Abstract
Optimum transmission strategy must be adopted in radio frequency energy-harvesting networks. For the purpose the study considered various radio applications in which the nodes operate on the batteries thereby minimizing the energy consumption and consequently obtaining high throughput and satisfactory delay. This paper analysed the best model for minimizing transmission energy which reduces the total consumption of energy needed to send required number of bits. Hence the study exploited proximal gradient convex optimization algorithm and spatial filter-based beam formers for minimizing the transmission power and reducing the computational time. These minimizations might be achieved by optimizing the signal to noise ratio. In general, receiving signals radiating from a particular location and directing the signal reception or transmission seems to be a challenging task. To overcome this the proposed spatial filter-based beamforming, a signal processing technique receives signals that are radiating from specific location and also attenuate signals from different locations. Moreover, it can easily direct signal reception or transmission. The simulation results depicted that the proposed algorithm is found to be energy efficient that describes the trade-off existing between the required harvested powers. This study employed Multi-objective Hungarian algorithm for the detection of channels that have low transmission power and less computational time for efficient resource allocation. The performance evaluation of the proposed system has been validated and compared with state of art methods like Joint optimization, fixed time allocation and bisectional search. The experimental results show that the proposed system outperforms the existing systems in terms of signal to noise ratio, transmission of energy and resource allocation.
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References
Li J, **ong K, Cao J, Yang X, Liu T (2020) Energy Efficiency in RF Energy Harvesting-Powered Distributed Antenna Systems for the Internet of Things. Sensors, 20: 4631
Zhou, Z., Gao, C., Xu, C., Chen, T., Zhang, D., & Mumtaz, S. (2017). Energy-efficient stable matching for resource allocation in energy harvesting-based device-to-device communications. IEEE access, 5, 15184–15196.
Lukman, S., Agajo, J., & Salihu, B. (2021). A survey of radio frequency energy harvesting techniques toward effective powering of Mobile Devices using Cockcroft Walton voltage. Multiplier, EasyChair 2516–2314.
Hossain, M. A., Noor, R. M., Yau, K. L. A., Ahmedy, I., & Anjum, S. S. (2019). A survey on simultaneous wireless information and power transfer with cooperative relay and future challenges,. IEEE access, 7, 19166–19198.
Srivantana T, Maichalernnukul K. (2017). Two-way multi-antenna relaying with simultaneous wireless information and power transfer. Symmetry, 9: 42,
Basnayake V, Jayakody DNK, Sharma V, Sharma N, Muthuchidambaranathan P, Mabed H (2020) A new green prospective of non-orthogonal multiple access (noma) for 5G. Information, vol. 11, p. 89,
Choi, K. W., Hwang, S. I., Aziz, A. A., Jang, H. H., Kim, J. S., Kang, D. S., et al. (2020). Simultaneous wireless information and power transfer (SWIPT) for internet of things: novel receiver design and experimental validation,. IEEE Internet of Things Journal, 7, 2996–3012.
Sun, W., Liu, C., Qian, M., Xu, S., & Chen, Y. (2020). Downlink ergodic sum capacity maximisation for massive distributed antenna systems with SWIPT protocol. IET Communications, 15(3), 464-475
Zheng, Y., Bi, S., Zhang, Y. J. A., Lin, X., & Wang, H. (2020). Joint beamforming and power control for throughput maximization in IRS-assisted MISO WPCNs,. IEEE Internet of Things Journal, 8, 8399–8410.
Khani, M., Alizadeh, M., Hoydis, J., & Fleming, P. (2020). Adaptive neural signal detection for massive MIMO,. IEEE Transactions on Wireless Communications, 19, 5635–5648.
Briantoro, H., Funabiki, N., Kuribayashi, M., Munene, K. I., Sudibyo, R. W., Islam, M. M., et al. (2020). Transmission power optimization of concurrently communicating two access points in wireless local area network,. International Journal of Mobile Computing and Multimedia Communications (IJMCMC), 11, 1–25.
Samanta, A., & Misra, S. (2017). Energy-efficient and distributed network management cost minimization in opportunistic wireless body area networks,. IEEE Transactions on Mobile Computing, 17, 376–389.
Nalband, A. H., Sarvagya, M., & Ahmed, M. R. (2021). Spectral Efficient Beamforming for mmWave MISO Systems using Deep Learning Techniques. Arabian Journal for Science and Engineering, 46, 9783-9795
Tuan, P. V., & Koo, I. (2017). Optimal multiuser MISO beamforming for power-splitting SWIPT cognitive radio networks. Ieee Access : Practical Innovations, Open Solutions, 5, 14141–14153.
