, 46(2): 215-222.
[13] ZHANG Na, XU Hai-xia, BAO Xiao-an, XU Lu, WU Biao. Multi-objective Test Case Prioritization Method Combined with Dynamic Reduction [J]. Computer Science, 2019, 46(12): 208-212.
[14] JI Yi, JIA Jun-cheng, SHENG Kai. Time Slot Optimization for Channel Hopping in CRN [J]. Computer Science, 2019, 46(11): 58-64.
[15] DU Yan-ming, XIAO Jian-hua. Workflow Scheduling Strategy with Multi-QoS Constraint Based on Priority in Cloud Environment [J]. Computer Science, 2019, 46(10): 128-134.
Viewed
Full text


Abstract

Cited
  Shared   
  Discussed   
No Suggested Reading articles found!
渝ICP备16013121号-4
Add:18# Honghu West Rd., Yubei ,Chongqing,China    Post Code: 401121
Tel: 023-63500828/023-67039612/023-67039623
E-mail: jsjkx12@163.com
Powered by Beijing Magtech Co., Ltd.