Intelligent VR (Virtual Reality) elastic bandage equipment includes a main body, left and right supporting arms, a rear support, a telescopic assembly and a driving mechanism. According to a touch panel in the equipment, different input signals are triggered through different touch actions and touch durations, and a motor is controlled through a main control circuit board, so that the motor outputs different rotating speeds and directions; and therefore, the motor further drives the driving mechanism to drive the telescopic assembly to move and stretch, the telescopic assembly further drives the left and right supporting arms to retract, and adjustment of the distance between the main body and the head of a human body is achieved, so that the equipment is more comfortable to use, the use range is enlarged, and the operation is easy.

A head-mounted display includes a display device, a connecting structure and a head abutting portion. The connecting structure is in a shape of strip. The connecting structure has two opposite ends. The ends are respectively connected with the display device. The connecting structure and the display device define an accommodation space. The accommodation space is configured to accommodate a head of a user. The head abutting portion is pivotally connected with the connecting structure. The head abutting portion is at least partially located between the connecting structure and the display device. The head abutting portion is configured to abut against the head of the user.

A vehicle (10) for a driver (14) of the vehicle (10) and a display device (16) are provided. The display device (16) includes a projection surface (18) extending in the horizontal and vertical direction and a projector (20) that is configured so as to project a projection (24) onto the projection surface (18). The projection surface (18) is curved in the horizontal direction and surrounds the driver (14) in the horizontal direction by at least one hundred degrees. A method for displaying a projection (24) on a projection surface (18) for a driver (14) of a vehicle (10) is also provided. The method includes: d) determining a viewing direction and/or head orientation (26) of the driver (14) towards the projection surface (18); and f) projecting the projection (24) onto the projection surface (18) in the viewing direction and/or head orientation (26) of the driver (14).

An augmented reality display device including a virtual image display and a controller is provided. The virtual image display is configured to provide a left eye virtual image and a right eye virtual image to a left eye and a right eye of a user, respectively. The controller is electrically connected to the virtual image display, and is configured to command the virtual image display to display a left eye virtual mark and a right eye virtual mark, corresponding to a real mark in space, in the left eye virtual image and the right eye virtual image, respectively, and calculate an interpupillary distance between the left eye and the right eye according to a deviation of the left eye virtual mark with respect to the real mark and a deviation of the right eye virtual mark with respect to the real mark.

In example implementations, an apparatus is provided. The apparatus includes an eye mount, an adjustable layer, and a foam layer. A first side of the eye mount is to be coupled to a display portion of a head mounted display. The adjustable layer is coupled to an outer perimeter of a second side of the eye mount. The foam layer is coupled to the adjustable layer.

Disclosed in the present disclosure is a VR glasses which includes: a screen frame and a bottom plate, wherein the screen frame is fixed to the bottom plate, the bottom plate is provided with two light-transmitting holes symmetrically, and an edge of the screen frame has a first side structure perpendicular to the bottom plate; a first lens barrel and a second lens barrel, wherein the first lens barrel and the second lens barrel communicate with the two light-transmitting holes and each of the first lens barrel and the second lens barrel is provided with a lens; and a transmission mechanism, wherein the transmission mechanism is a stepped adjustment mechanism, the transmission mechanism is arranged close to the first side structure of the screen frame, the first lens barrel and the second lens barrel is configured to move toward each other through the transmission mechanism.

The disclosed subject matter relates to a light projector module, comprising: a base plate, a light source on one side of the base plate, a micro-electro-mechanical-system (MEMS) scanning assembly on the base plate, and a set of at least one lens mounted on the one side of the base plate between the light source and the MEMS scanning assembly, wherein the MEMS scanning assembly has an arm mounted on and extending from the other side of the base plate, a scanning mirror being movably mounted on the arm and facing the base plate, and wherein a light guide is mounted on the base plate or the arm for directing the at least one light beam from the lens set on the one side to the scanning mirror on the arm extending from said other side of the base plate.

An actuator aligned multi-channel projector assembly generates image light using a plurality of projectors. A projector includes a plurality of optical components in optical series and one or more actuators. The plurality of optical components include a light source and a plurality of optical elements. The light source generates first light. The plurality of optical elements project the first light. The first light is output from the projector and combined with a second to form an image presented via a display element of a headset to a user. The one or more actuators adjust a position of at least one optical component of the plurality of optical components relative to another optical component in order to compensate for misalignment of a portion of the image formed from the first light relative to a portion of the image formed from the second light.

An optical device is disclosed. The optical device includes a first lens having a first surface and a plurality of side surfaces; a first display device disposed on a first side surface of the side surfaces of the first lens; and a first active mirror disposed in the first lens. The first active mirror is tilted at a first angle during a first period and is tilted at a second angle during a second period.

Systems and methods for a flexible, modular head-mounted display is provided. The head-mounted display system may comprise a base member and one or more arm members that are coupled to the base member. The arm member(s) may be coupled to the base member via a hinge system that allows the arm member(s) to move with respect to the base member. Interior walls of the hinge system may define a passage therethrough such that wiring may extend throughout the head-mounted display system. The head-mounted display system may further include a cover that encloses at least a portion of the hinge. The cover may overlap with the base member or the one or more arm members.