A magnetic resonance wireless power transmission device capable of adjusting resonance frequency is disclosed. A wireless power transmission device according to an embodiment of the present invention comprises: a power amplifier for amplifying a wireless power signal using a driving frequency signal; a resonator for configuring a resonance tank and wirelessly transmitting, through magnetic resonance, the wireless power signal output from the power amplifier using a resonance frequency of the resonance tank; and a resonance control unit for controlling a duty ratio using a frequency applied to the resonator or a frequency signal generated by the resonator and adjusting the resonance frequency of the resonator.

The exemplified disclosure presents a highly power efficient amplifier (e.g., front-end inverter and/or amplifier) that achieves significant current reuse (e.g., 6-time for a 3-stack embodiments) by stacking inverters and splitting the capacitor feedback network. In some embodiments, the exemplified technology facilitates N-time current reuse to substantially reduced power consumption. It is observed that the exemplified disclosure facilitates significant current-reuse operation that significantly boost gain gm while providing low noise performance without increasing power usage. In addition, the exemplified technology is implemented such that current reuse and number of transistor has a generally linear relationship and using fewer transistors as compared to known circuits of similar topology.

A control method of a minimum power input applicable to a wireless power transfer system including a power transmission unit and at least one power receiving unit is provided. The power transmission unit is electrically connected with a control voltage signal and an input voltage signal and accordingly generates the minimum power input. The power transmission unit transmits the minimum power input wirelessly through a wireless transmission to the at least one power receiving unit for receiving. By adjusting the input voltage signal, the duty ratio and resonant frequency of the control voltage signal, the present invention ensures an optimal power transmission efficiency of the wireless power transmission system. Moreover, parameters of a charge pump reservoir and gate driving circuit can be further designed in view of the trend feedback of its gate drive waveforms so as to optimize the effect of the proposed invention.

A control method of a minimum power input applicable to a wireless power transfer system including a power transmission unit and at least one power receiving unit is provided. The power transmission unit is electrically connected with a control voltage signal and an input voltage signal and accordingly generates the minimum power input. The power transmission unit transmits the minimum power input wirelessly through a wireless transmission to the at least one power receiving unit for receiving. By adjusting the input voltage signal, the duty ratio and resonant frequency of the control voltage signal, the present invention ensures an optimal power transmission efficiency of the wireless power transmission system. Moreover, parameters of a charge pump reservoir and gate driving circuit can be further designed in view of the trend feedback of its gate drive waveforms so as to optimize the effect of the proposed invention.

To provide a high-voltage output amplifier having a wide bandwidth which can efficiently reduce power consumption and allows employment of relatively low withstand voltage Nch MOS FETs without imbalanced voltage distribution between a Nch MOS FET Q101 and a Nch MOS FET Q102 and imbalanced distribution between a Nch MOS FET Q201 and a Nch MOS FET Q202. A high-voltage amplifier of a positive-side output stage circuit comprises a Nch MOS FET Q101 and a Nch MOS FET Q102, while a high-voltage amplifier of a negative-side output stage circuit comprises a Nch MOS FET Q201 and a Nch MOS FET Q 202. The source of the Nch MOS FET Q101 is connected to the drain of the Nch MOS FET Q102, the source of the Nch MOS FET Q201 is connected to the drain of the Nch MOS FET Q202. Current controls at the source of the Nch MOS FET Q102 and the source of the Nch MOS FET Q202 are conducted respectively. The current control at the source of the Nch MOS FET Q202 is conducted by a negative-side photo coupler. The gate of the Nch MOS FET Q101 and the gate of the Nch MOS FET Q201 are connected via a condenser C151.

The exemplified disclosure presents a highly power efficient amplifier (e.g., front-end inverter and/or amplifier) that achieves significant current reuse (e.g., 6-time for a 3-stack embodiments) by stacking inverters and splitting the capacitor feedback network. In some embodiments, the exemplified technology facilitates N-time current reuse to substantially reduced power consumption. It is observed that the exemplified disclosure facilitates significant current-reuse operation that significantly boost gain gm while providing low noise performance without increasing power usage. In addition, the exemplified technology is implemented such that current reuse and number of transistor has a generally linear relationship and using fewer transistors as compared to known circuits of similar topology.

To provide a high-voltage output amplifier having a wide bandwidth which can efficiently reduce power consumption and allows employment of relatively low withstand voltage Nch MOS FETs without imbalanced voltage distribution between a Nch MOS FET Q101 and a Nch MOS FET Q102 and imbalanced distribution between a Nch MOS FET Q201 and a Nch MOS FET Q202.

A high-voltage amplifier of a positive-side output stage circuit comprises a Nch MOS FET Q101 and a Nch MOS FET Q 102, while a high-voltage amplifier of a negative-side output stage circuit comprises a Nch MOS FET Q201 and a Nch MOS FET Q 202. The source of the Nch MOS FET Q101 is connected to the drain of the Nch MOS FET Q102, the source of the Nch MOS FET Q201 is connected to the drain of the Nch MOS FET Q202. Current controls at the source of the Nch MOS FET Q102 and the source of the Nch MOS FET Q202 are conducted respectively. The current control at the source of the Nch MOS FET Q202 is conducted by a negative-side photo coupler. The gate of the Nch MOS FET Q101 and the gate of the Nch MOS FET Q201 are connected via a condenser C151.

A magnetic resonance wireless power transmission device capable of adjusting resonance frequency is disclosed. A wireless power transmission device according to an embodiment of the present invention comprises: a power amplifier for amplifying a wireless power signal using a driving frequency signal; a resonator for configuring a resonance tank and wirelessly transmitting, through magnetic resonance, the wireless power signal output from the power amplifier using a resonance frequency of the resonance tank; and a resonance control unit for controlling a duty ratio using a frequency applied to the resonator or a frequency signal generated by the resonator and adjusting the resonance frequency of the resonator.