CN112114428A - AR or MR glasses - Google Patents

Abstract

The application discloses AR or MR glasses relates to virtual technical field for improve the interior electronic components overall arrangement of AR or MR glasses, mirror leg weight about the balance makes the mirror leg can fold, and convenience of customers wears and deposits more. The method comprises the following steps: the glasses comprise a glasses frame, a first glasses leg, a second glasses leg, a first hinge and a second hinge; one end of the first glasses leg is connected with the glasses frame through a first hinge; one end of the second glasses leg is connected with the glasses frame through a second hinge; the distance from the first hinge to the frame is different from the distance from the second hinge to the frame; the inside main control board that supports DP display interface transmission standard chip that contains of first mirror leg, the inside main control board that supports Type-C transmission standard chip that contains of second mirror leg sets up. The embodiment of the application is applied to AR augmented reality equipment or MR mixed reality equipment.

Description

AR or MR glasses

Technical Field

The application relates to the field of virtual technologies, in particular to AR or MR glasses.

Background

With the development of technology, AR (augmented reality) or MR (mixed reality) glasses are increasingly appearing in daily life, the AR glasses are a technology for calculating the position and angle of a camera image in real time and adding a corresponding image, the technology aims to cover a virtual world on a screen in the real world and perform interaction, and a new technology for integrating real world information and virtual world information in a seamless manner is a new technology for integrating entity information (visual information, sound, taste, touch and the like) which is difficult to experience in a certain time space range of the real world originally, and the virtual information is applied to the real world after simulation and then is overlapped through scientific technologies such as computers and the like, and is perceived by human senses, so that the sensory experience beyond the real world is achieved. The real environment and the virtual object are simultaneously superposed on the same picture or space in real time, and the MR technology also provides a new interactive function.

The augmented reality technology not only shows real world information, but also displays virtual information simultaneously, and the two kinds of information are mutually supplemented and superposed. In visual augmented reality, a user can see the real world around it by using a head-mounted display to multiply and combine the real world with computer graphics.

Disclosure of Invention

The embodiment of the application provides an AR or MR glasses for improve the interior electronic components overall arrangement of AR or MR glasses, mirror leg weight about the equilibrium makes the mirror leg be convenient for accomodate, fold, and convenience of customers wears and deposits more.

In order to achieve the above purpose, the embodiment of the present application adopts the following technical solutions:

in a first aspect, there is provided AR or MR glasses, the device comprising: the glasses comprise a glasses frame, a first glasses leg, a second glasses leg, a first hinge and a second hinge; one end of the first glasses leg is connected with the glasses frame through a first hinge; one end of the second glasses leg is connected with the glasses frame through a second hinge; the distance from the first hinge to the frame is different from the distance from the second hinge to the frame.

Embodiments of the present application provide an AR or MR eyewear. The left and right temples can be folded by arranging the hinges at different positions of the left and right temples, and the left and right temples do not interfere with each other after being folded. The Type-C interface which is originally arranged on one side is split in function and is respectively arranged on the left side and the right side of the glasses leg. The electronic components of the AR or MR glasses are respectively arranged on the left and right glasses legs, so that the left and right glasses legs are uniform in quality, and the wearing comfort is improved. Simultaneously, owing to with the design of electronic components dispersion, mirror leg thickness reduces, and the wiring between the mirror leg reduces, and the volume reduces by a wide margin, and convenience of customers carries and deposits.

Drawings

Fig. 1 is a schematic diagram of a Type-C interface female socket provided in an embodiment of the present application;

FIG. 2 is a schematic diagram of a Type-C interface male connector according to an embodiment of the present application;

fig. 3 is a schematic diagram of a Type-C interface pin provided in an embodiment of the present application;

fig. 4 is a first schematic structural diagram of an AR or MR glasses according to an embodiment of the present application;

fig. 5 is a schematic structural diagram of an AR or MR glasses according to an embodiment of the present application;

fig. 6 is a schematic structural diagram of an AR or MR glasses according to an embodiment of the present application.

