TWM509357U - Intelligent glasses - Google Patents

Description

Smart glasses

The present invention is a kind of smart glasses, especially one that can adjust the display position to the user's eyes according to the different distances between the eyes of different users, so that the user can watch the correct or better visual display angle when wearing. And smart glasses that enhance the visual comfort when worn.

The custom-made smart glasses may be equipped with an external projection display on the frame of the general glasses, or the projection display and the frame are integrated. Therefore, the Republic of China Patent Publication No. 201443510 discloses a "smart glasses", please As shown in the first figure, the lens body 1 is provided with two frames 10, and the pair of frames 10 are respectively fitted with a lens 11 which can be combined with a smart phone 12 or a notebook computer. 13 is connected to provide an image on the pair of lenses 11 that is received by the user's eyes.

Although the technical solution can easily display the image and be viewed by the user's eyes, since the eyes of different users have different interpupillary distances, the lens body 1, the pair of frames 10 and their corresponding ones The lens 11 is designed to have a corresponding size. Therefore, the image projected by the pair of lenses 11 is actually a fixed orientation. Therefore, the orientation of the image is different when different user's pupil distances are different. Causes the user to feel uncomfortable with the pressure and easy to get tired. Therefore, how to improve the above-mentioned shortcomings, that is, the application for this case The technical difficulties that people want to solve are located.

In view of the lack of practice, the purpose of this creation is to develop a suitable position that can adjust the display position to the user's eyes according to the different distances between the eyes of different users, so that the user can watch correctly or better when wearing. The smart glasses that visually display the angle and enhance the visual comfort when worn.

In order to achieve the above object, the present invention provides a smart glasses, comprising: a lens body, which is provided with two frame frames and two side frames; a support seat is provided with a clamping portion on one side, the clamping The movable portion is clamped between the pair of frames, the support base is provided with a receiving space and a corresponding first opening and a second opening, wherein the receiving space is provided with a microcontroller; four warning lights, the Each of the warning lights is electrically connected to the microcontroller, wherein two warning lights are fixed on a surface side of the support base, and the other two warning lights are fixed on the other side of the support seat; a first near-eye The optical device is movably fitted to the first opening via a first fitting portion, the first near-eye optical device is provided with a first imaging lens facing the one of the frames; and a second near-eye optical device is connected to the optical device The second engaging portion is movably coupled to the second opening, and the second near-eye optical device is provided with a second imaging lens facing the other of the frames, and the first imaging lens is electrically connected to the second imaging lens. Smart glasses host its processor

The microcontroller is electrically connected to a sound emitting component, and the first camera lens and the second camera lens are a photosensitive coupled device (CCD) or an image sensor (CMOS).

The present invention provides another embodiment. The present invention provides a smart glasses, comprising: a lens body with two frames and two side frames; a support base fixed on one side There is a clamping portion, the clamping portion is movably clamped between the pair of frames, the supporting seat is provided with an accommodating space and a corresponding first opening and a second opening, and the receiving space is provided with a micro a first micro motor and a second micro motor, the first micro motor and the second micro motor are fixed on opposite sides of the accommodating space, and the first micro motor and the second micro motor Electrically connecting the micro-controller, the first micro-motor is connected to a first gear, the second micro-motor is connected to a second gear, the micro-controller is electrically connected to a control button, and the control button is fixed on the support One end of the surface; a first near-eye optical device is movably fitted to the first opening via a first fitting portion, and a first rack is disposed on a side of the first fitting portion, and the first rack is movably coupled The second gear is configured to be movably fitted to the second opening via a second fitting portion, and the second fitting portion is provided with a second rack on a side thereof, the second rack The movable shaft is connected to the second gear, and the first near-eye optical device is provided a first imaging lens of the one of the frames, the second near-eye optical device is provided with a second imaging lens facing the other of the frames, and the first imaging lens and the second imaging lens are electrically connected to the smart lens. Host its processor.

