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Neural Computing and Applications

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07.12.2019 | Applying Artificial Intelligence to the Internet of Things

BP neural network-based ABEP performance prediction for mobile Internet of Things communication systems

verfasst von: Lingwei Xu, Jingjing Wang, Han Wang, T. Aaron Gulliver, Khoa N. Le

Erschienen in: Neural Computing and Applications | Ausgabe 20/2020

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Abstract

Wireless communications play an important role in the mobile Internet of Things (IoT). For practical mobile communication systems, N-Nakagami fading channels are a better characterization than N-Rayleigh and 2-Rayleigh fading channels. The average bit error probability (ABEP) is an important factor in the performance evaluation of mobile IoT systems. In this paper, cooperative communications is used to enhance the ABEP performance of mobile IoT systems using selection combining. To compute the ABEP, the signal-to-noise ratios (SNRs) of the direct link and end-to-end link are considered. The probability density function (PDF) of these SNRs is derived, and this is used to derive the cumulative distribution function, which is used to derive closed-form ABEP expressions. The theoretical results are confirmed by Monte-Carlo simulation. The impact of fading and other parameters on the ABEP performance is examined. These results can be used to evaluate the performance of complex environments such as mobile IoT and other communication systems. To support active complex event processing in mobile IoT, it is important to predict the ABEP performance. Thus, a back-propagation (BP) neural network-based ABEP performance prediction algorithm is proposed. We use the theoretical results to generate training data. We test the extreme learning machine (ELM), linear regression (LR), support vector machine (SVM), and BP neural network methods. Compared to LR, SVM, and ELM methods, the simulation results verify that our method can consistently achieve higher ABEP performance prediction results.

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Wang D, Chen D, Song B, Guizani N, Yu XY, Du XJ (2018) From IoT to 5G I-IoT: the next generation IoT-based intelligent algorithms and 5G technologies. IEEE Commun Mag 56(10):114–120CrossRef

Bedi G, Venayagamoorthy GK, Singh R, Brooks RR, Wang KC (2018) Review of internet of things (IoT) in electric power and energy systems. IEEE Internet of Things Journal 5(2):847–870CrossRef

Hou XM, Zhang FQ, Liu D (2017) Dynamic coordination process based on predictive graph in mobile cloud environment. J Liaocheng Univ (Nat Sci Ed) 30(4):96–100

Xu LW, Wang JJ, Zhang H, Gulliver TA (2017) Performance analysis of IAF relaying mobile D2D cooperative networks. J Frankl Inst 354(2):902–916MATHCrossRef

Li JQ (2018) Solving reverse logistic problem in prefabricate system by a discrete artificial bee colony algorithm. J Liaocheng Univ (Nat Sci Ed) 31(2):102–110

Zhou SY, Liu X, Effenberger F, Chao J (2018) Low-latency high-efficiency mobile fronthaul with TDM-PON (mobile-PON). IEEE/OSA J Opt Commun Networking 10(1):A20–A26CrossRef

Li Y, Sun K, Cai L (2018) Cooperative device-to-device communication with network coding for machine type communication devices. IEEE Trans Wireless Commun 17(1):296–309CrossRef

Li XW, Liu M, Deng C, Mathiopoulos PT, Ding ZG, Liu YW (2019) Full-duplex cooperative NOMA relaying systems with I/Q imbalance and imperfect SIC. IEEE Wirel Commun Lett. https://doi.org/10.1109/LWC.2019.2939309CrossRef

Lin ME (2016) Computer network attack modeling method based on attack graph. J Liaocheng Univ (Nat Sci Ed) 29(3):100–104

10.

Lei HJ, Yang ZX, Park KH, Ansari IS, Guo YC, Pan GF, Alouini MS (2019) Secrecy outage analysis for cooperative NOMA systems with relay selection schemes. IEEE Trans Commun 67(9):6282–6298CrossRef

11.

Lei HJ, Zhang ZM, Park KH, Xu P, Zhang ZF, Pan GF, Alouini MS (2018) Secrecy outage of max-min TAS scheme in MIMO-NOMA systems. IEEE Trans Veh Technol 67(8):6981–6990CrossRef

12.

Wang HM (2017) Full-Diversity uncoordinated cooperative transmission for asynchronous relay networks. IEEE Trans Veh Technol 66(1):468–480

13.

El-Malek AHA, Salhab AM, Zummo SA (2017) New bandwidth efficient relaying schemes in cooperative cognitive two-way relay networks with physical layer security. IEEE Trans Veh Technol 66(6):5372–5386CrossRef

14.

Mahmood NH, Ansari IS, Popovski P, Mogensen P, Qaraqe KA (2017) Physical-layer security with full-duplex transceivers and multiuser receiver at Eve. IEEE Trans Commun 65(10):4392–4405CrossRef

15.

İlhan H, Uysal M, Altunbas I (2009) Cooperative diversity for intervehicular communication: performance analysis and optimization. IEEE Trans Veh Technol 58(7):3301–3310CrossRef

16.

Yu JS, Bi MH, Zhuo XH, Huang TC (2018) IMDD-UMFC system performance improvement based on non-uniform quantization ADC/DAC. Journal of Liaocheng University (Natural Science Edition) 31(4):7–12

17.

Nguyen BC, Hoang TM, Dung LT (2019) Performance analysis of vehicle-to-vehicle communication with full-duplex amplify-and-forward relay over double-Rayleigh fading channels. Vehic Commun 19:100166CrossRef

18.