Detailed Description

In the following, some concepts related to the embodiments of the present application are briefly introduced, and the technical solutions in the embodiments of the present application will be clearly and completely described with reference to the drawings in the embodiments of the present application. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present application.

In the description of this application, "/" means "or" unless otherwise stated, for example, A/B may mean A or B. "and/or" herein is merely an association describing an associated object, and means that there may be three relationships, e.g., a and/or B, which may mean: a exists alone, A and B exist simultaneously, and B exists alone. Further, "at least one" means one or more, "a plurality" means two or more. The terms "first", "second", and the like do not necessarily limit the number and execution order, and the terms "first", "second", and the like do not necessarily limit the difference.

First, technical terms designed in the embodiments of the present application are introduced:

AR: it is called Augmented Reality technology. The AR is a new technology for seamlessly integrating real world information and virtual world information, and is a technology for applying virtual information to the real world and sensing the virtual information by human senses by superposing entity information (visual information, sound, taste, touch and the like) which is difficult to experience in a certain time-space range of the real world after simulation through scientific technologies such as computers and the like so as to achieve sensory experience beyond reality. The real environment and the virtual object are superimposed on the same picture or space in real time and exist simultaneously.

The augmented reality technology not only shows real world information, but also displays virtual information simultaneously, and the two kinds of information are mutually supplemented and superposed. In visual augmented reality, a user can see the real world around it by using a head-mounted display to multiply and combine the real world with computer graphics.

The augmented reality technology comprises new technologies and new means such as multimedia, three-dimensional modeling, real-time video display and control, multi-sensor fusion, real-time tracking and registration, scene fusion and the like. Augmented reality provides information that is generally different from what human beings can perceive.

MR: all known as Mixed Reality. MR is a set of technology combinations that provide not only new viewing methods but also new input methods, all of which are combined with each other, thus driving innovation. The combination of input and output is a key differentiation advantage for small and medium-sized enterprises. Therefore, mixed reality can directly influence your workflow and help your staff to improve work efficiency and innovation capability. Let us look at some feasible schemes to understand the working principle and what benefits it has.

The mixed reality technology is a further development of the virtual reality technology, and the technology is used for building an interactive feedback information loop among the real world, the virtual world and a user by presenting virtual scene information in a real scene so as to enhance the reality sense of the user experience.

VR: it is called Virtual Reality technology. The VR technology is an important direction of simulation technology, is a collection of various technologies such as simulation technology, computer graphics man-machine interface technology, multimedia technology, sensing technology, network technology and the like, and is a challenging advanced subject and research field of cross technology. The virtual reality technology mainly comprises the aspects of simulating environment, perception, natural skill, sensing equipment and the like. The simulated environment is a three-dimensional realistic image generated by a computer and dynamic in real time. Perception means that an ideal VR should have the perception that everyone has. In addition to the visual perception generated by computer graphics technology, there are also perceptions such as auditory sensation, tactile sensation, force sensation, and movement, and even olfactory sensation and taste sensation, which are also called multi-perception. The natural skill refers to the head rotation, eyes, gestures or other human body behavior actions of a human, and data adaptive to the actions of the participants are processed by the computer, respond to the input of the user in real time and are respectively fed back to the five sense organs of the user. The sensing device refers to a three-dimensional interaction device.

DP: known collectively as DisplayPort, is the first display communication port that relies on packetized data transmission technologies found in ethernet, USB, and PCI Express technologies. It can be used for both internal and external display connections. Unlike past standards that require fixed transmission of timer signals within differential pairs at each output, the DisplayPort protocol is based on small data packets called micro-packets that can embed timer signals in the data stream. Its advantage is less pins and higher resolution. The use of data packets also allows the use of DisplayPort to be scalable, meaning that over time additional functionality can be added without significant changes to the physical communication ports themselves.

