Efficient Authentication Protocol and Its Application in Resonant Inductive Coupling Wireless Power Transfer Systems

Chaos theory and its extension into cryptography has generated significant applications in industrial mixing, pulse width modulation and in electric compaction. Likewise, it has merited applications in authentication mechanisms for wireless power transfer systems. Wireless power transfer (WPT) via resonant inductive coupling mechanism enables the charging of electronic devices devoid of cords and wires. In practice, the key to certified charging requires the use of an authentication protocol between a transmitter (charger) and receiver (smartphone/some device). Via the protocol, a safe level and appropriate charging power can be harvested from a charger. Devoid of an efficient authentication protocol, a malicious charger may fry the circuit board of a receiver or cause a permanent damage to the device. In this regard, we first propose a chaos-based key exchange authentication protocol and analyze its robustness in terms of security and computational performance. Secondly, we theoretically demonstrate how the protocol can be applied to WPT systems for the purposes of charger to receiver authentication. Finally, we present insightful research problems that are relevant for future research in this paradigm.

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Wireless Power Transfer Systems via Strong Coupled Magnetic Resonances — Design, PCB Implementation and Tests

Advanced Materials Research ◽

10.4028/www.scientific.net/amr.383-390.5984 ◽

2011 ◽

Vol 383-390 ◽

pp. 5984-5989

Author(s):

Yan Ping Yao ◽

Hong Yan Zhang ◽

Zheng Geng

Keyword(s):

Printed Circuit Board ◽

Experimental System ◽

Wireless Power Transfer ◽

Circuit Board ◽

Transfer Efficiency ◽

Power Transfer ◽

Wireless Power ◽

Power Transfer Efficiency ◽

Coil Winding ◽

Magnetic Resonances

In this paper, we present theoretical analysis and detailed design of a class of wireless power transfer (WPT) systems based on strong coupled magnetic resonances. We established the strong coupled resonance conditions for practically implementable WPT systems. We investigated the effects of non-ideal conditions presented in most practical systems on power transfer efficiency and proposed solutions to deal with these problems. We carried out a design of WPT system by using PCB (Printed Circuit Board) antenna pair, which showed strong coupled magnetic resonances. The innovations of our design include: (1) a new coil winding pattern for resonant coils that achieves a compact space volume, (2) fabrication of resonant coils on PCBs, and (3) integration of the entire system on a pair of PCBs. Extensive experiments were performed and experimental results showed that our WPT system setup achieved a guaranteed power transfer efficiency 14% over a distance of two times characteristic length(44cm). The wireless power transfer efficiency in this PCB based experimental system was sufficiently high to lighten up a LED with a signal generator.

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Infrastructure Material Magnetization Impact Assessment of Wireless Power Transfer Pavement Based on Resonant Inductive Coupling

IEEE Transactions on Intelligent Transportation Systems ◽

10.1109/tits.2021.3099490 ◽

2021 ◽

pp. 1-9

Author(s):

Feng Li ◽

Xuan Sun ◽

Siqi Zhou ◽

Yuhang Chen ◽

Zhibin Hao ◽

...

Keyword(s):

Impact Assessment ◽

Wireless Power Transfer ◽

Inductive Coupling ◽

Power Transfer ◽

Wireless Power

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Dynamic Wireless Power Transfer Charging Infrastructure for Future EVs: From Experimental Track to Real Circulated Roads Demonstrations

World Electric Vehicle Journal ◽

10.3390/wevj10040084 ◽

2019 ◽

Vol 10 (4) ◽

pp. 84 ◽

Cited By ~ 9

Author(s):

Stéphane Laporte ◽

Gérard Coquery ◽

Virginie Deniau ◽

Alexandre De Bernardinis ◽

Nicolas Hautière

Keyword(s):

Electric Vehicles ◽

Wireless Power Transfer ◽

Future Generation ◽

Road Transport ◽

Future Research ◽

Power Transfer ◽

Wireless Power ◽

Mechanical Contact ◽

Charging Infrastructure ◽

System Characterization

In a context of growing electrification of road transport, Wireless Power Transfer (WPT) appears as an appealing alternative technology as it enables Electric Vehicles (EVs) to charge while driving and without any mechanical contact (with overhead cables or rails in the ground). Although the WPT technology background dates from the end of 20th century, recent advances in semiconductor technologies have enabled the first real demonstrations. Within the FABRIC European project, the French research Institute VEDECOM and its partners implemented a whole prototype wireless power transfer charging infrastructure. The first demonstrations of Inductive WPT in different real driving conditions (up to 20 kW, from 0 to 100 km/h, with one or two serial vehicles) were provided. This paper describes the prototype equipment and its instrumentation and provides the system characterization results. The future of the Inductive WPT technology is further discussed considering its different technical and economic challenges. In parallel, how this technology could be part of future generation road infrastructures is discussed. Future research and demonstration steps are presented in the conclusion.

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