The embodiments of the disclosure provide an optical system and an image enlargement device. The optical system may include a display and an optical component disposed between the display and a viewing position. The optical component may include a first reflective element and a second reflective element. The first reflective element is configured to receive an incident light emitted from the display. The second reflective element is disposed on a reflected light path of the first reflective element, and configured to receive the incident light reflected by the first reflective element and reflect the reflected incident light to a viewing position. The first reflective element and/or the second reflective element having a function of concentrating light. Therefore, when the user looks at a display of a mobile phone or a terminal, the display is enlarged by the even reflection of the first reflective element and the second reflective element, thereby improving the user experience and comfort.

An example of an image display system includes a goggles apparatus and is capable of setting an angle of view of a virtual camera disposed in a virtual space to a first angle of view or a second angle of view smaller than the first angle of view. If the angle of view of the virtual camera is set to the first angle of view, the image display system sets a parallax between an image for a left eye and an image for a right eye to a first parallax. If the angle of view of the virtual camera is set to the second angle of view, the image display system sets the parallax between the image for a left eye and the image for a right eye to a second parallax smaller than the first parallax.

A three-dimensional display device includes a display panel, a shutter panel, an obtainer, an input unit, and a controller. The display panel includes subpixels that display a parallax image. The obtainer obtains an illuminance level. The input unit receives a position of a pupil. The controller causes a set of subpixels included in the subpixels to display a black image based on the illuminance level. The controller determines an origin position. The origin position is a position of the pupil for a viewable section to have a center aligning with a center of a set of consecutive subpixels in an interocular direction. The set of consecutive subpixels is included in the subpixels and displaying the first image or the second image corresponding to the viewable section. The controller controls the display panel based on a displacement of the pupil from the origin position in the interocular direction.

A 3D display device includes a display panel, an optical element, a second communication module, and a controller. The display panel is mounted on a moving body and configured to display a parallax image. The optical element is configured to define a propagation direction of image light emitted from the display panel. The second communication module is configured to receive a motion signal indicating a parameter of a motion of the moving body. The controller is configured to cause the display panel to display the parallax image based on the parameter indicated by the motion signal.

A medical magnification device, which is an example of an embodiment, comprises: a device body which has a face pad that comes into contact with the face of a user, and which covers the front of the left and right eyes of the user; a belt for fixing the device body to the head of the user; an imaging unit which has a zoom lens provided to the front of the device body, and which performs digital conversion on a magnified image obtained by the zoom lens; and a pair of monitors.

A display device having a viewing window on a viewing plane is described. The display device comprises a picture generating unit, a first waveguide pupil expander and a second waveguide pupil expander. The picture generating unit is arranged to display a picture on a display plane. The picture is a holographic reconstruction formed from a hologram of the picture. The first waveguide pupil expander comprises an input port arranged to receive light of the picture and to expand a first exit pupil thereof in a first dimension. The second waveguide pupil expander comprises an input port arranged to receive light of the picture and to expand a second exit pupil thereof in the first dimension. The first dimension corresponds to a dimension of the viewing window. A method of expanding a viewing window of a display device is also described.

Provided is an electronic device using an augmented reality, which is capable of selectively driving a monocular mode and a binocular mode by using one display module. According to an aspect of the present invention, an electronic device includes: a glasses body including a left eye lens and a right eye lens and a nose support part positioned between the left and right lenses; one display module positioned at the nose support part; an optical system including a left eye optical system transferring a screen displayed on a display provided in the display module and to the left eye lens and a right eye optical system transferring the screen to the right eye lens; and a control unit controlling the screen displayed on the display so as to display the screen on at least one lens of the two lenses.

An example of an image display system includes a goggles apparatus and is capable of setting an angle of view of a virtual camera disposed in a virtual space to a first angle of view or a second angle of view smaller than the first angle of view. If the angle of view of the virtual camera is set to the first angle of view, the image display system sets a parallax between an image for a left eye and an image for a right eye to a first parallax. If the angle of view of the virtual camera is set to the second angle of view, the image display system sets the parallax between the image for a left eye and the image for a right eye to a second parallax smaller than the first parallax.

According to an aspect, a display device includes: a display panel; a first optical component serving as a switchable optical component capable of being switched between a reflection state and a transmission state of light by a reflection surface thereof; and a second optical component. The reflection surface of the first optical component that faces the display panel is arranged on a light path extending from the display panel. The second optical component has a reflection surface. The reflection surface of the second optical component is on a path of light reflected by the first optical component.

A surgical navigation system includes: a tracker (125) for real-time tracking of a position and orientation of a robot arm (191); a source of a patient anatomical data (163) and a robot arm virtual image (166); a surgical navigation image generator (131) generating a surgical navigation image (142A) including the patient anatomy (163) and the robot arm virtual image (166) in accordance to the current position and/or orientation data provided by the tracker (125); a 3D display system (140) showing the surgical navigation image (142A).