DisplayPort can be used to transmit audio and video simultaneously, each of which can be transmitted separately without the other. Each color channel in the video signal path may have 6 to 16 bits, the audio path may have up to 8 channels of 24-bit 192kHz uncompressed PCM audio, or the compressed audio format may be encapsulated in an audio stream. A bi-directional, half-duplex auxiliary channel carries device management and device control data for the main link, such as the VESAEDD, MCCS, and DPMS standards. Further, the communication port is capable of carrying bidirectional USB signals.

The DisplayPort connector may have 1, 2, or 4 differential data pairs (lanes) on the main link, each lane may have an original code rate of 1.62, 2.7, or 5.4Gbit/s on a self-timer basis operating at 162, 270, or 540 MHz. The data is 8b/10b encoded, i.e. every 8-bit message is encoded in 10-bit symbols. Thus, the effective data transmission rate per channel after decoding is 1.296, 2.16, 4.32Gbit/s (or 80% of the total).

Type-C: the Universal Serial Bus (USB) interface is a hardware interface specification of a USB. The new version of the interface is highlighted by a slimmer design, faster transmission speeds (up to 10Gbps) and more aggressive power transmission (up to 100W). The Type-C double-sided pluggable interface has the greatest characteristic of supporting double-sided insertion of a USB interface, formally solves the worldwide problem of 'the USB can not be inserted correctly for ever', and is convenient to insert on the front side and the back side. Meanwhile, the USB data line used with the USB data line is also thinner and lighter.

Fig. 1 shows a schematic diagram of the female socket of the Type-C interface. It can be seen that there are 24 pins in the female socket, where the power and ground lines occupy 8 pins (including 4 VBUS and 4 GND). There are 16 remaining, of which two groups of 4 (two D + and two D-) are used for USB2.0 transmission and two groups of 8 (RX1+, RX1-, RX2+, RX2-, TX1+, TX1-, TX2+, TX2-) are used for transmitting USB3.0 data. The remaining 4 SBUs 1, SBUs 2, CC1, CC2 are signals that conventional USB interfaces do not have. The pin CC (configuration channel, including CC1 and CC2) is a key for the USB Type-C interface to implement forward and reverse insertion, and carries the functions of confirming the transmission direction and confirming forward and reverse insertion during the connection process of the Type-C interface, as well as the function of signal transmission, so as to implement the functional configuration of the load. When one CC serves as a configuration signal of the Type-C interface, the other CC serves as a power supply of an E-Marker chip on the cable. The remaining SBUs 1 and 2 are auxiliary signals and have different uses in different application scenarios. For example, when the DP signal transmission is performed in the ALT MODE, the DP signal transmission is performed as an audio transmission channel, and when the Type-C analog audio headset accessory MODE is entered, the DP signal transmission is performed as a microphone signal transmission channel.

As shown in fig. 2, which is a schematic diagram of the male header of the Type-C interface, comparing with the wiring diagram of the female header, it can be seen that the male header has only one CC, and the CC at the corresponding position with respect to the female header becomes VCONN. When the male plug is inserted into the female socket, the CC on the male plug may be connected with the CC1 on the female socket or connected with the CC2 on the female socket, which corresponds to the two cases of positive insertion and negative insertion. One chip is needed to detect whether the CC on the male plug is connected with the CC1 on the female plug or connected with the CC2 on the female plug, so as to control the signal corresponding relation of correct adaptation data transmission and audio/video transmission inside the device.

FIG. 3 is a detailed schematic diagram of a male connector of a Type-C interface, wherein SSRXp1, SSRXn1, SSTXp1, SSTXn1 correspond to RX1+, RX1-, TX1+, TX 1-in FIG. 2, respectively; SSRXp2, SSRXn2, SSTXp2, SSTXn2 correspond to RX2+, RX2-, TX2+, TX2-, respectively, in FIG. 2.

