A shooter game device provided with individual screens, the device comprising a game processing element, a table, a main screen, multiple individual operation elements and multiple individual screens; the game processing element provides a shooter game and controls a game process of the shooting game and generates a main game image; the main screen is provided on the table and displays the main game image; the multiple individual operation elements are provided on the table and are operated by players to generate an operation signal so as to change the game process; the multiple individual screens are provided on the table and correspond one-to-one to the multiple individual operation elements, and each of the individual screens presents an individual game image of the corresponding player; according to the foregoing, players can obtain personalized specific information by means of the individual screens, such as game explanations, education and guidance, special game effects, scores, and so on, so as to meet personalized usage requirements.

A head mounted display (HMD) is provided. The HMD includes a housing and a view port of the housing. The view port has a screen for rendering an augmented reality scene. Included is a communications device for exchanging streaming data over a network. A depth camera integrated in the housing and oriented to capture depth data of an environment in front of the housing is included. A processor is configured to use the depth data captured by the depth camera to identify spatial positioning of real objects in the environment. A real object is rendered into the augmented reality scene, and the real object is tracked such that insertion of augmented reality objects are placed in coordination with movements of the real object shown in the augmented reality scene. The real object captured by the depth camera is the environment where a user wearing the HMD is located.

A head mounted display (HMD) is provided. The HMD includes a housing and a view port of the housing. The view port has a screen for rendering an augmented reality scene. Included is a communications device for exchanging streaming data over a network. A depth camera integrated in the housing and oriented to capture depth data of an environment in front of the housing is included. A processor is configured to use the depth data captured by the depth camera to identify spatial positioning of real objects in the environment. A real object is rendered into the augmented reality scene, and the real object is tracked such that insertion of augmented reality objects are placed in coordination with movements of the real object shown in the augmented reality scene. The real object captured by the depth camera is the environment where a user wearing the HMD is located.

A system for displaying a mobile device screen comprises a head mounted display for displaying a first content to a user, a video camera mounted on the head mounted display, the video camera operable to capture a video image of a scene in front of the user, a region detection processor operable to detect a region of the captured video image comprising a mobile device screen, and an image processor operable to replace a corresponding region of the displayed first content in the head mounted display with the detected region of the captured video image comprising the mobile device screen.

A system for displaying a mobile device screen comprises a head mounted display for displaying a first content to a user, a video camera mounted on the head mounted display, the video camera operable to capture a video image of a scene in front of the user, a region detection processor operable to detect a region of the captured video image comprising a mobile device screen, and an image processor operable to replace a corresponding region of the displayed first content in the head mounted display with the detected region of the captured video image comprising the mobile device screen.

A virtual reality apparatus includes a head mountable display (HMD); a detector to detect a deviation of a current orientation of the HMD from a base orientation of the HMD; and a generator to generate content for presentation to the wearer of the HMD to prompt the wearer of the HMD to turn his head so as to change the orientation of the HMD towards the base orientation.

The mobile communication and gaming device is a personal data device. The mobile communication and gaming device is a programmable logical device. The mobile communication and gaming device has an interface that is configured for use with gaming applications. The mobile communication and gaming device comprises a logical appliance and a housing. The housing contains the logical appliance.

A switching method and system of interactive modes of a head-mounted device is provided. The interactive modes include gamepad tracking interactive mode and bare hand tracking interactive mode. A standard deviation of position data, a standard deviation of attitude data and a standard deviation of accelerometer data among IMU data are acquired, respectively. Whether the standard deviation of the position data, the standard deviation of the attitude data and the standard deviation of the accelerometer data meet a first preset condition is determined. Moreover, the standard deviation of the accelerometer data within a second preset duration is acquired in real time, and whether the standard deviation of the accelerometer data meets a second preset condition is determined. In cases where the standard deviation of the accelerometer data meets the second preset condition, the bare hand tracking interactive mode is paused, and the gamepad tracking interactive mode is started.

An example of an image processing system includes a first HMD worn by a first user and a smart device carried by a second user. In a virtual space, a second virtual camera and a second object are placed in accordance with a position of the smart device relative to a reference in a real space. In the virtual space, a first object is placed regardless of a position of the first HMD in the real space, and a first virtual camera is placed at a position relating to a position of the first object. An image of the virtual space including the second object is displayed on the first HMD based on the first virtual camera. An image of the virtual space including the first object is displayed on the smart device based on the second virtual camera.

The present invention is a portable gaming and entertainment system (or “environment”) for use with a video game console and related components that allows the user thereof to easily, safely and conveniently transport the system. The system comprises an integrated screen with USB and HDMI capabilities that connect directly to the video game console. The integrated screen contains monitor and speaker, and is operative to be opened and maintained at a position to provide a desirable viewing angle for a user. The integrated screen closes against the video game console so that the user may easily transport and/or store the entire system.