A fast face capture system and process for identifying an individual as the individual walks through a designated area is described. A set of raw images is streamed from at least one camera for detecting individuals entering the designated area. The images are searched for a face. If a face is detected, a tracking ID is assigned; and a timer and face tracking is commenced to obtain a sequence of candidate images for each individual as the individual walks through the designated area. A maximum quality image is selected from the sequence of candidate images for each individual based on at least one quality metric, the elapsed time, and the quality select count in the sequence of the candidate images. The maximum quality image is submitted for matching with a verified image of the person. The invention has particular application to security check points for quickly matching the face of the moving person with a previously acquired and verified identity.

A printer-equipped camera includes an instant film pack loading unit in which an instant film pack, a first displaying unit of which a displaying surface is arranged to face an exposure surface of an instant film in the instant film pack through the exposure opening with respect to the instant film pack loaded in the instant film pack loading unit, and that exposes the instant film by displaying an image, a light exit direction restriction member that is included on the displaying surface of the first displaying unit and restricts a light exit direction of light from each pixel of the first displaying unit to a constant range, an imaging unit that captures a subject image, a second displaying unit that displays an image to an outside, a print instruction unit that provides a print instruction for the image displayed on the second displaying unit, and a displaying control unit that exposes the exposure surface of the instant film by displaying the image on the first displaying unit.

A printer-equipped camera includes an instant film pack loading unit in which an instant film pack, a first displaying unit of which a displaying surface is arranged to face an exposure surface of an instant film in the instant film pack through the exposure opening with respect to the instant film pack loaded in the instant film pack loading unit, and that exposes the instant film by displaying an image, a light exit direction restriction member that is included on the displaying surface of the first displaying unit and restricts a light exit direction of light from each pixel of the first displaying unit to a constant range, an imaging unit that captures a subject image, a second displaying unit that displays an image to an outside, a print instruction unit that provides a print instruction for the image displayed on the second displaying unit, and a displaying control unit that exposes the exposure surface of the instant film by displaying the image on the first displaying unit.

A method of reducing noise in an input image by setting, as a local window among color pixels included in the input image, a target pixel and neighboring pixels adjacent to the target pixel, determining color pixel values for the target pixel and each of the neighboring pixels included in the local window, generating local color average values are generated by averaging, color by color, the color pixel values, generating offset color pixel values by converting the color pixel values of the target pixel and the neighboring pixels based on the local color average values, and generating a compensated color pixel value of the target pixel by adjusting the color pixel value of the target pixel based on the offset color pixel values.

A method of reducing noise in an input image by setting, as a local window among color pixels included in the input image, a target pixel and neighboring pixels adjacent to the target pixel, determining color pixel values for the target pixel and each of the neighboring pixels included in the local window, generating local color average values are generated by averaging, color by color, the color pixel values, generating offset color pixel values by converting the color pixel values of the target pixel and the neighboring pixels based on the local color average values, and generating a compensated color pixel value of the target pixel by adjusting the color pixel value of the target pixel based on the offset color pixel values.

Methods and processing modules apply adaptive sharpening, for a block of input pixels for which upsampling is performed, to determine a block of output pixels. A block of upsampled pixels is obtained based on the block of input pixels. One or more range kernels is determined based on a plurality of upsampled pixels of the block of upsampled pixels. Each of the one or more range kernels is combined with a sharpening kernel to determine one or more bilateral sharpening kernels. The one or more bilateral sharpening kernels are used to determine the output pixels of the block of output pixels.

An image processing apparatus is provided. The image processing apparatus according to an example embodiment includes an input unit comprising input circuitry, and a processor configured to: perform a noise reduction process on an image input through the input unit, identify a first pixel block based on an object pixel in the input image, identify a second pixel block based on the object pixel in a denoised image, obtain a gain value based on a pixel value included in the first pixel block and a pixel value included in the second pixel block, and perform an enhancement process on the denoised image by applying the obtained gain value to the second pixel block.

An image enhancement method includes the following steps. Separating an original image signal into a high frequency image signal and a low frequency image signal by performingperforming a wavelet transform through a first transformation circuit. Separating the high frequency image signal into a high frequency separation signal and a high-intermediate frequency separation signal by performingperforming the wavelet transform through a second transformation circuit. Separating the low frequency image signal into a low-intermediate frequency separation signal and a low frequency separation signal by performingperforming the wavelet transform. Enhancing high frequency separation signal to generate an enhanced high frequency separation signal configured to enhance the sharpness of an image. Through a inverse transformation circuit, integrating the enhanced high frequency separation signal, the high frequency separation signal, the low-intermediate frequency separation signal, and the low frequency separation signal into an enhanced image signal by performingperforming the inverse wavelet transform.

A substrate inspection device for inspecting a flexible printed board to determine whether the transparent adhesive material is properly applied thereto comprises: a substrate reading device which irradiates the flexible printed board with visible light to acquire image data; an adhesive material position determination unit which determines a position of adhesive material CAD data corresponding to the transparent adhesive material with respect to blue color image data among the image data corresponding to blue light which is readily absorbed by polyimide, to create adhesive material alignment data in which the adhesive material CAD data is superposed; an edge enhancing unit which performs processing, on the blue color image data, to enhance an edge of the transparent adhesive material; and a straight line determination unit which determines whether the edge of the transparent adhesive material is present in edge enhanced data in which the edge of the transparent adhesive material is enhanced.

In some embodiments, an image editing application stores, based on a first selection input, a selection state that identifies a first image portion of a target image as included in a preview image displayed in a mask-based editing interface of the image editing application. An edit to the preview image generated from the selected first image portion is applied in the mask-based editing interface. The image editing application also updates an edit state that tracks the edit applied to the preview image. The image editing application modifies, based on a second selection input received via the mask-based editing interface, the selection state to include a second image portion in the preview image. The edit state is maintained with the applied edit concurrently with modifying the selection state. The image editing application applies the edit to the modified preview image in the mask-based editing interface.