Analisa Penggunaan Teknologi Wireless Power Transfer

Authors

  • Arsanto Narendro Universitas Budi Luhur

Keywords:

Wireless Power Transfer, Energy Harvesting, Wireless Charging, Inductive Coupling, Capacitive Coupling, Charging Flexibility

Abstract

The extensive adoption and rapid expansion of mobile gadgets have positioned wireless power transfer (WPT) as a critical domain of scientific inquiry. A compelling feature of WPT lies in its ability to offer a versatile and economical charging solution, eliminating the necessity for a direct physical link to power outlets—a particularly beneficial trait when manual connection is impractical for the user. Historically, battery replenishment for such hardware has relied on wired systems, necessitating a tethered attachment to electricity via physical cabling. In contrast, WPT facilitates the transmission of energy through the air over brief spans, utilizing either magnetic fields generated by inductive coil coupling or electric fields arising from capacitive electrode interaction, which are subsequently captured by an antenna for functional use. This paper provides a comprehensive analysis of current WPT methodologies, their functional mechanisms, practical implementations, and prospective research trajectories within this nascent field. Despite existing limitations, WPT represents a transformative advancement poised to fundamentally reshape the operational framework of mobile networks, the Internet of Things (IoT), and associated future technological ecosystems.

References

Bi, S., Ho, C. K., & Zhang, R. (2015). Wireless powered communication: Opportunities and challenges. IEEE Communications Magazine, 53, 117-125.

Capua, G. D., Femia, N., Petrone, G., Lisi, G., Du, D., & Subramonian, R. (2017). Power and efficiency analysis of high-frequency wireless power transfer systems. International Journal of Electrical Power & Energy Systems, 84, 124-134. https://doi.org/10.1016/j.ijepes.2016.05.005

Chen, X., Ng, D. W. K., & Chen, H. (2016). Secrecy wireless information and power transfer: Challenges and opportunities. IEEE Wireless Communications, 23, 54-61.

Chhawchharia, S., Sahoo, S. K., Balamurugan, M., Sukchai, S., & Yanine, F. (2018). Investigation of wireless power transfer applications with a focus on renewable energy. Renewable and Sustainable Energy Reviews, 91, 888-902.

Dai, H., Liu, Y., Chen, G., Wu, X., & He, T. (2014). Safe charging for wireless power transfer. In IEEE INFOCOM 2014 – IEEE Conference on Computer Communications (pp. 1105-1113).

Federal Communications Commission. (2014). FCC Rules and Regulations Part 15 Section 247 (15.247) in Operation within the bands 902–928 MHz, 2400–2483.5 MHz, and 5725–5850 MHz (Tech. Rep.).

Grover, P., & Sahai, A. (2010). Shannon meets Tesla: Wireless information and power transfer. In 2010 IEEE International Symposium on Information Theory (pp. 2363-2367).

Hata, K., Imura, T., & Hori, Y. (2015). Dynamic wireless power transfer system for electric vehicle to simplify ground facilities - power control based on vehicle-side information. World Electric Vehicle Journal, 7, 558-569.

Hui, S. Y. R., Zhong, W., & Lee, C. K. (2014). A critical review of recent progress in mid-range wireless power transfer. IEEE Transactions on Power Electronics, 29, 4500-4511.

Jawad, A. M., Nordin, R., Gharghan, S. K., Jawad, H. M., & Ismail, M. (2017). Opportunities and challenges for near-field wireless power transfer: A review. Energies, 10.

Kim, J., et al. (2013). Coil design and shielding methods for a magnetic resonant wireless power transfer system. Proceedings of the IEEE, 101, 1332-1342.

Kurs, A., Karalis, A., Moffatt, R., Joannopoulos, J. D., Fisher, P., & Soljacic, M. (2007). Wireless power transfer via strongly coupled magnetic resonances. Science, 317, 83-86.

Lee, S., & Lorenz, R. D. (2011). Development and validation of model for 95%-efficiency 220-w wireless power transfer over a 30-cm air gap. IEEE Transactions on Industry Applications, 47, 2495-2504.

Li, J. (2017). Research progress of wireless power transmission technology and the related problems. AIP Conference Proceedings, 1820. https://doi.org/10.1063/1.4977407

Li, J. L., Krairiksh, M., Rahman, T. A., & Al-Shamma'a, A. (2013). Keynote speakers: Wireless power transfer: From long-distance transmission to short-range charging. In 2013 IEEE International RF and Microwave Conference (RFM) (pp. xi-xv).

