TWI624694B - Immersive Interactive Glasses - Google Patents

Abstract

The invention is an immersive interactive experience glasses, comprising a frame body, a display host, a connection module and at least one screen capable of adjusting the degree of light transmission. The frame comprises a hollow frame, the hollow frame has opposite front and rear openings, a plurality of sides around the front opening and the rear opening; the display host is disposed at the front opening, the display host comprises a microcontroller; and the connection module comprises electrical A connector for connecting to the microcontroller; a screen electrical connector that adjusts the degree of light transmission and is disposed on one side of the frame, and the immersive interactive experience glasses can control the screen of the adjustable light transmission through the microcontroller Light transmission; to increase the use of interaction and ensure the safety of use.

Description

Immersive interactive experience glasses

The present invention relates to stereoscopic glasses, and more particularly to a pair of stereoscopic glasses.

Virtual Reality (VR), also known as virtual environment, is a virtual world that uses computer simulation to generate a three-dimensional space. It provides users with a simulation of the senses such as vision, so that users feel as if they are observing things in the three-dimensional space. . When the user moves the position, the computer can immediately perform complicated calculations to transmit accurate three-dimensional images back to the sense of presence.

However, since the image of the traditional virtual reality mainly comes from computer processing, the shortcoming in practical use is that it has insufficient interaction with the outside world and cannot be combined with the actual environment. In this regard, how to use Augmented Reality (AR) to calculate the position and angle of camera images in real time and add corresponding images to improve the interaction between the virtual reality and the real environment. The motivation of the inventor's creation.

In view of the above, the inventors of the present invention have made great efforts to solve the above problems in view of the above-mentioned prior art, and have made great efforts to solve the above problems, which has become the object of improvement of the present inventors.

It is an object of the present invention to provide an immersive interactive experience eyeglass that improves the interaction between a virtual reality and a real environment by controlling the light transmission of a screen that can adjust the degree of light transmission.

Another object of the present invention is to provide an immersive interactive experience glasses that can be applied to virtual reality and augmented reality to provide an integrated display mode.

Another object of the present invention is to provide an immersive interactive experience glasses, which can be applied to an interactive game, and switches virtual reality and augmented reality according to the game content story or context application, thereby achieving fascination and increasing interaction. Ensure the purpose of security.

In order to achieve the above object, the present invention is an immersive interactive experience glasses, comprising a frame, a display host, a connection module and at least one screen capable of adjusting the degree of light transmission. The frame comprises a hollow frame, the hollow frame has opposite front and rear openings, a plurality of sides around the front opening and the rear opening; the display host is disposed at the front opening, the display host comprises a microcontroller; and the connection module comprises electrical Connect at least one connector of the microcontroller; adjust the light transmittance of the screen electrical connector and set it on one side of the frame; the immersive interactive experience glasses can control the adjustable light transmission through the microcontroller The light of the screen.

Compared with the prior art, the immersive interactive experience glasses of the present invention are electrically connected to the control panel with adjustable light transmittance, and at least one screen with adjustable light transmission degree is disposed on the side of the frame body, which can be used in actual use. Controls the light transmission of the screen with adjustable light transmission, thereby expanding the lateral surrounding viewing angle range or shielding the surrounding environment of the line of sight; in addition, since the screen with adjustable light transmittance can also display relevant information, it can enhance virtual reality and reality. The interaction between the environments increases the utility of the invention.

1‧‧‧Immersive interactive experience glasses

10‧‧‧ frame

11‧‧‧ hollow frame

111‧‧‧ front opening

112‧‧‧After opening

113‧‧‧left side

114‧‧‧ right side

115‧‧‧Upper side

116‧‧‧ lower side

20‧‧‧Display host

21‧‧‧Microcontroller

22‧‧‧ display

23‧‧‧Battery

24‧‧‧Control connector

25‧‧‧Connecting module

26‧‧‧Connector

261‧‧‧First connector

262‧‧‧Second connector

263‧‧‧ third connector

264‧‧‧fourth connector

27‧‧‧Connecting board

30‧‧‧Screens with adjustable light transmission

31‧‧‧The first screen with adjustable light transmission

32‧‧‧Second screen with adjustable light transmission

33‧‧‧ Third screen with adjustable light transmission

34‧‧‧The fourth screen with adjustable light transmission

40‧‧‧Window partition

41‧‧‧ visible holes

50‧‧‧protection box

51‧‧‧Arc film

60‧‧‧ protective cover

1 is a schematic view showing the wearing of the immersive interactive experience glasses of the present invention.

