An image pickup system includes a stereoscopic endoscope including image pickup optical systems having a parallax therebetween and a first image pickup device and a second image pickup device, and a processor including a first photometric measurement section configured to photometrically measure a luminance value of a first image pickup signal related to the first image pickup device, a second photometric measurement section configured to measure a luminance value of a second image pickup signal related to the second image pickup device, and a control section including a threshold value comparison section configured to compare the luminance value with a threshold value. When the luminance value of either one of the first image pickup signal and the second image pickup signal exceeds the threshold value, the image pickup system performs light adjustment control of a light source based on a photometric value of the other image pickup signal.

An image pickup system includes a stereoscopic endoscope including image pickup optical systems having a parallax therebetween and a first image pickup device and a second image pickup device, and a processor including a first photometric measurement section configured to photometrically measure a luminance value of a first image pickup signal related to the first image pickup device, a second photometric measurement section configured to measure a luminance value of a second image pickup signal related to the second image pickup device, and a control section including a threshold value comparison section configured to compare the luminance value with a threshold value. When the luminance value of either one of the first image pickup signal and the second image pickup signal exceeds the threshold value, the image pickup system performs light adjustment control of a light source based on a photometric value of the other image pickup signal.

The present specification relates to a portable device that controls a photography mode, and a control method therefor. A control method of a portable device that controls a photography mode according to an embodiment may comprise the steps of: detecting a first marker at a first distance from the portable device and a second marker at a second distance using at least one of a first camera unit and a second camera unit; and executing a photography mode that captures an image. A 2D photography mode is executed if the first distance of the detected first marker and the second distance of the detected second marker are effectively the same; and a 3D photography mode is executed if the first distance of the detected first marker and the second distance of the detected second marker are different, wherein the 3D photography mode may be a mode that generates a 3D image using binocular disparity of the first camera unit and the second camera unit.

The present specification relates to a portable device that controls a photography mode, and a control method therefor. A control method of a portable device that controls a photography mode according to an embodiment may comprise the steps of: detecting a first marker at a first distance from the portable device and a second marker at a second distance using at least one of a first camera unit and a second camera unit; and executing a photography mode that captures an image. A 2D photography mode is executed if the first distance of the detected first marker and the second distance of the detected second marker are effectively the same; and a 3D photography mode is executed if the first distance of the detected first marker and the second distance of the detected second marker are different, wherein the 3D photography mode may be a mode that generates a 3D image using binocular disparity of the first camera unit and the second camera unit.

A multiple lenses system includes a lens module, a processing unit, a switching unit, and a focus module. The lens module includes a plurality of lenses. The switching unit is electrically connected to the plurality of lenses and the processing unit. The focus module includes a laser emitter and a laser receiver. The laser emitter emits laser beam towards an object under control of the processing unit. The laser receiver receives the laser beam reflected by the object. The processing unit obtains a focus distance between the object and the focus module according to a time difference from emitting the laser beam to receiving the laser beam, and controls the switching unit to switch and to select at least one of the plurality of lenses according to the focus distance.

A multiple lenses system includes a lens module, a processing unit, a switching unit, and a focus module. The lens module includes a plurality of lenses. The switching unit is electrically connected to the plurality of lenses and the processing unit. The focus module includes a laser emitter and a laser receiver. The laser emitter emits laser beam towards an object under control of the processing unit. The laser receiver receives the laser beam reflected by the object. The processing unit obtains a focus distance between the object and the focus module according to a time difference from emitting the laser beam to receiving the laser beam, and controls the switching unit to switch and to select at least one of the plurality of lenses according to the focus distance.

There is provided an information processing apparatus, an information processing method, and a program, the information processing apparatus including: a control unit that determines a display method for an object in a virtual space on a basis of a positional relationship between the object and a viewpoint. A binocular parallax regarding the object which is to be imparted to a user varies depending on the determined display method.

A camera device includes a camera head that captures an observation image of a target site which is obtained by a surgical microscope, and a camera control unit that processes a signal of the observation video captured by the camera head. The camera head captures right and left observation images having a parallax from the surgical microscope to obtain a high-resolution observation video including right and left parallax videos for one screen, and the camera control unit cuts out the right parallax video and the left parallax video from the observation video including the right and left parallax videos to generate a high-resolution 3D video which is displayed on a monitor in 3D and with which stereoscopic observation can be performed.

A camera device includes a camera head that captures an observation image of a target site which is obtained by a surgical microscope, and a camera control unit that processes a signal of the observation video captured by the camera head. The camera head captures right and left observation images having a parallax from the surgical microscope to obtain a high-resolution observation video including right and left parallax videos for one screen, and the camera control unit cuts out the right parallax video and the left parallax video from the observation video including the right and left parallax videos to generate a high-resolution 3D video which is displayed on a monitor in 3D and with which stereoscopic observation can be performed.

An electronic device for processing images is provided. The electronic device includes multiple camera groups each including a pair of cameras disposed in different optical axis directions, and having different fields of views, multiple processors each configured to process images acquired through the multiple camera groups and a designated processor configured to control the first processor and the second processor. The designated processor is further configured to select an operation mode associated with the electronic device, at least based on an input associated with a first camera group or a second camera group, and if the operation mode is selected as a first operation mode, obtain an image covering the first FOV by using first images that is processed through a first processor, and restrict power supply to the second processor or the second camera group.