CN113917705A - Intelligent visual interaction system for different light and shade environments and control method thereof - Google Patents

Abstract

The invention discloses a control method of an intelligent visual interaction system, which comprises the following steps: s100: when the control module receives the first signal, the light sensor, the timing device and the displacement sensor are started simultaneously, and then the step S200 is executed; s200: the light sensor records light and shade degrees L1 and L2 of the environment where the liquid crystal lens is located and sends the light and shade degrees to the control module, the displacement sensor monitors a displacement change value delta S of the intelligent visual interaction system, the time of the timing device is recorded as time T1, the time T1 is sent to the control module, and then the step S300 is carried out; s300: the control module calculates a first compensation value delta B1 of the liquid crystal lens and adjusts the light transmittance of the liquid crystal lens according to the value. The invention can pre-calculate the light and shade degree of the following light according to the recorded light change and the moving speed of the user and pre-compensate the light transmittance by the method, thereby providing the eyesight protection function for the user. In addition, the invention also provides an intelligent visual interaction system for different light and shade environments.

Description

Intelligent visual interaction system for different light and shade environments and control method thereof

Technical Field

The invention relates to the technical field of intelligent visual interaction systems, in particular to an intelligent visual interaction system for different light and shade environments and a control method thereof.

Background

With the rapid development of society, the artificial intelligence technology becomes a technology which can provide great convenience for the daily life of people, and the development of the technology is also vigorous. Such as: the technology development of applying artificial intelligence technology to various products in daily life of people is also accelerating, such as intelligent automobiles, intelligent sound boxes, intelligent translation pens, intelligent visual interaction systems and the like.

It is known that spectacles are composed of lenses and frames, which are used for improving vision, protecting eyes or as an article for decorative purposes. However, the existing glasses are generally myopia glasses, aging glasses, sunglasses, or the like, and when a user wears the glasses to enter a certain occasion with different light brightness, the existing glasses do not have the function of automatically adjusting the light transmittance according to different environments, so that various discomfort can be brought to the user of the glasses.

Therefore, there is a need for an intelligent visual interaction system for different light and dark environments and a control method thereof to solve the above problems.

Disclosure of Invention

The invention provides an intelligent visual interaction system control method aiming at the technical defects at present.

The technical scheme adopted by the invention for realizing the purpose is as follows:

an intelligent visual interaction system control method comprises the following steps: s100: when the control module receives the first signal, the control module simultaneously sends a monitoring instruction to the light sensor, the timing device and the displacement sensor so as to start the light sensor, the timing device and the displacement sensor at the same time, and then the step S200 is carried out; s200: the light sensor records the brightness L1 of the environment where the liquid crystal lens of the intelligent visual interaction system is located when the monitoring instruction is received, the displacement sensor monitors the displacement change value delta S of the intelligent visual interaction system, when the displacement change value delta S is larger than a first preset distance, the timing device records the time from the receiving of the monitoring instruction to the time when the displacement change value delta S is larger than the first preset distance as time T1 and sends the time T1 to the control module, the light sensor records the brightness L2 of the environment where the liquid crystal lens is located when the displacement change value delta S is larger than the first preset distance, then the light sensor simultaneously sends L1 and L2 to the control module, and then the process goes to the step S300; s300: the light sensor, the timing device and the displacement sensor enter a sleep mode, the control module calculates a first compensation value delta B1 of the liquid crystal lens according to the received information, and adjusts the light transmittance of the liquid crystal lens according to the first compensation value delta B1.

Further, the first compensation value Δ B1 is calculated as follows:

k1 is a first adjustment parameter that can be set by the control module, and the value of the first adjustment parameter K1 is positive.

In a further improvement, before the step S100, the method further includes the following steps: s010: when the automatic adjusting switch is turned on, the moving distance of the intelligent visual interaction system is monitored in real time through the starting device, and when the moving distance is larger than a second preset distance, the starting device sends the first signal to the control module.