The inventive principle is described below:

at present, most wearable smart devices are relatively thick and heavy, especially AR or VR glasses. When the weight is too heavy, it is a burden to the wearer and is uncomfortable. Also, since the temples are thick, it is difficult to fold. Even if the glasses can be folded, the glasses are easy to interfere with each other, and the left and right temples cannot be completely folded like ordinary glasses. In addition, since AR or MR glasses are small, it is necessary to store electronic components in temples. In order to realize data transmission between the AR or MR glasses and other devices, in one implementation mode, video, audio and information transmission with a computer can be realized by arranging a Type-C interface on the glasses legs of the AR or MR glasses. However, the above technical solutions have the following disadvantages: when electronic components on the Type-C interface glasses leg do not need to communicate with a computer, the glasses leg is difficult to fold and inconvenient to store due to the fact that the glasses leg is connected with the glasses leg provided with the Type-C interface in a wiring mode from the glasses frame. Simultaneously, one side sets up the scheme of Type-C interface and can lead to glasses weight unbalance, makes to wear not comfortable enough.

Further, the present application contemplates the invention of AR or MR glasses to solve the above-mentioned technical problems.

The first embodiment is as follows:

the embodiment of the application provides AR or MR glasses, which are applied to AR augmented reality equipment or MR mixed reality equipment.

As shown in fig. 4, the AR or MR eyeglasses 20 include: a frame 25, a first temple 21, a second temple 23, a first hinge 22, and a second hinge 24; one end of the first temple 21 is connected with the frame 25 through the first hinge 22; one end of the second temple 23 is connected with the spectacle frame 25 through a second hinge 24; the first hinge 22 is at a different distance from the frame 25 than the second hinge 24 is at from the frame 25.

In order to facilitate storage in the folded state of the temples without the temples interfering with each other when the temples are folded, the distance between the folded first temple 21 and the folded second temple 23 is less than 1mm in two different states of the AR or MR eyeglasses 20 as shown in fig. 4 and 5.

In the embodiment of the present application, the folding positions of the AR or MR glasses 20 are designed according to the thicknesses of the glasses legs after the components are added, for example, the thicknesses of the glasses legs are 5mm and 7mm respectively, and the folding positions are basically different by 6-7mm to accommodate the thickness of the glasses legs. The length of folding position distance glasses body and the folding position of left and right glasses leg who long and who short depend on the design, do not have fixed requirement.

In addition, in the embodiment of the present application, as shown in fig. 6, the AR or MR eyeglasses 20 further include: a data processing module 200, a first bus 203, a second bus 204. And a data processing module 200 for processing data input and/or output to the AR or MR glasses 20, wherein a first end of the first bus 203 is connected to the data processing module through a terminal of the first temple 21, and a second end of the first bus 203 is used for connecting an external device. A first end of the second bus 204 is connected to the data processing module 200 through the tip of the second temple 23, and a second end of the second bus 204 is used for connecting an external device.

In the embodiment of the application, through setting up two buses, thereby two buses are drawn forth from two mirror legs respectively and are connected external equipment, and then are convenient for optimize the overall arrangement of components and parts in the glasses, reduce the line of walking through the picture frame between the mirror leg.

The second end of the first bus 203 and the second end of the second bus 204 are respectively connected to pins of a predetermined physical interface, so that when the predetermined physical interface is connected to an external device, the second end of the first bus 203 and the second end of the second bus 204 are connected to the external device.

In the embodiment of the application, the external equipment is connected through connecting the two buses on the same physical interface, so that the two glasses legs and the external equipment can be subjected to data exchange simultaneously on the premise of not changing the original transmission mode.

The data processing module 200 includes a first sub-module 201 and a second sub-module 202. Wherein the first sub-module 201 is arranged in the first temple 21 and the second sub-module 202 is arranged in the second temple 23.

The first end of the first bus 203 is connected to the data processing module 200 through the end of the first temple 21, and specifically includes: a first end of the first bus 203 is connected to the first sub-module 201 through the tip of the first temple 21. The first end of the second bus 204 is connected to the data processing module 200 through the end of the second temple 23, and specifically includes: a first end of the second bus 204 is connected to the second sub-module 202 through an end of the second temple 23.

