Detector, power transmitter, power receiver, power feed system, and detection method

The invention claimed is: 1. A detector comprising a detecting circuit configured to determine a value of a Q factor or a degree of variation of the value of the Q factor in a first circuit including a first coil configured to electromagnetically couple with an external object, and to detect whether the external object is present in the vicinity of the first coil; determination circuitry configured to determine, in a case where the detecting circuit detects that the external object is present in the vicinity of the first coil, whether the external object is a second circuit including a second coil or is another conductor based on a comparison of the determined value of the Q factor or the determined degree of variation of the value of the Q factor with a predetermined threshold, and configured to generate a control signal indicating a result of the determination; and communication control circuitry configured to selectively begin a non-contact power transmission to the external object in response to the control signal, wherein the value of the Q factor or the degree of variation of the value of the Q factor is determined based on a ratio of voltages or an impedance, and wherein the predetermined threshold corresponds to a value of the Q factor in the first circuit under a condition that neither the other conductor nor the second circuit are present in the vicinity of the first coil. 2. The detector according to claim 1 , wherein the detecting circuit is configured to detect whether the external object is present in the vicinity of the first coil using a state of the electromagnetic coupling with the external object. 3. The detector according to claim 2 , wherein the determination circuitry is configured to determine whether the external object is the other conductor or the second circuit based on a result of determining whether communication with the external object via the first coil is possible. 4. The detector according to claim 3 , wherein the determination circuitry is configured to decide that the external object is the second circuit when it is determined that the communication with the external object is possible, and to decide that the external object is the other conductor when it is determined that the communication with the external object is not possible. 5. The detector according to claim 3 , wherein in a case where the presence of the external object in the vicinity of the first coil is detected, the detecting circuit is configured to instruct the communication control circuitry to output a transmission signal to the external object and to determine whether the communication with the external object is possible depending on the presence or absence of a response to the transmission signal. 6. The detector according to claim 5 , wherein the detecting circuit is configured to determine that the communication with the external object is possible when there is a response to the transmission signal, and to determine that the communication with the external object is not possible when there is no response to the transmission signal. 7. The detector according to claim 1 , wherein the detecting circuit includes: arithmetic processing circuitry configured to calculate the value of the Q factor or the degree of variation of the value of the Q factor; and the determination circuitry, the determination circuitry being further configured to determine a state of the electromagnetic coupling with the external object by comparing the value of the Q factor or the degree of variation of the value of the Q factor that is calculated by the arithmetic processing a circuitry with the predetermined threshold. 8. The detector according to claim 7 , wherein the first circuit is a resonant circuit including the first coil and a capacitor, and the arithmetic processing circuitry is configured to calculate the value of the Q factor in the resonant circuit from a ratio of a first voltage between the first coil and the capacitor in the resonant circuit to a second voltage across the first coil in the resonant circuit. 9. The detector according to claim 7 , wherein the first circuit is a resonant circuit including the first coil and a capacitor, and the arithmetic processing circuitry is configured to calculate the value of the Q factor in the resonant circuit by using a half-value width method in the resonant circuit. 10. The detector according to claim 9 , wherein the resonant circuit is a series resonant circuit, and the arithmetic processing circuitry is configured to calculate the value of the Q factor in the series resonant circuit using the half-value width method based on a resonant frequency in the series resonant circuit and a bandwidth frequency at which an impedance of √2 times as much as an absolute value for an impedance at the resonant frequency is achieved. 11. The detector according to claim 9 , wherein the resonant circuit is a parallel resonant circuit, and the arithmetic processing circuitry is configured to calculate the value of the Q factor in the parallel resonant circuit using the half-value width method based on a resonant frequency in the parallel resonant circuit and a bandwidth frequency at which an impedance of (1/√2) times as much as an absolute value for an impedance at the resonant frequency is achieved. 12. The detector according to claim 7 , wherein the first circuit is a resonant circuit including the first coil and a capacitor, and the arithmetic processing circuitry is configured to determine a real part component and an imaginary part component of an impedance in the resonant circuit using an automatic balanced bridge circuit and a vector ratio detector, and to calculate the value of the Q factor in the resonant circuit from a ratio of the real part component to the imaginary part component. 13. The detector according to claim 1 , wherein the detecting circuit is configured to perform detection concerning a state of the electromagnetic coupling with the external object by the combined use of the value of the Q factor in the circuit and one of an L value in the circuit and a value of a coupling factor k in the event of the electromagnetic coupling. 14. A power transmitter, comprising: a power transmitting coil configured to electromagnetically couple with an external object; a power transmitting section configured to perform power transmission using the power transmitting coil; a detecting circuit configured to determine a value of a Q factor or a degree of variation of the value of the Q factor in a first circuit including the power transmitting coil, and to detect whether the external object is present in the vicinity of the power transmitting coil; determination circuitry configured to determine, in a case where the detecting circuit detects that the external object is present in the vicinity of the first power transmitting coil, whether the external object is a second circuit including a second coil or is another conductor based on a comparison of the determined value of the Q factor or the determined degree of variation of the value of the Q factor with a predetermined threshold, and configured to generate a control signal indicating a result of the determination; and communication control circuitry configured to selectively begin a non-contact power transmission to the external object in response to the control signal, wherein the value of the Q factor or the degree of variation of the value of the Q factor is determined based on a ratio of voltages or an impedance, and wherein the predetermined threshold corresponds to a value of the Q factor in the first circuit under a condition that neither