A system, method, and computer program product for generating a lightweight source code for implementing an image processing pipeline is disclosed. The method comprises receiving a specification for an image processing pipeline based on configuration settings associated with a user interface of a viewer application, generating a graphics language (GL) representation of the image processing pipeline based on the specification, and code for causing the GL representation to be compiled via a compile service to generate a binary executable instantiation of the image processing pipeline for execution on one or more graphics processing unit (GPU) cores.

A system, method, and computer program product for generating a lightweight source code for implementing an image processing pipeline is disclosed. The method comprises receiving a specification for an image processing pipeline based on configuration settings associated with a user interface of a viewer application, generating a graphics language (GL) representation of the image processing pipeline based on the specification, and code for causing the GL representation to be compiled via a compile service to generate a binary executable instantiation of the image processing pipeline for execution on one or more graphics processing unit (GPU) cores.

Techniques for video content based on multiple capture devices are described and are implementable to enable multiple video capture devices to be utilized for a video feed. Generally, the described implementations enable video content captured by multiple video capture devices to be utilized, such as to integrate different instances of video content into a merged video content stream. In at least one implementation this provides higher quality video attributes to be utilized than is provided by utilizing a single video content source.

Techniques for video content based on multiple capture devices are described and are implementable to enable multiple video capture devices to be utilized for a video feed. Generally, the described implementations enable video content captured by multiple video capture devices to be utilized, such as to integrate different instances of video content into a merged video content stream. In at least one implementation this provides higher quality video attributes to be utilized than is provided by utilizing a single video content source.

A medical control device includes circuitry configured to: control an autofocus operation on a captured image from an observation target illuminated with excitation light of a first wavelength band and a pattern image of a second wavelength band, the observation target fluorescing in response to the excitation light to output light in a third wavelength band. The captured image includes light components in the first to third wavelengths bands, of which the second and third wavelength bands are different. The autofocus operation is controlled by calculating, based on the pattern image of the second wavelength band in the captured image, an evaluation value used in an autofocus process that controls a focus position of an imaging device configured to generate the captured image.

A solid-state imaging device capable of acquiring an RGB image, a CMY image, and luminance information through one imaging process. The solid-state imaging device includes a pixel array portion in which a plurality of pixel unit groups are arrayed, the pixel unit group including pixel units disposed in a 2×2 matrix, the pixel unit including pixels disposed in an 2×2 matrix, and the pixels including a photoelectric conversion unit and a color filter. Each of the pixel unit groups is configured such that an R filter and a C filter are included as the color filters in a first pixel unit among four pixel units constituting the pixel unit group, a G filter and an M filter are included as the color filters in each of second and third pixel units, and a B filter and a Y filter are included as the color filters in a fourth pixel unit.

A solid-state imaging device capable of acquiring an RGB image, a CMY image, and luminance information through one imaging process. The solid-state imaging device includes a pixel array portion in which a plurality of pixel unit groups are arrayed, the pixel unit group including pixel units disposed in a 2×2 matrix, the pixel unit including pixels disposed in an 2×2 matrix, and the pixels including a photoelectric conversion unit and a color filter. Each of the pixel unit groups is configured such that an R filter and a C filter are included as the color filters in a first pixel unit among four pixel units constituting the pixel unit group, a G filter and an M filter are included as the color filters in each of second and third pixel units, and a B filter and a Y filter are included as the color filters in a fourth pixel unit.

The present technique relates to a telemedicine system, a telemedicine method, an information processing device, and a program that allow a medical practitioner to more accurately obtain visual information on a patient in telemedicine.

The telemedicine system includes a first imaging unit that images a patient in a first space, an image processing unit that corrects an image of the patient based on imaging conditions in a first space and display conditions in a second space for displaying the image of the patient imaged in the first space, and a display unit that displays the corrected image of the patient in the second space. The present technique can be applied to, for example, a telemedicine system.

An apparatus includes an acquisition unit configured to acquire a first control value related to white balance based on an input image, a determination unit configured to determine whether a first area including the acquired first control value is changeable, a control unit configured to change the first area to a second area based on a result of determination by the determination unit, and a calculation unit configured to calculate a second control value related to the white balance to be applied to the input image in the second area in a case where the first area is changed to the second area, wherein the control unit changes the first area to the second area by stages.

An apparatus includes an acquisition unit configured to acquire a first control value related to white balance based on an input image, a determination unit configured to determine whether a first area including the acquired first control value is changeable, a control unit configured to change the first area to a second area based on a result of determination by the determination unit, and a calculation unit configured to calculate a second control value related to the white balance to be applied to the input image in the second area in a case where the first area is changed to the second area, wherein the control unit changes the first area to the second area by stages.