A device for mixed reality includes a curved mirror and a first holder. The curved mirror has a concave surface, a convex surface opposite to the concave surface, and a light transmissive medium between the concave surface and the convex surface. The first holder is disposed in front of the concave surface and within a focal length of the curved mirror and configured to support a portable apparatus. The first holder has a curved surface configured to reflect a sound wave from the portable apparatus to the curved mirror.

A convex mirrored device that is placed on the floor to reflect electronic viewing monitors in view of the user when in downward facing positions. The device includes one or more convex arched mirrors that are placed on the floor between the user and the screen with the reflective side up. The arched mirror allows the user to execute multiple different downward facing positions while viewing monitor screens in the room having different sizes and heights. In one embodiment, the device attaches to the front of an activity mat and has hinges between the mirrors so that activity mat and the mirrored device can be rolled up and folded together. This enables the device to rolled up and folded for easy transportation and storage by the user.

A positioning platform providing positioning of component placed thereon onto four axes includes a lower plate, an upper plate, a first adjustment member, a second adjustment member, a third adjustment member, connection members, fixing members, a first fixing block, a second fixing block, fixing plates, slot fixing members, fixing covers, a yaw screw, a spring pin, a spring, and a yaw block.

An adjustable mirror assembly includes a mirror having a reflective surface. The adjustable mirror assembly may include a first locking mechanism configured to lock a support in a finite number of discrete positions. The support may be movable between a lowered position and a raised position. The mirror may be pivotally mounted to the support and may be configured to pivot about a second pivot axis to orient the reflective surface of the mirror in an aft-facing direction in both the lowered position and the raised position.

A mirror holding mechanism includes: a reflection mirror, a mirror holding member, and a cam member. The mirror holding member has two side surface portions sandwiching the reflection mirror in an X direction. In the side surface portion, a guide hole through which a shaft portion protruding from the reflection mirror to an outer side in the X direction is formed so as to pass through the side surface portion. The guide hole is formed into a long hole longitudinally extending in a Y direction. The cam member is disposed on an outer side of the side surface portion in the X direction and rotatably held by the side surface portion. On the cam member, a cam surface with which a distal end part of the shaft portion comes into contact is formed. When the cam member rotates, the shaft portion moves in the Y direction.

According to various embodiments of the present invention, a three-dimensional imaging device and/or an electronic device may comprise: a stand for supporting an electronic device including a display panel; a half mirror disposed on one surface of the stand in such a way as to slantingly face the display panel of the electronic device supported by the stand; and a retro-reflection member disposed on the stand in such a way as to incline toward the half mirror, wherein the half mirror reflects an image (hereinafter, a first output image) output from the display panel to introduce the reflected image into the retro-reflection member, and allows the image reflected by the retro-reflection member to transmit therethrough, so as to form an image(hereinafter, a first aerial image) corresponding to the first output image, on a space at another side of the half mirror. Such an electronic device may exist in various forms according to embodiments.

A flexure mount is described herein. The flexure mount includes three different flexures laterally offset from one another along a length of the flexure mount. The flexured design of the flexure mount allows for compliance in certain directions to reduce stress buildup normally associated with rigid mounting of dissimilar materials under dynamic thermal environments.

An audiovisual-capturing system for a lighted mirror is used to illuminate a user's face and aid in capturing images or video of the user through a one-way mirror. The system includes a support structure, a one-way mirror, and a plurality of lights. The support structure includes a bordering frame which attached around the one-way mirror. The plurality of lights is connected to the bordering frame and is distributed about the bordering frame. The plurality of lights is used to illuminate the user's face. The support structure also includes a device stand which is used to support an audiovisual-capturing device. The one-way mirror is positioned in between the device stand and the plurality of lights. This allows the audiovisual-capturing device to capture images or record video through the one-way mirror, while the user is able to see their reflection through the one-way mirror.

The invention includes a handlebar grip, a binding ring, a rod and a mirror. The handlebar grip has a main body and a tubular seat extending from an end of the main body. An outer diameter of the tubular seat is less than an outer diameter of the main body. The binding ring is a C-shaped body around the tubular seat. Two ends thereof are separately formed with a positioning hole and a threaded hole. The rod has a first end and a second end. The first end is formed with a positioning bar being inserted into the positioning hole. The positioning bar has a through hole. A screw passes through the through hole and the positioning hole and is screwed into the threaded hole to make the binding ring fasten the tubular seat. The mirror is pivotally connected to the second end of the rod.

The disclosure provides an optical apparatus including at least one optical element including glass, at least one support including silicon and a housing including glass. Furthermore, the at least one optical element and the at least one support can be anodically bonded together, and the at least one support and the housing can be anodically bonded together. The disclosure further provides a method for fabricating optical components with durable bonds and incorporates active alignment.