2 is a perspective exploded view of the immersive interactive experience glasses of the present invention.

3 is a block diagram of the immersive interactive experience glasses of the present invention.

4 is a schematic diagram of the use of the immersive interactive experience glasses of the present invention.

Fig. 5 is a schematic view showing another use of the immersive interactive experience glasses of the present invention.

Fig. 6 is a schematic view showing still another use of the immersive interactive experience glasses of the present invention.

The detailed description and technical content of the present invention are set forth in the accompanying drawings.

Please refer to FIG. 1 to FIG. 3 , which are respectively a schematic diagram, a perspective exploded view and a block diagram of the immersive interactive experience glasses of the present invention. As shown in FIG. 1 , the immersive interactive experience glasses 1 of the present invention are worn in front of the eyes of a human body. In actual use, the immersive interactive experience glasses 1 can be coupled to the human body by means of straps or attachments. 2, the immersive interactive experience glasses 1 of the present invention include a frame 10, a display host 20, a connection module 25, and at least one screen 30 with adjustable light transmission. The screen 30 of the adjustable light transmission is disposed on one side of the frame 10 (the front side of the user's eyes is the front side and the side is the side side). The display host 20 is disposed inside the frame 10 and can control the light transmission of the screen 30 of the adjustable light transmittance. Accordingly, the immersive interactive experience glasses 1 achieves the purpose of increasing the use of interaction and ensuring the safety of use through the degree of light transmission of the screen 30 which can adjust the degree of light transmission. The structure of the immersive interactive experience glasses 1 is described in more detail.

The frame 10 includes a hollow frame 11 having a front opening 111 (the front of the user's eyes is forward) and a rear opening 112 between the front opening 111 and the rear opening 112. The multiple sides of the surrounding area are 113~116. Specifically, the side surfaces 113-116 include a left side surface 113, a right side surface 114, an upper side surface 115, and a lower side surface 116. Preferably, the hollow frame 11 has a rectangular shape, and the front opening 111 and the rear opening 112 are respectively a rectangular opening.

The display host 20 is disposed in the front opening 111. The display host 20 includes a microcontroller 21, a display 22 electrically connected to the microcontroller 21, a battery 23, and a control connector 24. In this embodiment, the microcontroller 21, the display 22, the battery 23, and the control connector 24 are integrated into one mobile phone.

Furthermore, the connection module 25 includes at least one connector 26 electrically connected to the microcontroller 21. In the embodiment, the connection module 25 further includes a connection board 27 provided with the connector 26, the connection board 27 is provided with the connector 26, and the connection module 25 is separately and separately disposed on the display host. One side of 20.

In this embodiment, the at least one adjustable light transmittance screen 30 is disposed on one of the side surfaces 113-116 of the frame body 10, and the power source of the screen 30 capable of adjusting the light transmission level is a battery through the display host 20. 23 supplies. Moreover, the screen 30 of the adjustable light transmission is opaque when not energized (the power supply is not received), and the screen 30 of the adjustable light transmittance can be used to shield the surrounding environment to provide a user with fascination. An immersive virtual reality. On the other hand, when the screen 30 with adjustable light transmission is energized (received power supply), it can be displayed as light transmission or display related information, such as providing environmental information to the user for safety considerations.

Moreover, the screen 30 of the adjustable light transmission is electrically connected to the microcontroller 21 through the connector 26, so that the immersive interactive experience glasses 1 can control the adjustable through the microcontroller 21. The light level of the screen 30 is transparent. That is, the microcontroller 21 can determine whether or not to supply power to the screen 30 of the adjustable light transmission level.

