Wireless power transmission system and power transmission device of wireless power transmission system

What is claimed is: 1. A power transmission device that transmits first AC power in a noncontact manner to a power receiving device having a first resonator, the first resonator receiving the first AC power, the power transmission device comprising: a second resonator that electromagnetically couples with the first resonator to transmit the first AC power to the first resonator; a third resonator that electromagnetically couples with the first resonator to transmit second AC power to the first resonator; an inverter that generates the first AC power by using either a frequency f 11 or a frequency f 12 , the frequency f 11 being lower than a first resonance frequency f 0 between the first resonator and the second resonator, the frequency f 12 being higher than the first resonance frequency f 0 ; an oscillator that generates the second AC power by using either a frequency f 10 or a frequency f 20 , the frequency f 10 being lower than a second resonance frequency fr between the first resonator and the third resonator, the frequency f 20 being higher than the second resonance frequency fr; a foreign object detector that determines whether or not a foreign object is present between the first resonator and the third resonator based on a physical quantity in the third resonator that changes according to the second AC power of either the frequency f 10 or the frequency f 20 ; and power transmission control circuitry operative to: set a foreign object detection period in which foreign object is detected by the foreign object detector, between i) a first power transmission period in which the first AC power is transmitted from the second resonator to the first resonator and ii) a second power transmission period subsequent to the first power transmission period; set to the inverter, one of the frequency f 11 or the frequency f 12 in the first power transmission period; and set to the inverter, the other of the frequency f 11 or the frequency f 12 in the second power transmission period if it is determined that the foreign object is present in the foreign object detection period. 2. The power transmission device according to claim 1 , wherein, if it is determined that the foreign object is not present in the foreign object detection period, the power transmission control circuitry sets to the inveter, in the second power transmission period, the frequency f 11 or the frequency f 12 that is the same frequency as the frequency used in the first power transmission period, and causes the inverter to start to transmit the first AC power at the set one of the frequency f 11 and the frequency f 12 . 3. The power transmission device according to claim 1 , wherein, if it is determined that the foreign object is present in the foreign object detection period when the frequency f 11 is used in the first power transmission period and the frequency f 10 is used in the foreign object detection period, the power transmission control circuitry sets to the inverter, the frequency f 12 in the second power transmission period, and causes the inverter to start to transmit the first AC power at the frequency f 12 . 4. The power transmission device according to claim 2 , wherein, if it is determined that the foreign object is not present in the foreign object detection period when the frequency f 11 is used in the first power transmission period and the frequency f 10 is used in the foreign object detection period, the power transmission control circuitry sets to the inverter, the frequency f 11 in the second power transmission period, and causes the inverter to start to transmit the first AC power at the frequency f 11 . 5. The power transmission device according to claim 1 , wherein, if it is determined that the foreign object is present in the foreign object detection period when the frequency f 12 is used in the first power transmission period and the frequency f 20 is used in the foreign object detection period, the power transmission control circuitry sets to the inverter, the frequency f 11 in the second power transmission period, and causes the inverter to start to transmit the first AC power at the frequency f 11 . 6. The power transmission device according to claim 2 , wherein, if it is determined that the foreign object is not present in the foreign object detection period when the frequency f 12 is used in the first power transmission period and the frequency f 20 is used in the foreign object detection period, the power transmission control circuitry sets to the inverter, the frequency f 12 in the second power transmission period, and causes the inverter to start to transmit the first AC power at the frequency f 12 . 7. The power transmission device according to claim 1 , wherein the foreign object detector measures the physical quantity in the third resonator that changes according to the second AC power, and determines that a foreign object is present between the first resonator and the third resonator when a difference between the physical quantity after having changed and a prescribed reference value is greater than a preset threshold value. 8. The power transmission device according to claim 1 , wherein the foreign object detector measures the physical quantity in the third resonator, and determines whether or not a foreign object is present, based on a value calculated from the measured physical quantity. 9. The power transmission device according to claim 8 , wherein the physical quantity in the third resonator is i) a voltage that is applied to the third resonator, ii) a current that flows in the third resonator, iii) a frequency that is applied to the third resonator, iv) an input impedance value of the third resonator, or v) an input inductance value of the third resonator. 10. The power transmission device according to claim 1 , wherein the first resonator has a parallel resonance circuit including a coil and a capacitor, and, if the physical quantity in the third resonator is an input inductance of the third resonator, the foreign object detector is operative to; measure i) an input inductance value Lin(f 10 ) of the third resonator that is produced when the oscillator is oscillating at the frequency f 10 and ii) an input inductance value Lin(f 20 ) of the third resonator that is produced when the oscillator is oscillating at the frequency f 20 ; calculate a coupling coefficient k according to an expression k 2 =1−Lin(f 20 )/Lin(f 10 ): and determine whether or not the foreign object is present based on the calculated coupling coefficient k. 11. The power transmission device according to claim 1 , wherein the first resonator has a parallel resonance circuit including a coil and a capacitor, and, if the physical quantity in the third resonator is an input inductance value of the third resonator, the foreign object detector is operative to: measure i) an input inductance value Lin(f 10 ) of the third resonator that is produced when the oscillator is oscillating at the frequency f 10 and ii) an input inductance value Lin(f 20 ) of the third resonator that is produced when the oscillator is oscillating at the frequency f 20 ; calculate a ratio between the Lin(f 10 ) and the Lin(f 20 ); and determine whether or not the foreign object is present based on the calculated ratio. 12. The power transmission device according to claim 1 , wherein the first resonator has a parallel resonance circuit including a coil and a capacitor, the square of an oscillation frequency of the oscillator is inversely proportional to the input inductance value of the third resonator, when the oscillator is a self-exciting oscillator and when the p