The first imaging lens and the second imaging lens are a photosensitive coupled device (CCD) or an image sensor (CMOS).

The first camera lens and the second camera lens capable of detecting and tracking the position of the eyeball are provided by the present invention, and the eyeball detection result is calculated and determined by the processor, and the user can manually or automatically use the first near-eye optics. The device and the second near-eye optical device are adjusted to a preferred position corresponding to the user's eyes, so that the creation can be adjusted according to different distances between different users' eyeballs to adjust the relative display position to the user's eyes. Appropriately, the user can watch the correct or better visual display angle and improve the visual comfort when wearing.

[Use]

1‧‧‧ glasses body

10‧‧‧ Frame

11‧‧‧ lenses

12‧‧‧Smart Phone

13‧‧‧Note Computer

[this creation]

2‧‧‧ glasses body

20‧‧‧ frames

21‧‧‧ Side frame

3‧‧‧ support

3A‧‧‧ end face

30‧‧‧Clamping Department

31‧‧‧ accommodating space

32‧‧‧First opening

33‧‧‧second opening

34‧‧‧Microcontroller

34A‧‧‧Red warning light

34B‧‧ Green warning light

35‧‧‧Sounding components

36‧‧‧First micromotor

36A‧‧‧First gear

37‧‧‧Second micromotor

37A‧‧‧second gear

38‧‧‧Control button

4‧‧‧First near-eye optical device

40‧‧‧First mating department

40A‧‧‧first rack

41‧‧‧First camera lens

41A‧‧‧First range image detection

5‧‧‧Second near-eye optical device

50‧‧‧Second fitting

50A‧‧‧second rack

51‧‧‧Second camera lens

51A‧‧‧Second range image detection

6‧‧‧ eyes

7‧‧‧Host

71‧‧‧ Processor

The first picture is a schematic diagram of the implementation of the wisdom glasses used.

The second figure is a three-dimensional schematic diagram of the smart glasses of the preferred embodiment of the present invention manually adjusting the optimal image projection position according to the user's pupil distance.

The second A picture is a schematic diagram of the action of the smart glasses of the preferred embodiment of the present invention to manually adjust the optimal image projection position according to the user's distance.

The second figure B is a schematic diagram of the action of the smart glasses of the preferred embodiment of the present invention to manually adjust the optimal image projection position according to the user's distance.

The second C picture is a schematic diagram of the smart glasses of the preferred embodiment of the present invention, which manually adjusts the optimal image projection position according to the user's distance and uses the sound to remind the action.

The third figure is a three-dimensional schematic diagram of the smart glasses of the preferred embodiment of the present invention automatically adjusting the optimal image projection position according to the user's pupil distance.

The third A picture is a pre-action diagram of the smart glasses of the preferred embodiment of the present invention automatically adjusting the optimal image projection position according to the user's distance.

The third B diagram is a schematic diagram of the action of the smart glasses of the preferred embodiment of the present invention automatically adjusting the optimal image projection position according to the user's pupil distance.

In order for your review board to have a clear understanding of the content of this work, please refer to the preferred embodiment of the following description, please refer to it.

Referring to the second figure, the present invention provides a smart glasses, comprising: a glasses body 2, a support base 3, a first near-eye optical device 4, a second near-eye optical device 5, and two Red warning light 34A and two green warning lights 34B.

The lens body 2 is provided with two frame 20 and two side frames 21, which are commonly used wearing glasses, and the pair of frames 20 can be provided with lenses having no degree or degree.

The support base 3 is fixed with a clamping portion 30 on one side thereof. In order to balance the support base 3, the clamping portion 30 is preferably located in the middle of the support base 3. The clamping portion 30 can be movably clamped in the pair. Between the frames 20, a accommodating space 31 and a corresponding first opening 32 and a second opening 33 are formed in the supporting base 3. The micro-controller 34 is disposed in the accommodating space 31. The controller 34 is preferably fixedly disposed, and the microcontroller 34 is electrically connected to each of the red warning light 34A and the green warning light 34B to control the operation of each warning light.

