Induction heating system

The invention claimed is: 1 . An induction heating appliance, comprising: a surface defining a plurality of different heating zones comprising at least a first heating zone and a second heating zone, wherein the first heating zone and the second heating zone are disposed in different locations on the surface; a dispenser, wherein the first heating zone is closer to the dispenser than the second heating zone; a plurality of induction coils including a first induction coil and a second induction coil, wherein the first induction coil is positioned to individually heat the first heating zone of the surface, wherein the second induction coil is positioned to individually heat the second heating zone of the surface; a plurality of capacitors including a first capacitor and a second capacitor, wherein the first induction coil is electrically connected in series with the first capacitor to form a first resonant circuit and the second induction coil is electrically connected in series with the second capacitor to form a second resonant circuit; a plurality of resonant circuit power switches including a first resonant circuit power switch and a second resonant circuit power switch, wherein the first resonant circuit is electrically connected in series with first resonant circuit power switch to form a first power branch and the second resonant circuit is electrically connected in series with the second resonant power switch to form a second power branch; a single power inverter including at least two power inverter switches, wherein the first power branch and the second power branch are electrically connected in parallel with the at least two power inverter switches of the single power inverter; a first switch driver coupled to the first resonant circuit power switch and the second resonant circuit power switch; a second switch driver coupled to the power inverter switch; and a controller coupled to the first switch driver and the second switch driver, the controller configured to provide signals to the first switch driver and the second switch driver to control a turn-on time of the first resonant circuit power switch, the second resonant circuit power switch, and the at least two power inverter switches to independently control a first temperature of the first heating zone and a second temperature of the second heating zone; wherein the controller is configured to engage the single power inverter such that the first induction coil maintains a temperature at the first heating zone that is greater than the temperature maintained by the second induction coil at the second heating zone. 2 . The induction heating appliance of claim 1 , further comprising a sensor coupled to the controller and configured to provide signals to the controller, wherein the controller is configured to determine the presence or absence of a food vessel within the first heating zone or the second heating zone based on the signals provided to the controller. 3 . An induction heating system, comprising: a plurality of induction coils including a first induction coil and a second induction coil; a plurality of capacitors, wherein the first induction coil and the second induction coil are each electrically connected in series with one of the plurality of capacitors to form a resonant circuit; a plurality of resonant circuit power switches, wherein the resonant circuit of the first induction coil and the resonant circuit of the second induction coil are each electrically connected in series with a single one of the plurality of resonant circuit power switches to form at least two power branches; a single power inverter including at least two power inverter switches, wherein the at least two power branches are electrically connected in parallel with the at least two power inverter switches of the single power inverter; and a controller configured to: provide a signal to at least one of (a) the at least two power inverter switches or (b) the plurality of resonant circuit power switches to selectively and individually adjust a temperature associated with the plurality of induction coils; determine a type of material of a vessel disposed in proximity with the first induction coil; and determine the type of material of the vessel based on (a) a phase angle between signal and a current draw of the first induction coil and (b) an amplitude of the current draw of the first induction coil. 4 . The induction heating system of claim 3 , wherein the single power inverter comprises half-bridge topology. 5 . The induction heating system of claim 3 , wherein the single power inverter comprises full-bridge topology. 6 . The induction heating system of claim 3 , wherein the controller is configured to control an on time of at least one of the at least two power switches and thereby control the temperature associated with the respective induction coil. 7 . The induction heating system of claim 3 , wherein the inductance of at least one of the plurality of induction coils is 25-250 microhenries. 8 . The induction heating system of claim 3 , further comprising at least one driver part, wherein the driver part is connected with the resonant circuit power switch in the power branch, wherein the driver part is configured to receive the control signal from the controller and vary the turn-on time of the resonant circuit power switch to regulate the output power of the power branch. 9 . The induction heating system of claim 3 , wherein the at least two power inverter switches facilitate regulating the switching frequency of the single power inverter. 10 . The induction heating system of claim 9 , further comprising a driver part, wherein the driver part connects with the at least two power inverter switches in the single power inverter, wherein the driver part is configured to receive the control signal from the controller and vary the switching frequency of the single power inverter. 11 . The induction heating system of claim 3 , further comprising a plurality of current sensors, wherein each current sensor is configured to detect the current of the induction coils. 12 . The induction heating system of claim 11 , further comprising a signal conditioning circuit, wherein the signal conditioning circuit is configured to transfer the analog signal from the current sensors to digital signals. 13 . An induction heating system, comprising: a plurality of induction coils including a first induction coil and a second induction coil; a plurality of capacitors, wherein the first induction coil and the second induction coil are each electrically connected in series with one of the plurality of capacitors to form a resonant circuit; a plurality of resonant circuit power switches, wherein the resonant circuit of the first induction coil and the resonant circuit of the second induction coil are each electrically connected in series with a single one of the plurality of resonant circuit power switches to form at least two power branches; a single power inverter including at least two power inverter switches, wherein the at least two power branches are electrically connected in parallel with the at least two power inverter switches of the single power inverter; a controller configured to provide a signal to at least one of (a) the at least two power inverter switches or (b) the plurality of resonant circuit power switches to selectively and individually adjust a temperature associated with the plurality of induction coils; a plurality of current sensors, wherein each current sensor is configured to detect the current of the induction coils; a signal conditioning circuit, wherein the signal co