Nguyen SQ, Kong HY (2016) Outage probability analysis in dual-hop vehicular networks with the assistance of multiple access points and vehicle nodes. Wirel Pers Commun 87(4):1175–1190CrossRef

19.

Ai Y, Cheffena M, Mathur A, Lei HJ (2018) On physical layer security of double Rayleigh fading channels for vehicular communications. IEEE Wirel Commun Lett 7(6):1038–1041CrossRef

20.

Pandey A, Yadav S (2018) Physical layer security in cooperative AF relaying networks with direct links over mixed Rayleigh and double-Rayleigh fading channels. IEEE Trans Veh Technol 67(11):10615–10630CrossRef

21.

Alghorani Y, Kaddoum G, Muhaidat S, Pierre S, Al-Dhahir N (2016) On the performance of multihop-intervehicular communications systems over n*Rayleigh fading channels. IEEE Wirel Commun Lett 5(2):116–119CrossRef

22.

Nguyen BC, Tran XN, Hoang TM, Dung LT (2019) Performance analysis of full-duplex vehicle-to-vehicle relay system over double-Rayleigh fading channels. Mob Networks Appl. https://doi.org/10.1007/s11036-019-01291-xCrossRef

23.

Wang H, Xu LW, Lin WZ, Xiao PP, Wen R (2019) Physical layer security performance of wireless mobile sensor networks in smart city. IEEE Access 7:15436–15443CrossRef

24.

Karagiannidis GK, Sagias NC, Mathiopoulos PT (2007) N*Nakagami: a novel stochastic model for cascaded fading channels. IEEE Trans Commun 55(8):1453–1458CrossRef

25.

Xu LW, Wang JJ, Zhang H, Liu Y, Shi W, Gulliver TA (2018) Outage performance for IDF relaying mobile cooperative networks. Mobile Networks & Applications 23(6):1496–1501CrossRef

26.

Xu LW, Yu X, Wang H, Dong XL, Liu Y, Lin WZ, Wang XJ, Wang JJ (2019) Physical layer security performance of mobile vehicular networks. Mob Netw Appl. https://doi.org/10.1007/s11036-019-01224-8CrossRef

27.

Zhang WP, Kumar M, Liu JQ (2019) Multi-parameter online measurement IoT system based on BP neural network algorithm. Neur Comput Appl 31(12):8147–8155CrossRef

28.

Hu ZL, Zhao Q, Wang J (2018) The prediction model of cotton yarn intensity based on the CNN-BP neural network. Wireless Pers Commun 102(2):1905–1916CrossRef

29.

Xu LW, Wang H, Lin W, Gulliver TA, Le Khoa N (2019) GWO-BP neural network based OP performance prediction for mobile multiuser communication networks. IEEE Access 7:152690–152700CrossRef

30.

Yu RY, An XM, Jin B, Shi J, Move OA, Liu YH (2018) Particle classification optimization-based BP network for telecommunication customer churn prediction. Neural Computing & Application 29(3):707–720CrossRef

31.

Liu X, Zhou YJ, Wang ZR, Chen XH (2018) A BP neural network-based communication blind signal detection method with cyber-physical-social systems. IEEE Access 6:43920–43935CrossRef

32.

Liu L (2019) Recognition and analysis of motor imagery EEG signal based on improved BP neural network. IEEE Access 7:47794–47803CrossRef

33.

Li ZX, Jia LZ, Li F, Hu HY (2010) Outage performance analysis in relay-assisted inter-vehicular communications over double-Rayleigh fading channels. In: Proceedings of the IEEE International Conference on Communications and Mobile Computing, Shenzhen, China, pp 266–270

34.

Hasna MO, Alouini MS (2004) Harmonic mean and end-to-end performance of transmission systems with relays. IEEE Trans Wireless Commun 52(1):130–135CrossRef

35.

Anghel PA, Kaveh M (2004) Exact symbol error probability of a cooperative network in a Rayleigh-fading environment. IEEE Trans Wireless Commun 3(5):1416–1421CrossRef

36.

Gradshteyn I, Ryzhik I (2007) Table of Integrals, Series and Products, 7th edn. Academic Press, San DiegoMATH

37.

The Wolfram Functions Site (Online). http://functions.wolfram.com/. Accessed Feb 22 2018

38.

Cola TD, Mongelli M (2018) Adaptive time window linear regression for outage prediction in Q/V band satellite systems. IEEE Wireless Communications Letters 7(5):808–811CrossRef

39.

Yu X, Chu Y, Jiang F, Guo Y, Gong DW (2018) SVMs classification based two-side cross domain collaborative filtering by inferring intrinsic user and item features. Knowl-Based Syst 141:80–91CrossRef

40.

Xu KK, Yang HD, Zhu CJ (2019) A novel extreme learning machine-based Hammerstein-Wiener model for complex nonlinear industrial processes. Neurocomputing 358(9):246–254CrossRef

Titel: BP neural network-based ABEP performance prediction for mobile Internet of Things communication systems
verfasst von: Lingwei Xu
Jingjing Wang
Han Wang
T. Aaron Gulliver
Khoa N. Le
Publikationsdatum: 07.12.2019
Verlag: Springer London
Erschienen in: Neural Computing and Applications / Ausgabe 20/2020
Print ISSN: 0941-0643
Elektronische ISSN: 1433-3058
DOI: https://doi.org/10.1007/s00521-019-04604-z

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