The first near-eye optical device 4 is movably fitted to the first opening 32 via a first fitting portion 40, so that the first near-eye optical device 4 preferably fits within a range in which the first opening 32 is movable. The first near-eye optical device 4 is provided with a first imaging lens 41 facing the one of the frames 20, and the first imaging lens 41 is preferably disposed to face the lens in the frame 20. The position of the user's eyes is sensed.

The second near-eye optical device 5 is movably fitted to the second opening 33 via a second fitting portion 50, so that the second near-eye optical device 5 is preferably embedded in the movable range of the second opening 33. The second near-eye optical device 5 is provided with a second imaging lens 51 facing the other of the frames 20, and the second imaging lens 51 is preferably disposed to pass through the frame 20. The position of the user's eye is sensed by the lens. In the embodiment, the first camera lens 41 and the second camera lens 51 are preferably a photosensitive-coupled device (CCD) or an image sensor ( CMOS), and the first imaging lens 41 and the second imaging lens 51 respectively have the characteristics of a first range image detection 41A and a second range image detection 51A, please cooperate Referring to FIG. 2A, the first camera lens 41 and the second camera lens 51 are electrically connected to a host 7 of the smart glasses and a processor 71 thereof. The processor 71 is also electrically connected to the microcontroller 34. .

The pair of red warning lights 34A and the pair of green warning lights 34B are respectively electrically connected to the microcontroller 34. One of the red warning lights 34A and the one of the green warning lights 34B are fixed on the surface side of the support base 3, The preferred position is such that one of the eyes of the user can be viewed. The other red warning light 34A and the other green warning light 34B are fixed on the other side of the surface of the support base 3. The user is made visible to the other of the eyes.

Referring to the second figure and the second figure A, the embodiment is applied to manual adjustment, wherein when the user wears the glasses body 2, the first near-eye display device 4 or the second near-eye display device 5 may The pair of eyes 6 are not aligned with the user. At this time, the first camera lens 41 or the second camera lens 51 that faces the face of the user and can sense the position of the eyeball is provided by the present invention. The first camera lens 41 is provided. Or the second camera lens 51 can convert the detected eyeball image into an electronic signal and transmit it back to the processor 71 of the host computer 7 for calculation and discrimination. If the operation result does not reach a predetermined sensing data range, the processing is performed. The controller 71 can send a corresponding control signal to the microcontroller 34, and the microcontroller 34 can cause the pair of red warning lights 34A to be electrically conductive, that is, the first near-eye optical device 4 and the second The near-eye optical device 5 is not aligned with the proper position of the pair of eyes 6, so that the user can be informed of the adjustment action; the user can directly determine the first near-eye optical device 4 according to the actual visual observation during actual wear. With the second near vision The relative position of the device 5 and the pair of eyes 6 of the user is adjusted. In this embodiment, the first near-eye optical device 4 and the second near-eye optical device 5 are offset from opposite sides of the support base 3, The user can manually adjust the first near-eye optical device 4 or the second near-eye optical device 5 to slide with respect to the first opening 32 or the second opening 33, respectively, and the first near-eye optical light is disposed 4 due to the frictional force of the fitting. Or the second near-eye optics When the device 5 is not adjusted to move, it can be rubbed by friction.

Please continue to refer to the second figure B, wherein the movement of the first near-eye optical device 4 on the support base 3 and the first range image detection 41A according to the first imaging lens 41, or the second The movement of the near-eye optical device 5 on the support base 3 is in accordance with the second range image detection 51A of the second imaging lens 51, and when the appropriate positions of the pair of eyes 6 corresponding to the user are respectively detected. The calculation and determination result of the processor 71 indicates that the user has been adjusted to the correct position. At this time, the processor 71 can send a corresponding control signal to the microcontroller 34, so that the microcontroller 34 can make the pair of greens. The warning light 34B is turned on and the red warning light 34A is turned off, that is, the user is informed that the first near-eye optical device 4 and the second near-eye optical device 5 have been adjusted to be in a relatively good position with respect to the pair of eyes 6 of the user. It is the characteristics of the creation.

