Power supply device, integrated circuit, energy transmitter and impedance matching method

What is claimed is: 1. A resonance contactless power supply device, comprising: a) a converter configured to convert an input power signal to an adjustable DC voltage; b) an inverter configured to receive said adjustable DC voltage, and to generate an AC voltage with a leakage inductance resonance frequency; c) a first resonance circuit comprising a transmitting coil, and being configured to receive said AC voltage from said inverter; d) a second resonance circuit comprising a receiving coil that is contactlessly coupled to said transmitting coil, wherein said second resonance circuit is configured to receive electric energy from said transmitting coil; and e) a control circuit configured to control said adjustable DC voltage according to a phase difference between said AC voltage and an AC current output by said inverter, such that said phase difference is maintained as a predetermined angle, wherein said control circuit comprises a current phase detector configured to detect a zero-crossing point of said AC current, an error amplifying circuit configured to generate an error amplifying signal by comparing a phase difference signal against an angle threshold signal that is proportional to said predetermined angle, and a compensation circuit configured to generate a compensation signal by compensating said error amplifying signal. 2. The resonance contactless power supply device according to claim 1 , wherein said predetermined angle is greater than or equal to about 50°, and less than or equal to about 60°. 3. The resonance contactless power supply device according to claim 2 , wherein said predetermined angle is about 55°. 4. The resonance contactless power supply device according to claim 1 , wherein said control circuit comprises: a) said current phase detector configured to detect a phase of said AC current, and to generate a current phase signal that indicates whether said AC current is positive or negative; b) a compensation signal generator configured to obtain said phase difference according to a control signal and said current phase signal, and to generate said compensation signal according to said phase difference and said predetermined angle; and c) a control signal generator configured to generate a control signal according to a power stage current and said compensation signal, where said control signal is used to control said inverter in order to regulate said adjustable DC voltage. 5. The resonance contactless power supply device according to claim 4 , wherein: a) said compensation signal generator is configured to receive said phase difference signal, and to generate said compensation signal according to said phase difference signal and said angle threshold signal; and b) said phase difference signal is proportional to said phase difference. 6. The resonance contactless power supply device according to claim 5 , wherein said compensation signal generator comprises: a) an AND-gate configured to receive said current phase signal and said control signal, and to generate said phase difference width signal having a pulse width that corresponds to said phase difference; and b) an averaging circuit configured to generate said phase difference signal by averaging said phase difference width signal. 7. The resonance contactless power supply device according to claim 1 , wherein said control circuit comprises an averaging circuit configured to determine said phase difference. 8. An integrated circuit configured for a resonance contactless energy transmitter, the integrated circuit comprising: a) a converter configured to convert an input power signal to an adjustable DC voltage; b) an inverter configured to receive said adjustable DC voltage, and to generate an AC voltage with a leakage inductance resonance frequency, wherein said AC voltage is configured to drive a first resonance circuit of said resonance contactless energy transmitter; and c) a control circuit configured to control said adjustable DC voltage according to a phase difference between said AC voltage and an AC current from said inverter, such that said phase difference is maintained as a predetermined angle, wherein said control circuit comprises a current phase detector configured to detect a zero-crossing point of said AC current, an error amplifying circuit configured to generate an error amplifying signal by comparing a phase difference signal against an angle threshold signal that is proportional to said predetermined angle, and a compensation circuit configured to generate a compensation signal by compensating said error amplifying signal. 9. The integrated circuit according to claim 8 , wherein said predetermined angle is greater than or equal to about 50°, and less than or equal to about 60°. 10. The integrated circuit according to claim 9 , wherein said predetermined angle is about 55°. 11. The integrated circuit according to claim 8 , wherein said control circuit comprises: a) said current phase detector configured to detect a phase of said AC current, and to output a current phase signal that indicates whether said AC current is positive or negative; b) a compensation signal generator configured to obtain said phase difference according to a control signal and said current phase signal, and to generate said compensation signal according to said phase difference and said predetermined angle; and c) a control signal generator configured to generate a control signal according to a power stage current and said compensation signal, wherein said control signal is used to control said inverter in order to regulate said adjustable DC voltage. 12. The integrated circuit according to claim 11 , wherein: a) said compensation signal generator is configured to receive said phase difference signal, and to generate said compensation signal according to said phase difference signal and said angle threshold signal; and b) said phase difference signal is proportional to said phase difference. 13. The integrated circuit according to claim 12 , wherein said compensation signal generator comprises: a) an AND-gate configured to receive said current phase signal and said control signal, and to generate a phase difference width signal having a pulse width that corresponds to said phase difference; and b) an averaging circuit configured to generate said phase difference signal by averaging said phase difference width signal. 14. A resonance contactless energy transmitter, comprising the first resonance circuit of claim 8 , wherein said first resonance circuit comprises a transmitting coil configured to receive said AC voltage from said inverter. 15. The integrated circuit according to claim 8 , wherein said control circuit comprises an averaging circuit configured to determine said phase difference. 16. An impedance matching method for a resonance contactless power supply device, the method comprising: a) converting an input power signal to an adjustable DC voltage; b) receiving, by an inverter, said adjustable DC voltage, and generating an AC voltage with a leakage inductance resonance frequency; c) detecting, by a current phase detector, a zero-crossing point of an AC current output from said inverter; d) receiving, by a first resonance circuit comprising a transmitting coil, said AC voltage from said inverter; e) receiving, by a second resonance circuit comprising a receiving coil that is contactlessly coupled to said transmitting coil, electric energy from said transmitting coil; f) generating, by an error amplifying circuit, an error amplifying signal by comparing a phase difference signal against an an