Wireless power transfer (WPT) enables device charging without direct physical or wired connections. Resonant circuits are key components of WPT systems that optimize energy transfer from the transmitter to the receiver. In parallel compensated receivers, capacitors balance the inductance of the receiver coil to achieve resonance, reducing circuit impedance, thereby enhancing power transfer.
The electromagnetic fields generated by such receivers can interfere with other electronic devices. Controlling this interference requires modulating the system's operating frequency. However, this modulation creates a mismatch between the modulated and resonant frequencies, severely degrading power output and system efficiency. Current strategies to correct this mismatch rely on additional hardware or complex circuitry, leading to energy loss, complex control settings, and bulkier designs.
In an attempt to find an innovative solution to overcome these challenges, a group of scientists led by Professor Dukju Ahn at Incheon National University, Korea, proposed a resonant tuning rectifier (RTR) for parallel resonant receiver systems. The novel RTR features a minimalist design that synchronizes its operation with the natural rhythm of the system's primary current. "Our RTR does not require extra power components or complex feedback circuitry, rendering it more practical for real-world use," says Prof. Ahn. The study was made available online on May 14, 2024 and was published in Volume 71, Issue 12 of IEEE Transactions on Industrial Electronics on December 01, 2024.
The RTR automatically adjusts effective capacitance to tune the resonant frequency by syncing control signals with the system's current, compensating for differences between intrinsic resonance and modulation periods. Unlike existing methods, it uses a simple sensor coil to extract phase information without impacting performance, eliminating the need for transmitter-receiver communication.
Testing a 2.2 kW prototype for automobile charging showed that the RTR compensates for frequency modulation (80—90 kHz) in 70 ms, maintaining stable power output during misalignment and improving efficiency from 3.5% to 8.1%. Its zero-voltage system optimizes control settings to reduce power loss, offering a simple, cost-effective solution for real-time adaptation and stable power delivery.
"The automatic adjustment of resonant frequency impacts not only wireless charging but also induction heating, plasma generation, and power conversion," explains Prof. Ahn. "With minimal energy loss, high efficiency, stable throughput, a minimalist design, and low system impact, RTR can significantly enhance wireless power system performance," he concludes. As wireless charging becomes more widespread, the proposed RTR offers a promising solution to mitigate existing challenges, making this technology more accessible to everyday users.
