Induction cooker

The invention claimed is: 1. An induction cooker comprising: a first coil; a second coil disposed on an outer peripheral side of the first coil, a third coil disposed on an outer peripheral side of the second coil; a first inverter circuit configured to supply a first high-frequency current to the first coil; a second inverter circuit configured to supply a second high-frequency current to the second coil; a third inverter circuit configured to supply a third high-frequency current to the third coil; and a controller configured to control driving of the first inverter circuit, the second inverter circuit and the third inverter circuit, determine whether a heating target is formed of a composite in which the heating target placed above the first coil is detected from the first inverter circuit as formed of a magnetic material, the heating target placed above the second coil is detected from the second inverter circuit as formed of a magnetic material or a composite containing a magnetic material and a non-magnetic material, and the heating target placed above the third coil is detected from the third inverter circuit as formed of a non-magnetic material, and responsive to determining that the heating target is formed of the composite: stop operation of the first inverter circuit to promote an even heating temperature, cause the second inverter circuit and the third inverter circuit to operate, and set a frequency of the third high-frequency current to be higher than a frequency of the second high-frequency current. 2. The induction cooker of claim 1 , wherein the controller sets electric power to be supplied to the second coil from the second inverter circuit and electric power to be supplied to the third coil from the third inverter circuit to be equal to each other. 3. The induction cooker of claim 1 , wherein when the heating target placed above the first coil, the second coil and the third coil is formed of a magnetic material, the controller causes the first inverter circuit and the third inverter circuit to operate, and stops operation of the second inverter circuit. 4. The induction cooker of claim 3 , wherein the controller sets electric power to be supplied to the third coil from the third inverter circuit to be larger than electric power to be supplied to the first coil from the first inverter circuit. 5. The induction cooker of claim 3 , wherein the controller sets a ratio of electric power per unit area of the third coil to be equal to a ratio of electric power per unit area of the first coil. 6. The induction cooker of claim 1 , wherein the controller sets the frequency of the second high-frequency current to be higher than a frequency of the first high-frequency current, and to be lower than the frequency of the third high-frequency current. 7. The induction cooker of claim 1 , wherein the controller sets the frequency of the second high-frequency current to be higher than a frequency of the first high-frequency current by not less than an audible frequency, and to be lower than the frequency of the third high-frequency current by not less than the audible frequency. 8. The induction cooker of claim 1 , further comprising: a top plate on which a heating zone is formed, the heating zone indicating a placement position on which the heating target is to be placed, wherein the first coil is disposed at a center of the heating zone, and the second coil and the third coil are disposed concentrically with the first coil. 9. The induction cooker of claim 1 , wherein a switching element of at least one of the first inverter circuit, the second inverter circuit, and the third inverter circuit is formed of a wide-bandgap semiconductor material. 10. The induction cooker of claim 1 , further comprising: a fourth coil disposed on an outer peripheral side of the third coil; and a fourth inverter circuit configured to supply a fourth high-frequency current to the fourth coil, wherein when the heating target placed above the first coil is formed of a magnetic material, the heating target placed above the second coil is formed of a magnetic material or a composite containing a magnetic material and a non-magnetic material, the heating target placed above the third coil is formed of a magnetic material or a composite containing a magnetic material and a non-magnetic material, and the heating target placed above the fourth coil is formed of a non-magnetic material, the controller stops the operation of the first inverter circuit, causes the second inverter circuit, the third inverter circuit, and the fourth inverter circuit to operate, and sets a frequency of the fourth high-frequency current to be higher than the frequency of the second high-frequency current and the frequency of the third high-frequency current. 11. The induction cooker of claim 10 , wherein when the heating target placed above the first coil, the second coil, the third coil and the fourth coil is formed of a magnetic material, the controller causes the first inverter circuit and the fourth inverter circuit to operate, and stops operation of at least one of the second inverter circuit and the third inverter circuit. 12. An induction cooker comprising: a top plate on which a heating zone is formed, the heating zone indicating a placement position on which a heating target is to be placed; a plurality of coils provided for the heating zone such that three or more coils are provided for one heating zone; a plurality of inverter circuits configured to supply a high-frequency current to each of the plurality of coils; and a controller configured to control driving of each of the plurality of inverter circuits, determine whether the heating target is formed of a composite in which materials of the heating target placed above the plurality of coils are in order of a magnetic material, a magnetic material or a composite containing a magnetic material and a non-magnetic material, and a non-magnetic material from an inner peripheral side toward an outer peripheral side of the heating zone, and responsive to determining that the heating target is formed of the composite: stop operation of the inverter circuit for the coil disposed on an innermost peripheral side to promote an even heating temperature, cause, to operate, at least one of the inverter circuit for the coil above which the heating target formed of a magnetic material is disposed and the inverter circuit for the coil above which the heating target formed of a composite containing a magnetic material and a non-magnetic material is disposed, cause, to operate, the inverter circuit for the coil above which the heating target formed of a non-magnetic material is disposed, and set a frequency of the high-frequency current of the inverter circuit for the coil above which the heating target formed of a non-magnetic material is disposed to be higher than a frequency of the high-frequency current of the inverter circuit for the coil above which the heating target formed of a magnetic material or a composite containing a magnetic material and a non-magnetic material is disposed. 13. The induction cooker of claim 12 , wherein when the heating target placed above the coils being three or more coils disposed adjacent to each other is formed of a magnetic material, the controller causes, to operate, the inverter circuit for the coil disposed on an innermost peripheral side out of the coils above which the heating target formed of a magnetic material is placed and, to operate, the inverter circuit for the coil disposed on an outermost peripheral side out of the co