Sub-regions within one or more face images are identified within a digital image, and enhanced by applying an artificial glint symmetrically and/or synchronously to image data corresponding to sub-regions of eyes within the face image. An enhanced face image is generated including an enhanced version of the face that includes certain original pixels in combination with pixels corresponding to the one or more eye regions of the face with the artificial glint.

Processing for judging whether a face is included in a frame is performed, in a predetermined interval, on each of frames included in a moving image of a subject, displayed on a monitor, until the judgment becomes positive. If it is judged that a face is included in a frame, the facial position is detected in the frame, and stored. Then, judgment is made as to whether a face is included in the next frame after predetermined time. If the judgment is positive, the facial position is detected. The previously stored facial position is replaced by the newly detected facial position, and the newly detected facial position is stored. These processes are repeated until photographing operation is performed by operating a release unit.

Processing for judging whether a face is included in a frame is performed, in a predetermined interval, on each of frames included in a moving image of a subject, displayed on a monitor, until the judgment becomes positive. If it is judged that a face is included in a frame, the facial position is detected in the frame, and stored. Then, judgment is made as to whether a face is included in the next frame after predetermined time. If the judgment is positive, the facial position is detected. The previously stored facial position is replaced by the newly detected facial position, and the newly detected facial position is stored. These processes are repeated until photographing operation is performed by operating a release unit.

Techniques for capturing images are described. In one scenario, one or more processors of an imaging device can obtain geodata information and time information associated with the imaging device. The geodata and time information is obtained prior to capturing a first image. Next, one or more second images can be identified from a database of images based on the geodata information and the time information. The processor(s) can be communicatively coupled to the database via a communications network. Additionally, the one or more processors can determine one or more image capture conditions associated with the one or more second images; and automatically modify one or more settings of the imaging device to be used for capturing the first image. The settings can be modified based on at least one of the one or more image capture conditions associated with the one or more second images. Other embodiments are possible.

Sub-regions within one or more face images are identified within a digital image, and enhanced by applying an artificial glint symmetrically and/or synchronously to image data corresponding to sub-regions of eyes within the face image. An enhanced face image is generated including an enhanced version of the face that includes certain original pixels in combination with pixels corresponding to the one or more eye regions of the face with the artificial glint.

A method, a system, and computer program product for correcting image artifacts in image data captured by a camera sensor in conjunction with a flash. The method includes extracting, from a buffer, an image data captured by at least one camera sensor. The method then includes determining, from a metadata of the image data, a face in the image data and a position of a first eye and a second eye. The method then includes selecting at least one region of interest around at least one of the first and the second eye based on a size of the face and a distance between the eyes. In response to selecting the at least one region of interest, at least one correction is applied to the at least one region of interest to reduce or eliminate the appearance of at least one image artifact in the image data.

A method, a system, and computer program product for correcting image artifacts in image data captured by a camera sensor in conjunction with a flash. The method includes extracting, from a buffer, an image data captured by at least one camera sensor. The method then includes determining, from a metadata of the image data, a face in the image data and a position of a first eye and a second eye. The method then includes selecting at least one region of interest around at least one of the first and the second eye based on a size of the face and a distance between the eyes. In response to selecting the at least one region of interest, at least one correction is applied to the at least one region of interest to reduce or eliminate the appearance of at least one image artifact in the image data.

A image manipulation technique allows a user to correct an image using samples obtained from other images. These samples may be obtained from one or more other images in a library of images. Matching techniques may identify an image that best matches the image to be corrected, or may aggregate or average multiple images that are identified as containing an area corresponding to the area to be corrected. Identification of the image or images to use as the source of the samples may be automatic or manual. The images may be from a library of images under the control of the user or from a library of images maintained by another person or service provider. Application of the samples to correct the image may be manually or automatically directed.

A digital camera has an integral flash and stores and displays a digital image. Under certain conditions, a flash photograph taken with the camera may result in a red-eye phenomenon due to a reflection within an eye of a subject of the photograph. A digital apparatus has a red-eye filter which analyzes at least one partial face region identified within the digital image for the red-eye phenomenon and modifies the image to eliminate the red-eye phenomenon by changing the red area to black. The modification of the image is enabled when a photograph is taken under conditions indicative of the red-eye phenomenon. The modification is subject to anti-falsing analysis which further examines the area around the red-eye area for indicia of the eye of the subject. The detection and correction can be optimized for performance and quality by operating on subsample versions of the image when appropriate.

An image processing device for correcting at least a portion of a face image containing a person's face, includes an image acquisition unit that acquires a face image, a region extractor that extracts a pupil region containing a pupil from the face image, a determination unit that determines a presence or absence of halation in the pupil region, a first template acquisition unit that acquires a first template image which is a correction template image, a reference color acquisition unit that acquires a reference color corresponding to the person from the face image, a second template acquisition unit that generates a second template image using the first template image and the reference color, and a correction unit that composites the second template image with at least the region in the pupil region where the halation occurred to correct the halation.