In the embodiment of the application, the first sub-module 201 is arranged in the first glasses leg 21, and the second sub-module 202 is arranged in the second glasses leg 23, so that the balance weight is more balanced, the use by a user is facilitated, and the user experience is improved. In addition, in the present application, by adopting a manner that the first end of the first bus 203 is connected to the first sub-module 201 through the tail end of the first temple 21, and the first end of the second bus 204 is connected to the second sub-module 202 through the tail end of the second temple 23, the data transmitted by the first bus 203 can be directly processed by using the first sub-module 201, and the data transmitted by the second bus 204 is processed by using the second sub-module 202, so that the routing passing through the inside of the lens frame is reduced.

When the physical interface is a Type-C interface, in order to improve transmission efficiency and optimize a transmission mode for transmitting data such as video, audio, and data between the AR or MR glasses 20 and an external device, in an embodiment of the present application:

the second end of the first bus 203 and the second end of the second bus 204 are respectively connected to pins of the Type-C interface 205, so that when the Type-C interface 205 is connected to an external device, the second ends of the first bus 203 and the second bus 204 are connected to the external device. The first sub-module 201 is configured to process data of the USB transmission standard, and the second sub-module 202 is configured to process data of the DP transmission standard.

In order to enable the Type-C interface 205 to satisfy the basic data transmission function and have a colorful audiovisual effect, the following connection method can be adopted to enable the Type-C interface 205 to support USB2.0 and DP four-channel modes:

a first bus 203 for connecting the D +, D-, VBUS, GND pins in the Type-C interface 205 to the first sub-module 201, and a second bus 204 for connecting the SSTXn1, SSTXp1, SSTXn2, SSTXp2, SSRXn1, SSRXp1, SSRXn2, SSRXp2, SBU1, SBU2 pins in the Type-C interface 205 to the second sub-module 202.

In order to enable the Type-C interface 205 to satisfy the basic video and audio functions and perform high-speed data transmission, the following connection method may be adopted to enable the Type-C interface 205 to support single or dual channel modes of USB3.1, USB2.0 and DP:

a first bus 203 for connecting the pins D +, D-, VBUS, GND, SSTXn1, SSTXp1, SSRXn1, and SSRXp1 in the Type-C interface 205 to the first sub-module 201, and a second bus 204 for connecting the pins SSTXn2, SSTXp2, SSRXn2, SSTRp2, SBU1, and SBU2 in the Type-C interface 205 to the second sub-module 202.

In order for the AR or MR glasses 20 to acquire which of the two connection methods is used, the AR or MR glasses 20 further include: and a detection module, configured to detect a connection state of the first bus 203 and the second bus 204.

Wherein, in the first connection state, the first bus 203 connects the D +, D-, VBUS, GND pins in the Type-C interface 205 to the first sub-module 201, and the second bus 204 connects the SSTXn1, SSTXp1, SSTXn2, SSTXp2, SSRXn1, SSRXp1, SSRXn2, SSRXp2, SBU1, SBU2 pins in the Type-C interface 205 to the second sub-module 202.

In the second connection state, the first bus 203 connects the D +, D-, VBUS, GND, SSTXn1, SSTXp1, SSRXn1, SSRXp1 pins in the Type-C interface 205 to the first sub-module 201, and the second bus 204 connects the SSTXn2, SSTXp2, SSRXn2, SSTRp2, SBU1, SBU2 pins in the Type-C interface 205 to the second sub-module 202.

The first sub-module 201 is configured to select, according to a detection result of the detection module, a version of a USB transmission standard used when data transmission is performed with an external device through the first bus 203.

When detecting that the AR or MR glasses 20 are in the first connection state, the USB2.0 transmission standard is used for data transmission, and when detecting that the AR or MR glasses 20 are in the second connection state, the USB3.1 transmission standard is used for data transmission, and meanwhile, the USB standard supported by the external device is used for data transmission according to the support condition of the external device.

The second sub-module 202 is configured to select, according to a detection result of the detection module, a version of a DP transmission standard used when data transmission is performed with the external device through the second bus 204.