Please continue to refer to the second C diagram. In the embodiment, the microcontroller 34 is further electrically connected to a sounding component 35, whereby the user will use the first near-eye optical device 4 or the second near-eye optical device 5 When adjusted to the correct position, in addition to the indication of the light number, the microcontroller 34 can still make the sounding element 35 sound, and a better prompt effect can be achieved.

Referring to the third figure, the present embodiment is applied to the self-adjusting smart glasses, and includes the glasses body 2, the support base 3, the first near-eye optical device 4, and the second near-eye optical device 5.

The lens body 2 is similarly provided with the pair of frame 20 and the pair of side frames 21, and the support base 3 is sandwiched between the pair of frames 20 by the clamping portion 30. The accommodating space 31 and the corresponding first opening 32 and the second opening 33 are disposed in the accommodating space 31, the first micro motor 36 and the second micro motor 37. The first micro motor 36 and the second micro motor 37 are fixed on opposite sides of the accommodating space 31, and the first micro motor 36 The second micro-motor 37 is electrically connected to the micro-controller 34. The first micro-motor 36 is connected to a first gear 36A. The second micro-motor 37 is connected to a second gear 37A. Please refer to the third figure A. The controller 34 is also electrically connected to the host 7 of the smart glasses, and the processor 71 is electrically connected to a control button 38. The control button 38 is fixed on the surface 3A of the support base 3. The control button 38 is used to activate the automatic adjustment function. The first near-eye optical device 4 is movably fitted to the first opening 32 via the first fitting portion 40. A first rack 40A is rotatably coupled to the first gear 36A, and the second near-eye optical device 5 is movably fitted to the second opening via the second fitting portion 50. 33. A second rack 50A is disposed on a side of the second engaging portion 50. The second rack 50A is movably coupled to the second gear 37A. The first near-eye optical device 4 is provided with one of the frames. 20 of the first imaging lens 41, the second near-eye optical device 5 is provided with the first frame 20 The imaging lens 51, the first imaging lens 41 which is connected to the host processor 7 and 51 71 of the second imaging lens electrically.

Referring to the third and third A diagrams, the embodiment is applied to automatic adjustment, wherein when the user wears the glasses body 2, the first near-eye optical device 4 or the second near-eye optical device 5 may The pair of eyes 6 are not aligned with the user. At this time, the user only needs to press the control button 38, and the processor 71 of the host computer 7 can receive the eyeball returned by the first camera lens 41 or the second camera lens 51. The electronic signal of the image is calculated and determined, and the processor 71 can generate a corresponding correction position control signal to the microprocessor 34, so that the microcontroller 34 outputs the first micro motor 36 and the second micro. a first motor 36 drives the first gear 36A, the first gear 36A drives the first rack 40A, and the first fitting portion 40 is coupled to the first near-eye optical device 4, and the second The second motor 37 drives the second gear 37A, and the second gear 37A drives the second rack 50A, and the second fitting portion 50 is coupled to the second near-eye optical device 5, so that the The first near-eye optical device 4 and the second near-eye optical device 5 are displaced to a relatively appropriate position of the pair of eyes 6 of the user. At this time, please refer to the third B diagram, the processor 71 can generate a The corresponding control signal is given to the microprocessor 34, so that the micro-controller 34 can stop the first micro-motor 36 and the second micro-motor 37, so that the creation can realize the function of automatic adjustment; in addition, it is worth mentioning The first near-eye optical device 4 or the second is provided because the first gear 36A and the first rack 40A and the second gear 37A and the second rack 50A are coupled by friction. The near-eye optical device 5 can be smashed without adjusting the movement.

