A microwave cooking appliance performs controlled beverage warming using a temperature sensor to capture a thermal image of a beverage in a cooking cavity. One or more sensing locations within the thermal image that are suitable for determining the temperature of the beverage are determined in part by ordering temperature readings from the thermal image by temperature to determine a temperature function and then determining locations in the thermal image that correspond to the beverage by calculating a derivative function over at least a portion of the temperature function.

Apparatuses and methods are provided for processing an object in a cavity. The apparatuses include at least one radio frequency (RF) energy supply component configured to supply RF energy for application to one or more radiating elements configured to emit RF radiation in response to the applied RF energy. In some embodiments, a provided apparatus also includes a memory storing a set of coefficients associated with the RF energy supply component; and a processor configured to receive feedback in response to emission of RF radiation by the one or more radiating elements and control application of RF energy to one or more of the radiating elements based on the feedback and the set of coefficients.

An apparatus for roasting coffee beans comprises a roasting chamber for containing coffee beans. The roasting chamber is positioned within a resonant cavity of a waveguide. A microwave emitter produces microwave energy within the waveguide with one or more stable high intensity microwave regions within the roasting chamber to heat the coffee beans in the roasting chamber to a temperature sufficient to roast the coffee beans. A device configured to move the coffee beans within the one or more high intensity microwave regions is coupled to the roasting chamber.

An apparatus for applying EM energy to a load may include at least one processor configured to receive information indicative of dissipated energy for each of a plurality of modulation space elements and group a number of the plurality of modulations space elements into at least two subsets based on the information received indicative of dissipated energy. The processor may also be configured to associate a power delivery protocol with each of the at least two subsets wherein the power delivery protocol differs between subsets and regulate energy applied to the load in accordance with each power delivery protocol.

The present disclosure provides a microwave oven, and a thawing control method and device for the same. The method includes: detecting temperatures of a plurality of temperature detecting points on food in the microwave oven; and controlling the microwave generator to start, and thawing the food according to the temperatures of the plurality of temperature detecting points on the food. With the method, the thawed food is more nutritious, healthier, and easier to cut, and has the low temperature difference, without a cooked discoloration phenomenon.

A microwave oven includes a controller in communication with an infrared sensor and a human-machine interface, the controller configured: (i) to determine a temperature at each position of a cavity as a function of the output of each pixel of the infrared sensor; (ii) to recognize a rise and fall in the temperature at one or more positions within the cavity; (iii) to estimate the position or positions within the cavity that a food item occupies as a function of the one or more positions within the cavity where the controller recognized the rise and fall in temperature occurred; and (iv) to determine whether the position or positions that the food item is estimated to occupy is adequate for the controller to determine accurately a temperature of the food item during an automatic heating operation that utilizes the infrared sensor.

Several embodiments include a cooking appliance/instrument (e.g., oven). The cooking appliance/instrument can include a cooking chamber, a support tray adapted to hold food in the cooking chamber; and a heating system comprised of at least a heating element. The heating system is adapted to emit waves according to a particular configuration such that the emitted waves is substantially transparent or substantially opaque to the support tray and thus enabling the cooking instrument to select what to heat.

This disclosure includes an electronic oven and an accompanying control system that avoid boiling or splattering in a heating chamber of the oven while an item is being heated in the chamber. A disclosed method which can be executed by the control system includes evaluating sensor data from a visible light sensor and sensor data from an infrared light sensor. The controller is communicatively coupled to the visible light sensor and the infrared light sensor. The method is directed towards generating a splatter prediction in response to the evaluation of the sensor data from the visible light sensor and the sensor data from the infrared light sensor. The method is further directed towards decreasing a power level of the microwave energy source in response to the splatter prediction. The controller is also communicatively coupled to the microwave energy source.

Systems and methods for user configurable cooking appliances include receiving system resources having associated budgets, facilitating user allocation the system resources to a plurality of heating elements without exceeding the associate budgets, applying the system resources to the heating elements to heat one or more food substances within a cooking chamber, and selectively regulating delivery of the system resources to the heating elements such that no more than the associated budget of each of the system resources is delivered to the heating elements. Computing components can execute a heating algorithm to cook at least one food substance in the cooking chamber, detect a state change of the food substance, and modify the heating algorithm to reconfigure the system resources supplied to the heating elements in response to the state change and in accordance with user configured allocation and associated budgets for the system resources.

A microwave oven container may include a body for containing a liquid, an agitator projecting through a bottom wall of the body to agitate the liquid contained in the body, where the agitator includes a first end located in the body and a second end located exterior to the body. The second end of the agitator is able to couple with a turntable drive of a microwave oven to power movement of the agitator in response to rotation of the turntable drive. The container may also include a cage located within the body that substantially surrounds the first end of the agitator and includes a plurality of openings to allow liquid contained in the body to pass through the cage.