When the AR or MR glasses 20 are detected to be in the first connection state, the DP four-channel mode (DP 4lane) is adopted, supporting 4K (4096X2160)60Hz image output and higher audio decoding rate, and when the AR or MR glasses 20 are detected to be in the second connection state, the DP single or dual-channel mode (DP 1lane or DP 2lane) is adopted, supporting 1080P image output and lower audio decoding rate.

Exemplarily, the embodiment of the present application further provides a data line. The data line is divided into a standard a and a standard B, two standards. One end of the data line is provided with a Typr-C standard hardware interface, and the other end of the data line is divided into two parts which can be respectively connected with interfaces at the tail ends of two mirror legs of AR or MR glasses 20. So that the data lines realize the functions of the first bus 203 and the second bus 204 in the above embodiments. Wherein the data lines of standard a enable the first bus 203 and the second bus 204 to be in a first connection state; with the data line of standard B, the first bus 203 and the second bus 204 can be brought into the second connection state.

In the using process, when the AR or MR glasses 20 provided by the embodiment of the present application are applied to a scene of high definition screen display (i.e. at this time, a large amount of audiovisual data needs to be transmitted through the DP transmission protocol), the data line of standard a is used to connect the AR or MR glasses 20 with an external electronic device. Then, the detection module detects the connection status of the data line, and determines that the pins SSTXn1, SSTXp1, SSRXn1 and SSRXp1 in the Type-C interface 205 have been connected to the second sub-module 202 for processing DP transmission standard data. Thus, a higher version and faster DP transmission standard may be used.

When the AR or MR glasses 20 provided in the embodiment of the present application are applied to a case where a large amount of sensor data needs to be transmitted through the USB transmission protocol, the AR or MR glasses 20 are connected to an external electronic device using a data line of standard B. Then, the detection module detects the connection status of the data line, and determines that the pins SSTXn1, SSTXp1, SSRXn1 and SSRXp1 in the Type-C interface 205 are connected to the first sub-module 201 for processing USB transmission standard data. Thus, a higher version and faster USB transmission standard may be used.

AR or MR glasses that this affair example provided, through evenly placing electronic components both sides mirror leg, carry out the split with a Type-C interface, place DP and USB function respectively on both sides mirror leg, through an external Type-C data line, make glasses can carry out data interchange with external equipment, less wiring through the picture frame between the mirror leg, make the mirror leg can fold, and simultaneously, through the design of hinge position, make glasses can not the country after the mirror leg is folding interfere, the glasses volume after folding reduces by a wide margin, convenience of customers deposits.

In another embodiment, the present application further provides an electronic device, which includes the AR or MR glasses 20 provided in the above embodiments.

In addition, the electronic device may further include: other functional devices for implementing AR functions. Such as a computing host, power adapter, etc.

Through the description of the above embodiments, it is clear to those skilled in the art that, for convenience and simplicity of description, the foregoing division of the functional modules is merely used as an example, and in practical applications, the functional modules may be distributed to be completed by different functional modules according to needs, that is, the internal structure of the device may be divided into different functional modules to complete all or part of the functions described above. For the specific working process of the device described above, reference may be made to the corresponding process in the foregoing method embodiment, which is not described herein again.

In the above example, the first temple and the second temple in fig. 4 and 5 are only for convenience of understanding, and in fact, the first temple is not necessarily referred to as a left temple, and the second temple is not necessarily referred to as a right temple.

In the embodiments provided in the present application, it should be understood that the disclosed apparatus may be implemented in other ways. For example, the above-described device embodiments are merely illustrative, and for example, the division of the functional blocks is only one logical division, and other divisions may be realized in practice, for example, a plurality of blocks or components may be combined or integrated into another system, or some features may be omitted, or not executed.

The above description is only for the specific embodiments of the present application, but the scope of the present application is not limited thereto, and any person skilled in the art can easily conceive of the changes or substitutions within the technical scope of the present application, and shall be covered by the scope of the present application. Therefore, the protection scope of the present application shall be subject to the protection scope of the claims.