Alavi, F., Cumanan, K., Ding, Z., & Burr, A. G. (2018). Beamforming techniques for nonorthogonal multiple access in 5G cellular networks,. IEEE Transactions on Vehicular Technology, 67, 9474–9487.
Tervo, O., Pennanen, H., Christopoulos, D., Chatzinotas, S., & Ottersten, B. (2017). Distributed optimization for coordinated beamforming in multicell multigroup multicast systems: power minimization and SINR balancing,. IEEE Transactions on Signal Processing, 66, 171–185.
Nguyen, D., Zomorrodi, M., Karmakar, N., & Ho, K. (2020). Efficient beamforming technique based on sparse MIMO array and spatial Filter Bank,. IEEE Antennas and Wireless Propagation Letters, 19, 1147–1151.
Higuchi, T., Ito, N., Araki, S., Yoshioka, T., Delcroix, M., & Nakatani, T. (2017). Online MVDR beamformer based on complex gaussian mixture model with spatial prior for noise robust ASR,. IEEE/ACM Transactions on Audio Speech and Language Processing, 25, 780–793.
Senel, K., Björnson, E., & Larsson, E. G. (2019). Joint transmit and circuit power minimization in massive MIMO with downlink SINR constraints: when to turn on massive MIMO?,. IEEE Transactions on Wireless Communications, 18, 1834–1846.
Zhang, X., Wang, J., & Poor, H. V. (2022). Joint optimization of IRS and UAV-Trajectory: for supporting statistical Delay and Error-Rate Bounded QoS over mURLLC-Driven 6G Mobile Wireless Networks using FBC,. IEEE Vehicular Technology Magazine, 17, 55–63.
Zhang, T., Wang, Y., Yi, W., Liu, Y., & Nallanathan, A. (2022). Joint Optimization of Caching Placement and Trajectory for UAV-D2D Networks. IEEE Transactions on Communications, 70(8), 5514-5527
Ranjan, R., Agrawal, N., & Joshi, S. (2020). Interference mitigation and capacity enhancement of cognitive radio networks using modified greedy algorithm/channel assignment and power allocation techniques,. IET Communications, 14, 1502–1509.
Banerjee, A., Paul, A., & Maity, S. P. (2017). Joint power allocation and route selection for outage minimization in multihop cognitive radio networks with energy harvesting,. IEEE Transactions on Cognitive Communications and Networking, 4, 82–92.
Nguyen, N. Q., & Prager, R. W. (2018). “A spatial coherence approach to minimum variance beamforming for plane-wave compounding. IEEE Transactions on Ultrasonics, Ferroelectrics, and Frequency Control, 65: 522–534,
Jiang, X., Wu, Z., Yin, Z., Yang, Z., & Zhao, N. (2020). Power consumption minimization of UAV relay in NOMA networks,. IEEE Wireless Communications Letters, 9, 666–670.
EL-Mokadem, E. S., El‐Kassas, A. M., Elgarf, T. A., & El‐Hennawy, H. (2020). Throughput enhancement of cognitive M2M networks based on NOMA for 5G communication systems,. International Journal of Communication Systems, 33, e4468.
Dash, S. P., Subhashini, K., & Satapathy, J. (2020). Optimal location and parametric settings of FACTS devices based on JAYA blended moth flame optimization for transmission loss minimization in power systems,. Microsystem Technologies, 26, 1543–1552.
Shim, Y., Park, H., & Shin, W. (2020). Joint time allocation for wireless energy harvesting decode-and-forward relay-based IoT networks with rechargeable and nonrechargeable batteries,. IEEE Internet of Things Journal, 8, 2792–2801.
Mu, G. (2020). Joint beamforming and power allocation for wireless powered UAV-assisted cooperative NOMA systems. EURASIP Journal on Wireless Communications and Networking, 2020: 1–14
Shin, J. (2021). Min-SINR-maximizing wireless-powered AF relay for multisource and multidestination networks,. Wireless Personal Communications, 116, 1785–1793.
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Thomas, R.M., Malarvizhi, S. Multicast Spatial Filter Beamforming with Resource Allocation Using Joint Multi-objective Optimization Approaches in Wireless Powered Communication Networks. Wireless Pers Commun 129, 2481–2501 (2023). https://doi.org/10.1007/s11277-023-10242-5
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DOI: https://doi.org/10.1007/s11277-023-10242-5