In actual implementation, when the microcontroller 21 determines that the screen 30 is not powered, the microcontroller 21 cuts off the electrical connection between the battery 23 and the control connector 24. The connector 26 cannot connect the battery 23 through the control connector 24, and the battery 23 cannot supply power to the battery 23 The screen 30 of the light transmission level is adjusted, and therefore, the screen 30 of the adjustable light transmittance is opaque due to the non-energization. In addition, when the microcontroller 21 determines to supply the screen 30 to the adjustable light transmission level, the microcontroller 21 can instruct the battery 23 to electrically connect with the control connector 24. At this time, the connector 26 The battery 23 can be connected through the control connector 24, and the battery 23 can be powered to the screen 30 with adjustable light transmittance. The screen 30 with adjustable light transmission is transparent due to energization, or displays relevant News.

The adjustable light transmittance screen 30 can be configured as a Polymer Dispersed Liquid Crystal (PDLC) or a Transmissive Display. Preferably, the number of the screens 30 with adjustable light transmission is plural, and the screens 30 with adjustable light transmission are disposed on the upper side 115, the lower side 116, the left side 113 or the right side of the hollow frame 11. 114.

Specifically, the display host 20 also has a game program built therein. The game program has at least one screen control command, and the microcontroller 21 controls the light transmission of the screen 30 with adjustable light transmittance according to the screen control command.

In this embodiment, the hollow frame 11 is combined with a plurality of screens 30 for adjusting the degree of light transmission, and includes a first adjustable light transmission screen 31, a second adjustable light transmittance screen 32, and a third A screen 33 for adjusting the degree of light transmission and a screen 34 for adjusting the degree of light transmission are provided. That is, the left side surface 113 of the hollow frame 11 is provided with the first adjustable light transmittance screen 31; the right side surface 114 is provided with the second adjustable light transmission level screen 32; the upper side surface 115 is provided with the screen The third adjustable light transmittance screen 33; and the lower side surface 116 is provided with the fourth adjustable light transmittance screen 34.

In this embodiment, the connector 26 includes a first connector 261, a second connector 262, a third connector 263, and a fourth connector 264. The first to fourth adjustable light transmittance screens 31 to 34 are electrically connected to the control connector 24 through the first to fourth connectors 261 to 264, respectively. The microcontroller 21 can control the light transmission of the first to fourth adjustable light transmittance screens 31 to 34 through the control connector 24, thereby increasing the viewing angle range of each side surface or shielding the environment around the line of sight.

In the embodiment, the immersive interactive experience glasses 1 further includes a window partition 40, a protective frame 50 and a protective cover 60. The window partition 40 is disposed between the front opening 111 and the rear opening 112 and has two visible holes 41. The distance between the two visible holes 41 corresponds to the distance between two eyes of a human body. Moreover, the protective frame 50 is coupled to the rear opening 112 and disposed on an outer side of the window partition 40. The protective cover 60 covers the front opening 111 and is disposed on an outer side of the display main unit 20. Preferably, one side of the protective frame 50 has an arc-shaped piece 51 attachable to the forehead of the human body.

Please refer to FIG. 4 to FIG. 6 , which are schematic diagrams of the use of the immersive interactive experience glasses of the present invention. As shown in FIG. 4, it is shown that the immersive interactive experience glasses 1 controls the screen 33 of the third adjustable light transmission level disposed on the upper side 115 to transmit light, and therefore, the third adjustable light transmittance screen 33 The display is shown in a light transmitting state, allowing the user to increase the visual range of the upper side 115. Similarly, as shown in FIG. 5, it is shown that the immersive interactive experience glasses 1 controls the screen 31 of the first adjustable light transmission level disposed on the left side surface 113 to transmit light, and therefore, the first adjustable light transmission degree The screen 31 is shown in a light transmitting state, allowing the user to increase the visible range of the left side 113. Please refer to FIG. 6 , which shows that the immersive interactive experience glasses 1 controls the second adjustable light transmittance screen 32 disposed on the right side surface 114 to transmit light. Therefore, the second adjustable light transmission degree The screen 32 is shown in a light transmitting state, allowing the user to increase the visual range of the right side 114.