Further improved, after the step S300, the method further includes the following steps: s400: the control module sends a monitoring instruction to the light sensor at an interval of a first preset time T2 after the light transmittance of the liquid crystal lens is adjusted, and the light sensor monitors the brightness L3 of the current environment where the liquid crystal lens is located after receiving the monitoring instruction; when L3 is less than K2 Δ B1, the control module automatically adjusts the interval time for the next monitoring command to be transmitted to K3 × T2; when L3 is greater than K2 × Δ B1, the control module adjusts the transmittance of the liquid crystal lens according to the second compensation value Δ B2, adjusts the interval time of the next sending of the monitoring command to K4 × T2, and then repeats the step S400 a plurality of times; the K2 is a second adjusting parameter which can be manually set, the K3 is a third adjusting parameter which can be manually set, the K4 is a fourth adjusting parameter which can be manually set, the K4 is a positive number which is less than 1, and the K2 and the K3 are positive numbers which are more than 1.

Further, the second compensation value Δ B2 is calculated as follows:

in a further improvement, in the step S300, the specific step of adjusting the transmittance of the liquid crystal lens according to the first compensation value Δ B1 includes:

s310: the control module judges whether the first compensation value delta B1 is larger than a preset compensation value delta B; if yes, go to step S320, otherwise, go directly to step S330;

s320: the control module firstly controls the liquid crystal lens to perform first light transmittance adjustment according to a value obtained by multiplying the first compensation value delta B1 by K5, and after the first light transmittance adjustment is maintained for a second preset time T3, the step S330 is performed;

s330: the control module controls the liquid crystal lens to adjust the light transmittance according to the first compensation value delta B1;

the preset compensation value Δ B and the second preset time T3 can be manually set according to needs, K5 is a fifth adjusting parameter that can be manually set, and K5 is a positive number less than 1.

In a further improvement, after the step S400, the method further includes the following steps:

s500: when the automatic adjusting switch is turned off, the control module controls the liquid crystal lens to adjust the light transmittance by a third compensation value Δ B3 and maintains the adjusted light transmittance of the liquid crystal lens.

Further, the third compensation value Δ B3 is calculated as follows:

the invention also provides an intelligent visual interaction system for different light and shade environments, which adopts the control method of the intelligent visual interaction system, and comprises a picture frame, at least two liquid crystal lenses, a control module, a light sensor, a timing device and a displacement sensor, wherein the liquid crystal lenses are symmetrically arranged on the picture frame, the light sensor is arranged on the part of the picture frame between the two liquid crystal lenses, the displacement sensor is arranged below the light sensor, and the control module and the timing device are both arranged on the legs of the picture frame.

The improved intelligent visual interaction system applicable to different light and shade environments further comprises an automatic adjusting switch and a starting device, wherein the automatic adjusting switch and the starting device are both installed on the glasses legs of the glasses frame, and the automatic adjusting switch is electrically connected with the starting device.

The invention has the beneficial effects that: the invention discloses a control method of an intelligent visual interaction system, which comprises the following steps: s100: when the control module receives the first signal, the control module simultaneously sends a monitoring instruction to the light sensor, the timing device and the displacement sensor so as to start the light sensor, the timing device and the displacement sensor at the same time, and then the step S200 is carried out; s200: the method comprises the steps that a light sensor records the brightness L1 of the environment where a liquid crystal lens of an intelligent visual interaction system is located when a monitoring instruction is received, the displacement sensor monitors the displacement change value delta S of the intelligent visual interaction system, when the displacement change value delta S is larger than a first preset distance, a timing device records the time required from the receiving of the monitoring instruction to the time when the displacement change value delta S is larger than the first preset distance as time T1 and sends the time T1 to a control module, the light sensor records the brightness L2 of the environment where the liquid crystal lens is located when the displacement change value delta S is larger than the first preset distance, then the light sensor sends L1 and L2 to the control module at the same time, and then the step S300 is carried out; s300: the light sensor, the timing device and the displacement sensor enter a sleep mode, the control module calculates a first compensation value delta B1 of the liquid crystal lens according to the received information, and adjusts the light transmittance of the liquid crystal lens according to the first compensation value delta B1. The method can record the light change of the liquid crystal lens when a user travels a short path by wearing the intelligent visual interaction system, and then the control center can calculate the brightness of the next light according to the recorded light change and the moving speed of the user and control the liquid crystal lens to perform the pre-compensation of the light transmittance, thereby providing the eyesight protection function for the next movement of the user.

The invention is further described with reference to the following detailed description and accompanying drawings.