Please continue to refer to the second picture, the second C picture, the third picture and the third picture A. With the creation of the first camera lens 41 capable of detecting and tracking eye-ball tracking, The second imaging lens 51 is further calculated and determined by the processor 71 for the eyeball detection result, and the user can manually or automatically adjust the first near-eye optical device 4 and the second near-eye optical device 5 to the user. The corresponding position of the eye 6 is correspondingly, so that the creation can be adjusted according to different distances between different eyeballs of the user to adjust the display position to the user's eyes at a relatively appropriate position, so that the user can watch the correct or compare when wearing. Excellent visual display angle and improved visual comfort when worn.

The above discussion is only for the preferred embodiment of the present invention, and is not intended to limit the scope of the patents of the present invention; therefore, the equivalent shape, structure or combination of changes made in the spirit and scope of the present invention should be Covered by the scope of this creation patent.

2‧‧‧ glasses body

20‧‧‧ frames

21‧‧‧ Side frame

3‧‧‧ support

30‧‧‧Clamping Department

31‧‧‧ accommodating space

32‧‧‧First opening

33‧‧‧second opening

34‧‧‧Microcontroller

34A‧‧‧Red warning light

34B‧‧ Green warning light

4‧‧‧First near-eye optical device

40‧‧‧First mating department

41‧‧‧First camera lens

5‧‧‧Second near-eye optical device

50‧‧‧Second fitting

51‧‧‧Second camera lens

Claims (5)

A smart glasses comprising: a lens body having two frames and two side frames; a support seat having a clamping portion on one side, the clamping portion being movably clamped to the pair of frames The support base is provided with a receiving space and a corresponding first opening and a second opening, wherein the receiving space is provided with a microcontroller; four warning lights, each of the warning lights is electrically connected to the micro a controller, wherein two warning lights are fixed on a surface side of the support base, wherein the other two warning lights are fixed on the other side of the support seat; a first near-eye optical device is connected through a first The merging activity is fitted to the first opening, the first near-eye optical device is provided with a first imaging lens facing the one of the frames; and the second near-eye optical device is movably coupled via a second fitting portion a second opening, the second near-eye optical device is provided with a second imaging lens facing the other of the frames, and the first imaging lens and the second imaging lens are electrically connected to a host of the smart glasses, and The processor is also electrically connected to the microcontroller . The smart glasses of claim 1, wherein the microcontroller is electrically connected to a sound emitting component. The smart glasses of claim 1, wherein the first camera lens and the second camera lens are a charge-coupled device (CCD) or an image sensor (CMOS). A smart glasses comprising: a lens body having two frames and two side frames; a support seat having a clamping portion on one side, the clamping portion being movably clamped to the pair of frames The support base is provided with a receiving space and a corresponding first opening and a second opening a micro-controller, a first micro-motor and a second micro-motor, the first micro-motor and the second micro-motor are fixed on opposite sides of the accommodating space, and The first micro motor and the second micro motor are electrically connected to the microcontroller, the first micro motor is connected to a first gear, the second micro motor is connected to a second gear, and the micro controller is electrically connected to a control button The control button is fixed to one end of the support surface; a first near-eye optical device is movably fitted to the first opening via a first fitting portion, and a first tooth is disposed on a side of the first fitting portion The first rack is movably coupled to the first gear; the second near-eye optical device is movably fitted to the second opening via a second fitting portion, and the second fitting portion is provided with a side a second rack, the second rack is movably coupled to the second gear, the first near-eye optical device is provided with a first camera lens facing the one of the frames, and the second near-eye optical device is provided with the first lens The second camera lens of the other frame, the first Like the glasses lens is connected to a second of the imaging lens which is electrically the host processor, and the processor is also connected electrically to the microcontroller. The smart glasses of claim 4, wherein the first imaging lens and the second imaging lens are a charge-coupled device (CCD) or an image sensor (CMOS).