Provided is a cooking device capable of being provided with a radio communication device so that the radio communication device establishes a satisfactory communication, instead of (i) further providing any special configuration in which the radio communication device is provided and (ii) making any change in structure of the cooking device. According to a cooking device (1), a space for providing a radio communication adapter is secured in a frame (3b) of a door (3) or in a circuit storing section (50), made of a nonmetal, which is configured to store a driving circuit of a display operation section (5).

Systems and methods include a cooking appliance comprising a heating element disposed within a cooking chamber and operable to selectively emit waves at any of a plurality of powers and/or peak wavelengths, a camera operable to capture an image of the cooking chamber, and a computing device operable to supply power to the heating element to vary the power and/or peak wavelength of the emitted waves and generate heat within the cooking chamber, and instruct the camera to capture the image when the heating element is emitting at a stabilized power and/or peak wavelength. The computing device is operable to generate an adjusted captured image by adjusting the captured image with respect to the stabilized power and/or peak wavelength. The computing device comprises feedback components operable to receive the adjusted captured image, extract features, and analyze the one or more features to determine an event, property, measurement and/or status.

A terminal includes a storage in which control method information is stored, the control method information indicating a relationship between each of a plurality of heating methods of an ingredient and each of a plurality of corresponding control methods for reducing heating power of a cooking appliance; and a controller that, in a case where the absence of a user of the cooking appliance from a kitchen is detected for a predetermined period of time during execution of one of the plurality of heating methods, determines a first control method corresponding to the one of the plurality of heating methods based on the control method information stored in the storage and then causes the cooking appliance to execute the first control method. The first control method is a method for reducing the heating power used in the one of the plurality of heating methods.

A heating cooking system includes a cooking device (100), servers (400, 500) for communicating with the cooking device (100) via a communication network and an information terminal (300) for communicating with the servers (400, 500) via the communication network. The servers (400, 500) have a communication tool manager (400) for managing communication tools of the information terminal (300) for users. The cooking device (100) has posting sections for posting information relating to executed cooking menus to the communication tool manager (400) of the servers (400, 500) via the communication network (N).

A information processor of a terminal apparatus reads from a memory identification information of a food handling apparatus and a table, identifies a function associated with the identification information of the food handling apparatus received by a information receiver in accordance with the table, and starts up the function.

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.

An IoT-based system and method are described for identifying appropriate cooking parameters for cooking food. For example, one embodiment of a system comprises: a cooking appliance for cooking food products, the cooking appliance having control logic to control cooking temperature or power level, cooking duration, and/or one or more other cooking variables; an IoT device integrated in or on the cooking appliance, the IoT device comprising scanning logic to capture a code associated with a food product to be cooked, the IoT device to use the code to identify cooking parameters associated with the food product; and the IoT device comprising circuitry to control the control logic of the cooking appliance in accordance with the cooking parameters associated with the food product.

A cooking apparatus includes a cooking chamber, a cooking plate having a visual representation distinguishing a plurality of areas on a top surface of the cooking plate, a plurality of heaters configured to supply heat to the plurality of areas and a controller configured to receive information about a cooking object including a plurality of pieces of food having different cooking conditions, based on the information about the cooking object, determine a first heating intensity to be used to heat the first piece of the food, and a second heating intensity to be used to heat the second piece of the food, control the plurality of heaters to supply heat of the first heating intensity to the first area, and control the plurality of heaters to supply heat of the second heating intensity to the second area.

A selective heating device comprises a chamber configured to contain a target to be at least partially heated, an active electromagnetic (EM) element to generate an electromagnetic field in the chamber and a passive EM element in the chamber. The passive EM element is capable of electromagnetically coupling to the active element. The active EM element and passive EM element are controllable to selectively heat a portion of the target.

A food preparation appliance includes a processing mechanism, a thermal element, a sensor positioned to acquire identifying data regarding identifying characteristics of a food product to be processed by the food preparation appliance, and a processing circuit. The processing circuit is configured to receive the identifying data from the sensor, identify a type of the food product based on the identifying data, and automatically set a predefined operating parameter of at least one of the processing mechanism and the thermal element to provide target processing of the food product based on the type and the identifying characteristics.