Drawings

FIG. 1 is a flow chart of a method of controlling an intelligent visual interaction system of the present invention;

FIG. 2 is a flow chart of a preferred embodiment of the intelligent visual interaction system control method of the present invention;

fig. 3 is a schematic structural diagram of an intelligent visual interaction system applicable to different light and dark environments according to the present invention.

In the figure: 100. the intelligent visual interaction system comprises an intelligent visual interaction system, 10 parts of a mirror frame, 20 parts of a liquid crystal lens, 30 parts of a control module, 40 parts of a light sensor, 50 parts of a timing device, 60 parts of a displacement sensor, 70 parts of an automatic adjusting switch and 80 parts of a starting device.

Detailed Description

The following description is only a preferred embodiment of the present invention, and does not limit the scope of the present invention.

Referring to fig. 1 to 3, the intelligent visual interaction system 100 applicable to different light and shade environments of the present invention includes a frame 10, liquid crystal lenses 20, a control module 30, at least two liquid crystal lenses 20, a timing device 50, and a displacement sensor 60, wherein the liquid crystal lenses 20 are symmetrically mounted on the frame 10, the light sensor 40 is mounted on a portion of the frame 10 between the two liquid crystal lenses 20, the displacement sensor 60 is located below the light sensor 40, and the control module 30 and the timing device 50 are both mounted on the temple of the frame 10. Preferably, the glasses frame further comprises an automatic adjusting switch 70 and an actuating device 80, wherein the automatic adjusting switch 70 and the actuating device 80 are both mounted on the temple of the glasses frame 10, and the automatic adjusting switch 70 is electrically connected with the actuating device 80. The control module 30 is configured to receive various information and calculate, and then control the liquid crystal lens 20 to correspondingly adjust different light transmittances, the light sensor 40 is configured to sense illumination brightness, the timing device 50 is configured to time, and the displacement sensor 60 is configured to sense a displacement. It should be noted that the level standard of the illumination brightness is already confirmed by the control module 30 at the time of writing, and the intelligent visual interaction system 100 applicable to different light and dark environments of the present invention adopts the following intelligent visual interaction system control method to achieve the adjustment of the light transmittance.

Referring to fig. 1 to fig. 3, the method for controlling an intelligent visual interaction system of the present invention includes the following steps: s100: when the control module 30 receives the first signal, the control module 30 sends a monitoring command to the light sensor 40, the timing device 50 and the displacement sensor 60 at the same time, so that the three are started at the same time, and then the process goes to step S200; s200: the light sensor 40 records a brightness level L1 of an environment where the liquid crystal lens 20 of the intelligent visual interaction system 100 is located when the monitoring instruction is received, the displacement sensor 60 monitors a displacement change value Δ S of the intelligent visual interaction system 100, when the displacement change value Δ S is greater than a first preset distance, the timing device 50 records a time required from the reception of the monitoring instruction until the displacement change value Δ S is greater than the first preset distance as a time T1 and sends the time T1 to the control module 30, the light sensor 40 records a brightness level L2 of the environment where the liquid crystal lens 20 is located when the displacement change value Δ S is greater than the first preset distance, then the light sensor 40 sends L1 and L2 to the control module 30 at the same time, and then the process proceeds to step S300; s300: the light sensor 40, the timing device 50 and the displacement sensor 60 enter the sleep mode, and the control module 30 calculates a first compensation value Δ B1 of the liquid crystal lens 20 according to the received information, and adjusts the light transmittance of the liquid crystal lens 20 according to the first compensation value Δ B1. Since the light sensor 40, the timing device 50 and the displacement sensor 60 are activated when the control module 30 receives the first signal, and automatically enter the sleep mode after the data is measured, the battery consumption can be effectively reduced, and the operation speed of the control module 30 can be increased. Specifically, the first compensation value Δ B1 is calculated as follows:

k1 is a first adjustment parameter that can be set in the control module 30, and the value of the first adjustment parameter K1 is positive.

With continued reference to fig. 1 to fig. 3, before step S100, the method further includes the following steps: s010: when the automatic adjustment switch 70 is turned on, the moving distance of the intelligent visual interaction system 100 is monitored in real time by the starting device 80, and when the moving distance is greater than a second preset distance, the starting device 80 sends a first signal to the control module 30. The step is set to reduce the energy loss of the intelligent visual interaction system 100 as much as possible, when the automatic adjustment switch 70 is turned off, the intelligent visual interaction system 100 only keeps the current transmittance for use without the automatic adjustment function, and the control module 30, the light sensor 40, the timing device 50 and the displacement sensor 60 are all in the sleep mode at this time; when the automatic adjustment switch 70 is turned on, the starting device 80 sends a first signal to the control module 30 when monitoring that the moving distance of the intelligent visual interaction system 100 is greater than a second preset distance, and the control module 30 sends a monitoring instruction to the light sensor 40, the timing device 50 and the displacement sensor 60 to start working at the same time.

