An image processing apparatus includes a reference value acquisition unit, an image processing unit, and a threshold specification unit. The reference value acquisition unit acquires a reference value to become a reference of brightness from a facial area of a human contained in a captured image. The image processing unit divides the facial area of the human into multiple exclusive portions. The threshold specification unit specifies a threshold for brightness used for the division into the multiple portions by the image processing unit based on the reference value acquired by the reference value acquisition unit. The image processing unit performs processing of correcting brightness in all the multiple divided portions by applying different correction modes.

A spectral imaging device is configured to capture color images synchronized with controlled illumination from different color light emitting diodes. A processor in the device applies a coupling factor to sampled color images to convert sampled pixels into spectral channels corresponding to LED color and color filter. Multi-spectral spectricity vectors produced at pixel locations are used along with spatial information to classify objects, such as produce items.

To allow re-producing, in another image processing apparatus, contents of image processing in an image processing apparatus, a provisional color grading apparatus 300 determines normalizing points (CodeValues that serve as references for normalizing) of input image signals according to format information and normalizes the input image signals. The provisional color grading apparatus 300 records values (normalizing information) obtained by converting the normalizing points into numerical values independent of devices, in association with parameters of color grading.

An aberration correction apparatus includes an aberration information acquisition unit which acquires aberration information from an imaging lens; a spectroscopic characteristic information acquisition unit which acquires spectroscopic characteristic information of an imaging device which performs a photoelectric conversion of an optical image that is formed in the imaging lens; and an aberration information correction unit which performs a correction according to the spectroscopic characteristic information with respect to the acquired aberration information.

An image processing apparatus comprising: an acquisition unit that acquires exposure information of an image signal; a setting unit that sets tone conversion characteristic based on the exposure information and visual characteristics; and a tone conversion unit that performs tone conversion on the image signal using the tone conversion characteristic. The visual characteristics is a minimum amount of luminance change that a human can recognize and that differ for different luminance, and the setting unit obtains for each luminance an intersection of a first function that indicates a ratio of an amount of luminance change per one code value difference of the image signal before the tone conversion is performed and a second function that indicates a ratio of a minimum amount of luminance change that a human can recognize, and sets the tone conversion characteristic based on the intersection.

In a high speed image capturing state, a camera signal processing circuit is not needed to perform a signal process at a high screen rate, but at a regular screen rate. In the high speed image capturing mode, raw data of 240 fps received from an image sensor 101 are recorded on a recording device 111 through a conversion processing section 201 and a recording device controlling circuit 210. Raw data that have been decimated and size-converted are supplied to a camera signal processing circuit 203 through a pre-processing circuit 202 and an image being captured is displayed on a display section 112 with a signal for which a camera process has been performed. In a reproducing state, raw data are read from the recording device 111 at a low screen rate according to a display performance of the display section 112 and the raw data that have been read are processed are processed by the pre-processing circuit 202 and the camera signal processing circuit 203 and a reproduced image is displayed by the display section 112.

A sensor device includes an array sensor in which a plurality of visible or non-visible light imaging elements is arranged in one or two dimensional manner, and an image processing unit that performs image processing using a parameter on which an instruction is given for the image signal obtained by imaging in the array sensor. In this case, a class is identified for an object detected from the image signal obtained by the imaging in the array sensor, the parameter to be used in the image processing is selected on the basis of the identified class, and a processing setting for the image processing unit is performed with the selected parameter.

There is provided a signal processor including correction circuitry configured to correct a signal for each color input to the signal processor and to output the corrected signal for each color, first conversion circuitry configured to receive the corrected signal for each color, to perform first image processing on each corrected signal for each color, and to generate a first signal having a first color gamut for each color, second conversion circuitry configured to receive the corrected signal for each color, to perform second image processing on each corrected signal for each color, and to generate a second signal having a second color gamut for each color, where the signal processor outputs a first image data having a first color gamut and a second image data having a second color gamut from same corrected signals for each color.

An electronic device includes a lens part that receives light from a subject, an image sensor that receives the light of the lens part from a group of pixels arranged two-dimensionally, and an processor that processes an image signal of the image sensor. The image sensor performs a read-out operation at a speed to prevent blurring of an image. The processor temporarily stores image data by the read-out operation in a memory, loads a plurality of images stored in the memory to generate an image, of which the number of bits is expanded compared with the image signal of the image sensor, and performs gamma processing on the image, of which the number of bits is expanded, to generate an image compressed to the same number of bits as the image signal of the image sensor.

An imaging device, an imaging method, and a recording medium storing an imaging program are provided. Each of the imaging device, imaging device, and the recording medium storing the imaging program outputs image data of an object on an image output unit, stores multiple levels of luminosity of the object in a memory in association with a plurality of set values that are referred to when image processing is performed on image data, specifies the level of luminosity of the object, selects one of the set values stored in the memory based on the level of luminosity specified by the specifying, and performs image processing on the image data output from the image output unit, based on the set value selected by the selecting.