Claims (8)

1. AR or MR eyeglasses, comprising: the glasses comprise a glasses frame, a first glasses leg, a second glasses leg, a first hinge and a second hinge;

one end of the first glasses leg is connected with the glasses frame through the first hinge;

one end of the second glasses leg is connected with the glasses frame through the second hinge;

the distance from the first hinge to the frame is different from the distance from the second hinge to the frame.

2. The AR or MR glasses according to claim 1,

the distance between the first leg after folding and the second leg after folding is less than 1 mm.

3. The AR or MR glasses according to claim 1, wherein the glasses further comprise a data processing module, a first bus, a second bus, wherein:

the data processing module is used for processing data input and/or output to the glasses;

the first end of the first bus is connected to the data processing module through the tail end of the first glasses leg, and the second end of the first bus is used for connecting external equipment;

the first end of the second bus is connected to the data processing module through the tail end of the second glasses leg, and the second end of the second bus is used for connecting external equipment.

4. The AR or MR glasses according to claim 3,

the second end of the first bus and the second end of the second bus are respectively connected with pins of a preset physical interface, so that when the preset physical interface is connected with external equipment, the second end of the first bus and the second end of the second bus are connected with the external equipment.

5. The AR or MR glasses according to claim 3,

the data processing module comprises a first sub-module and a second sub-module; the first sub-module is arranged in the first glasses leg, and the second sub-module is arranged in the second glasses leg;

the first end of the first bus is connected to the data processing module through the end of the first temple, and specifically includes: a first end of the first bus connected to the first sub-module through a tip of the first temple;

the first end of the second bus is connected to the data processing module through the end of the second temple, and the method specifically includes: a first end of the second bus is connected to the second sub-module through an end of the second temple.

6. The AR or MR glasses according to claim 5,

the second end of the first bus and the second end of the second bus are respectively connected with pins of a Type-C interface, so that when the Type-C interface is connected with external equipment, the second end of the first bus and the second end of the second bus are connected with the external equipment;

the first submodule is used for processing data of a Universal Serial Bus (USB) transmission standard;

the second submodule is used for processing data of a display interface DP transmission standard;

the first bus is used for connecting D +, D-, VBUS and GND pins in the Type-C interface to the first submodule;

the second bus is used for connecting pins SSTXn1, SSTXp1, SSTXn2, SSTXp2, SSRXn1, SSRXp1, SSRXn2, SSRXp2, SBU1 and SBU2 in the Type-C interface to the second sub-module;

or the first bus is used for connecting D +, D-, VBUS, GND, SSTxn1, SSTxp1, SSRXn1 and SSRXp1 pins in the Type-C interface to the first sub-module;

and the second bus is used for connecting pins SSTXn2, SSTXp2, SSRXn2, SSTsrp 2, SBU1 and SBU2 in the Type-C interface to the second sub-module.

7. The AR or MR glasses according to claim 6, wherein the glasses further comprise: a detection module;

the detection module is used for detecting the connection state of the first bus and the second bus; wherein, in a first connection state, the first bus connects the D +, D-, VBUS, GND pins in the Type-C interface to the first sub-module, and the second bus connects the SSTXn1, SSTXp1, SSTXn2, SSTXp2, SSRXn1, SSRXp1, SSRXn2, SSRXp2, SBU1, SBU2 pins in the Type-C interface to the second sub-module; in a second connection state, the first bus connects D +, D-, VBUS, GND, SSTxn1, SSTxp1, SSRXn1 and SSRXp1 pins in the Type-C interface to the first sub-module; the second bus connects pins SSTXn2, SSTXp2, SSRXn2, SSTRp2, SBU1 and SBU2 in the Type-C interface to the second sub-module;

the first submodule is used for selecting the version of the USB transmission standard adopted when the data transmission is carried out between the first bus and the external equipment according to the detection result of the detection module;

and the second submodule is used for selecting the version of the DP transmission standard adopted when data transmission is carried out between the second bus and the external equipment according to the detection result of the detection module.

8. The AR or MR glasses according to any one of claims 3-7,

the first bus is detachably connectable with an end of the first temple;

the second bus can be detachably connected with the tail end of the second glasses leg.

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