Abstract: The present disclosure provides systems and methods for protecting switching elements in an induction heating system. A switching power loss associated with a switching element of the induction heating system can be calculated and an operating frequency of the induction heating system can be adjusted based upon the switching power loss. According to one aspect, the switching power loss can be classified into one of a plurality of threat zones based upon the magnitude of the switching power loss and the operating frequency can be adjusted based upon the threat zone into which the switching power loss is classified. According to another aspect, the switching power loss can be calculated based at least in part on a duty cycle of an output signal. The duty cycle of the output signal can provide an indication of the proximity of the operating frequency of the induction heating system to resonance.

Abstract: Systems and methods for detecting vessel presence for an induction heating apparatus are disclosed. A detector circuit generates an output signal based on a feedback signal corresponding to a signal, such as current, flowing through an induction heating coil. The output signal has low frequency components that are averaged over multiple integer periods and compared to a reference value to determine the presence or absence of a vessel on the induction heating coil.

Abstract: A method for operating an induction cooktop having multiple induction heating coils includes monitoring a characteristic of the heating coils indicative of audible noise generated by simultaneous operation of multiple induction heating coils. Upon indication of audible noise from the monitored characteristic, an operating characteristic of at least one of the induction heating coils is varied so as to change the audible noise into a pre-defined, stored audible noise pattern that is desirous to a consumer or user of the cooktop.

Abstract: An induction cooktop appliance system and method for controlling the induction cooktop appliance based on a cookware position is provided. A variable power signal can be applied to an induction coil from an inverter. The power signal can be driven at a test frequency and an operating frequency. An electrical signal can be detected across a shunt resistor based on the test frequency and a cookware position can be determined based on the electrical signal. The operating frequency supplied to the induction coil can be modified based on determined cookware position.

Abstract: A system and method of controlling an induction cooking appliance based on a feedback signal. A feedback signal sampling time interval may be triggered when a power control signal has a magnitude of zero. The feedback signal sample may be used to calculate a status factor and the appliance may be controlled based on the calculated status factor.

Abstract: The present disclosure provides systems and methods for protecting switching elements in an induction heating system. A switching power loss associated with a switching element of the induction heating system can be calculated and an operating frequency of the induction heating system can be adjusted based upon the switching power loss. According to one aspect, the switching power loss can be classified into one of a plurality of threat zones based upon the magnitude of the switching power loss and the operating frequency can be adjusted based upon the threat zone into which the switching power loss is classified. According to another aspect, the switching power loss can be calculated based at least in part on a duty cycle of an output signal. The duty cycle of the output signal can provide an indication of the proximity of the operating frequency of the induction heating system to resonance.

Abstract: An induction heating system includes an induction heating coil operable to inductively heat a load with a magnetic field; a detector for detecting a current through the coil and providing a current signal representative of the current; and a controller with a memory in communication with a processor. The memory includes program instructions for execution by the processor to detect a presence of the load on the induction heating coil based on a characteristic of the current signal; determine a resonant frequency of the system with the load from a characteristic of the current signal; determine operational performance characteristics of the system; and output an indication of the operational performance characteristics of the system.

Abstract: An induction cooktop appliance system and method for controlling the induction cooktop appliance based on a cookware position is provided. A variable power signal can be applied to an induction coil from an inverter. The power signal can be driven at a test frequency and an operating frequency. An electrical signal can be detected across a shunt resistor based on the test frequency and a cookware position can be determined based on the electrical signal. The operating frequency supplied to the induction coil can be modified based on determined cookware position.

Abstract: A system and method of controlling an induction cooking appliance based on a feedback signal. A feedback signal sampling time interval may be triggered when a power control signal has a magnitude of zero. The feedback signal sample may be used to calculate a status factor and the appliance may be controlled based on the calculated status factor.

Abstract: A method for operating an induction cooktop having multiple induction heating coils includes monitoring a characteristic of the heating coils indicative of audible noise generated by simultaneous operation of multiple induction heating coils. Upon indication of audible noise from the monitored characteristic, an operating characteristic of at least one of the induction heating coils is varied so as to change the audible noise into a pre-defined, stored audible noise pattern that is desirous to a consumer or user of the cooktop.

Abstract: Systems and methods for detecting vessel presence and circuit resonance for an induction heating apparatus are disclosed. A detector circuit generates an output signal based on a feedback signal corresponding to a signal, such as current, flowing through an induction heating coil. The output signal has a duty cycle corresponding to the proximity of operating frequency of the induction heating apparatus to resonance. Changes in the duty cycle of the output signal can be monitored to determine the presence or absence of a vessel on the induction heating coil.