It should be noted that, in actual use, the immersive interactive experience glasses 1 can control a plurality of screens 30 for adjusting the light transmittance to simultaneously transmit, block or display information according to actual use conditions.

Furthermore, the display host 20 of the present invention can also have a built-in game program. The game program has at least one screen control command, and the microcontroller 21 controls the adjustable according to the screen control command The light transmission of the screen 30 is light. Accordingly, the immersive interactive experience glasses 1 of the present invention can be applied to an interactive game. In actual use, when the player performs an interactive game with the scenario, the microcontroller 21 of the immersive interactive experience glasses 1 can determine the control signal through the control signal. The screen 30 of the adjustable light transmittance on one side is transparent or further displays other related information.

Specifically, when the scenario requires a full virtual image, the microcontroller 21 of the present invention controls the screen 30 of the adjustable light transmittance to be opaque according to the screen control command, so as to obscure the player's line of sight and immerse the player in the virtual In the world. Moreover, when the scenario needs to increase the environmental image or requires more security considerations, the microcontroller 21 controls the screen 30 of the adjustable light transmission to transmit light or provide environmental information according to the screen control command. By. In this way, the player's game experience is better achieved, and the interaction between the virtual reality and the real environment is increased.

The above description is only the preferred embodiment of the present invention, and is not intended to limit the scope of the invention, and other equivalent variations of the patent spirit of the present invention are all within the scope of the invention.

Claims (10)

An immersive interactive experience glasses, comprising: a frame, comprising a hollow frame, the hollow frame has a front opening and a rear opening; a plurality of sides around the front opening and the rear opening; Provided in the front opening, the display host includes a microcontroller; a connection module including at least one connector electrically connected to the microcontroller; and at least one screen capable of adjusting the degree of light transmission, electrically connecting the The connector is disposed on one side of the frame, and the immersive interactive experience glasses can control the light transmission of the adjustable light transmission screen through the microcontroller. The immersive interactive experience glasses of claim 1, wherein the hollow frame has a rectangular shape, and the front opening and the rear opening are respectively a rectangular opening. The immersive interactive experience glasses of claim 1, wherein the display host further comprises a display electrically connected to the microcontroller, a battery and a control connector, wherein the adjustable light transmission screen is controlled by the control The connector is electrically connected to the microcontroller. The immersive interactive experience glasses of claim 3, wherein the connection module further comprises a connection board provided with the connector, the connection module being separately disposed on one side of the display host. The immersive interactive experience glasses of claim 1, wherein the display host further has a game program built therein, the game program having at least one screen control command, the microcontroller controlling the adjustable light transmission according to the screen control command The degree of light transmission from the screen. The immersive interactive experience glasses of claim 1, wherein the adjustable light transmittance screen is a polymer dispersed liquid crystal display or a transmissive screen. The immersive interactive experience glasses of claim 1, wherein the number of the adjustable light transmittance screens is plural, and the sides comprise a left side surface, a right side surface, an upper side surface and a lower side surface, wherein the adjustable The screen of the degree of light transmission is disposed on the upper side, the lower side, the left side or the right side. The immersive interactive experience glasses of claim 1, further comprising a window partition disposed between the front opening and the rear opening and having two visible holes, the distance between the two visible holes It corresponds to the distance between two eyes of a human body. The immersive interactive experience glasses of claim 8, further comprising a protective frame and a protective cover, the protective frame being coupled to the rear opening and disposed on an outer side of the window partition, the protective cover is covered The front opening is disposed on an outer side of the display host. The immersive interactive experience glasses of claim 9, wherein one side of the protective frame has an arc-shaped piece attachable to the forehead of the human body.