Operating a cooking appliance

The invention claimed is: 1. A method for operating a cooking appliance, said method comprising: irradiating a cooking compartment of the cooking appliance by sequentially emitting a first light pulse of a first wavelength range at a first time and a second light pulse of a second wavelength range at a second time; capturing, by a camera, a first image corresponding to the first wavelength range of light reflected in the cooking compartment at the first time and a second image corresponding to the second wavelength range of light reflected in the cooking compartment at the second time; optically recognizing, by a control device, a food object within the cooking compartment based on a combined camera image formed using the first image and the second image; optically identifying, by the control device, a first pixel subregion associated with the food object; optically recognizing, by the control device, a cooking compartment wall within the cooking compartment based on the combined camera image; optically identifying, by the control device, a second pixel subregion associated with the cooking compartment; spectroscopically evaluating, by the control device, the first pixel subregion using the first image and the second image; spectroscopically evaluating, by the control device, the second pixel subregion using the first image and the second image; determining, by the control device, a degree of browning of the food object based on the optical recognition and the spectroscopic evaluation of the first pixel subregion; determining, by the control device, a degree of soiling of the cooking compartment wall based on the optical recognition and the spectroscopic evaluation of the second pixel subregion; automatically controlling the cooking appliance, by the control device, to perform an action based on the degree of browning as determined by a combination of the optical evaluation and the spectroscopic evaluation; and automatically controlling the cooking appliance, by the control device, to perform an action based on the degree of soiling of the cooking compartment wall. 2. The method of claim 1 , wherein spectroscopically evaluating includes, for each of one or more subregions of a pixel sensor array of the camera, combining respective intensities sensed by each pixel of the subregion to obtain a combined sensed intensity corresponding to the subregion. 3. The method of claim 1 , wherein the camera is positioned to sense predominantly light reflected diffusely in the cooking compartment. 4. The method of claim 1 , wherein at least one of the first and second wavelength ranges is an infrared wavelength range. 5. The method of claim 4 , wherein the infrared wavelength range includes near-infrared wavelengths. 6. The method of claim 1 , further comprising recognizing an object within the cooking compartment as a food container. 7. The method of claim 6 , further including identifying a material of the food container based on the spectroscopic evaluation, and wherein automatically controlling the cooking appliance to perform an action includes causing the cooking appliance to stop a cooking process. 8. The method of claim 1 , further comprising: irradiating a cooking compartment of the cooking appliance by sequentially emitting a third light pulse of a third wavelength range at a third time; capturing, by a camera, a third image corresponding to the third wavelength range; of light reflected in the cooking compartment at the third time; wherein the first wavelength range is a visible red range of light, the second wavelength range is a visible blue range of light, and the third wavelength range is a visible green range of light; and wherein the combined camera image is a white light image formed using the first image, the second image, and the third image. 9. The method of claim 1 , wherein the spectroscopic evaluation includes comparing wavelength-dependent pixel intensities. 10. A cooking appliance, comprising: a cooking compartment including a first wall; a plurality of light sources, each configured to radiate light pulses of a different respective wavelength range into the cooking compartment; a light sensor configured to capture at least one image corresponding to each of the wavelength ranges reflected in the cooking compartment, to optically recognize a food object and the first wall of the cooking compartment in the at least one image, and to determine pixels associated with the food object and the first wall of the cooking compartment; a spectroscopic evaluation device configured to determine a degree of browning of the food object by executing a spectroscopic evaluation of light measured selectively in relation to the wavelength ranges using the pixels associated with the recognized food object, and to determine a degree of soiling of the first wall of the cooking compartment by executing a spectroscopic evaluation of light measured selectively in relation to the wavelength ranges using the pixels associated with the first wall of the cooking compartment; and a control device configured to control the cooking appliance depending on the degree of browning of the food object as indicated by a result of the combined spectroscopic and optical recognitions and to control the cooking appliance depending on the degree of soiling of the first wall of the cooking compartment as indicated by a result of the combined spectroscopic and optical recognitions; wherein the control device is configured to actuate the light sources sequentially; and wherein the control device is further configured to synchronize emission of light by the plurality of light sources and image recording by the light sensor such that each light pulse corresponds to a respective image. 11. The cooking appliance of claim 10 , wherein the plurality of light sources are configured to generate light of two or more IR wavelength ranges. 12. The cooking appliance of claim 10 , wherein two of the plurality of light sources are configured to generate light of different respective IR wavelength ranges. 13. The cooking appliance of claim 10 , wherein the spectroscopic evaluation devices is integrated into the control device. 14. The cooking appliance of claim 10 , wherein the plurality of light sources are disposed adjacent the first wall of the cooking compartment and the light sensor is disposed adjacent a second wall of the cooking compartment, such that the light sensor receives only diffusely reflected light. 15. A method of operation of a cooking appliance having a cooking compartment, the method comprising: capturing a first image of first light reflected in a cooking compartment when the cooking compartment is illuminated by light having a first wavelength range; capturing a second image of second light reflected in the cooking compartment when the cooking compartment is illuminated by light having a second wavelength range; identifying a food object within the cooking compartment based on object recognition performed on a combined camera image formed by the first image and the second image; identifying a cooking compartment wall within the cooking compartment based on object recognition performed on the combined camera image; determining pixels associated with the food object and with the cooking compartment wall; spectroscopically evaluating wavelength-dependent intensities corresponding to pixels associated with the food object of the first image and second image; spectroscopically evaluating wavelength-dependent intensities corresponding to pixels associated with the cooking compartment wall of the first image and the sec