Li, S., & Mi, C. C. (2015). Wireless power transfer for electric vehicle applications. IEEE Journal of Emerging and Selected Topics in Power Electronics, 3, 4-17.

Low, Z. N., Chinga, R. A., Tseng, R., & Lin, J. (2009). Design and test of a high-power high efficiency loosely coupled planar wireless power transfer system. IEEE Transactions on Industrial Electronics, 56, 1801-1812.

Okoyeigbo, O., et al. (2018). Comparative study of mimo-ofdm channel estimation in wireless systems. International Review on Modelling and Simulations (I.RE.MO.S.), 11(3), 158-165. https://doi.org/10.15866/iremos.v11i3.13884

Okoyeigbo, O., Okokpujie, K., Omoruyi, O., & Nkordeh, N. (2017). Comparative analysis of channel estimation techniques in siso, miso and mimo systems. International Journal of Electronics and Telecommunications (IJET), 63(3), 307-312.

Pan, H., Qi, L., Zhang X., Zhang Z., Salman W., Yuan Y., et al. (2017). A portable renewable solar energy-powered cooling system based on wireless power transfer for a vehicle cabin. Applied Energy, 195, 334-343.

Parmar, Y., Patel, A., & Shah, J. (2015). Review paper on wireless power transmission. International Journal of Scientific Research Engineering & Technology (IJSRET), 4, 1171-1173.

Sample, A., & Smith, J. R. (2009). Experimental results with two wireless power transfer systems. In 2009 IEEE Radio and Wireless Symposium (pp. 16-18).

Sample, A. P., Meyer, D. T., & Smith, J. R. (2011). Analysis, experimental results, and range adaptation of magnetically coupled resonators for wireless power transfer. IEEE Transactions on Industrial Electronics, 58, 544-554.

Sanborn, G., & Phipps, A. (2017). Standards and methods of power control for variable power bidirectional wireless power transfer. In 2017 IEEE Wireless Power Transfer Conference (WPTC) (pp. 1-4).

Shinohara, N. (2000). Wireless power transmission for solar power satellite (SPS). Space Solar Power.

Sun, L., Ma, D., & Tang, H. (2018). A review of recent trends in wireless power transfer technology and its applications in electric vehicle wireless charging. Renewable and Sustainable Energy Reviews, 91, 490-503.

Tesla, N. (1905). The transmission of electrical energy without wires as a means for furthering peace. Electrical World and Engineer, 4.

Valenta, C. R., & Durgin, G. D. (2014). Harvesting wireless power: Survey of energy-harvester conversion efficiency in far-field, wireless power transfer systems. IEEE Microwave Magazine, 15, 108-120.

Venkateswara, R. M., Sai, H. K., & Venkat, M. C. (2013). Microwave power transmission, A next generation power transmission System. IOSR Journal of Electrical and Electronics Engineering, 4.

Wang, B., Yerazunis, W., & Teo, K. H. (2013). Wireless power transfer: Metamaterials and array of coupled resonators. Proceedings of the IEEE, 101, 1359-1368.

Xie, L., Shi, Y., Hou, Y. T., & Lou, A. (2013). Wireless power transfer and applications to sensor networks. IEEE Wireless Communications, 20, 140-145.

Zhang, R., & Ho, C. K. (2013). MIMO broadcasting for simultaneous wireless information and power transfer. IEEE Transaction on Wireless Communications, 12,1989-2001 Zhou, X.,

Zhang, R., & Ho, C. K. (2013). Wireless information and power transfer: Architecture design and rate-energy tradeoff. IEEE Transactions on Communications, 61, 4754-4767.

Additional Files

Published

16-04-2026

How to Cite

Arsanto Narendro. (2026). Analisa Penggunaan Teknologi Wireless Power Transfer . OKTAL : Jurnal Ilmu Komputer Dan Sains, 5(04), 349–356. Retrieved from https://journal.mediapublikasi.id/index.php/oktal/article/view/6108

Issue

Vol. 5 No. 04 (2026): OKTAL : Jurnal Ilmu Komputer Dan Sains (INPRESS)

Section

Articles