With continued reference to fig. 1 to fig. 3, after the step S300, the method further includes the following steps: s400: the control module 30 sends a monitoring instruction to the light sensor 40 at an interval of a first preset time T2 after adjusting the light transmittance of the liquid crystal lens 20, and the light sensor 40 monitors the brightness L3 of the current environment of the liquid crystal lens 20 after receiving the monitoring instruction; when L3 is less than K2 Δ B1, the control module 30 automatically adjusts the interval time for the next monitor command to be K3 × T2; when L3 is greater than K2 × Δ B1, the control module 30 adjusts the transmittance of the liquid crystal lens 20 according to the second compensation value Δ B2, adjusts the interval time of the next sending of the monitoring command to K4 × T2, and then repeats the step S400 a plurality of times; the K2 is a second adjusting parameter which can be manually set, the K3 is a third adjusting parameter which can be manually set, the K4 is a fourth adjusting parameter which can be manually set, the K4 is a positive number which is less than 1, and the K2 and the K3 are positive numbers which are more than 1. The setting purpose of this step S400 is: after the liquid crystal lens 20 is controlled by the control module 30 to realize the transmittance adjustment for the first time, the light sensor 40, the timing device 50 and the displacement sensor 60 are all in the sleep mode, at this time, the control module 30 sends a monitoring command to the light sensor 40 at intervals to measure the brightness of the environment where the liquid crystal lens 20 is located at the current time, when L3 is smaller than K2 Δ B1, it is proved that the change value of the brightness of the environment at the current time is smaller, and at this time, the next monitoring time can be prolonged from T2 to K3T 2, so as to reduce the monitoring times in the same time period; when L3 is greater than K2 Δ B1, it is proved that the change value of the ambient brightness is large, and the transmittance of the liquid crystal lens 20 should be adjusted by the second compensation value Δ B2, and the next monitoring time is shortened from T2 to K4T 2, so as to increase the number of times of monitoring in the same period. Specifically, the second compensation value Δ B2 is calculated as follows:

referring to fig. 1 to fig. 3, in step S300, the specific step of adjusting the transmittance of the liquid crystal lens 20 according to the first compensation value Δ B1 includes: s310: the control module 30 determines whether the first compensation value Δ B1 is greater than a preset compensation value Δ B; if yes, go to step S320, otherwise, go directly to step S330; s320: the control module 30 first controls the liquid crystal lens 20 to perform a first transmittance adjustment according to a value obtained by multiplying the first compensation value Δ B1 by K5, and after the first transmittance adjustment is maintained for a second preset time T3, the process proceeds to step S330; s330: the control module 30 controls the liquid crystal lens 20 to adjust the light transmittance according to the first compensation value Δ B1; the preset compensation value Δ B and the second preset time T3 can be manually set according to needs, K5 is a fifth adjusting parameter that can be manually set, and K5 is a positive number less than 1. The setting purpose of the steps S310, S320 and S300 is: when the control module 30 pre-compensates the transmittance of the liquid crystal lens 20 by using the first compensation value Δ B1, if the value of Δ B1 is too large, it will cause the vision of the user to change from a very bright environment to a very dark environment or from a very dark environment to a very bright environment, and will cause discomfort to the user, so that when Δ B1 is greater than Δ B, the predetermined compensation value Δ B is used as a boundary criterion, the value of K5 × Δ B1 is used to perform a small-scale fine adjustment on the liquid crystal lens 20, and then the liquid crystal lens 20 is controlled to perform the transmittance adjustment by using the value of Δ B1, so that the human eye can gradually adapt to the light transmittance without discomfort in the process of slowly adjusting the scale.

With continuing reference to fig. 1 to fig. 3, after step S400, the method further includes the following steps:

s500: when the automatic adjustment switch 70 is turned off, the control module 30 first controls the liquid crystal lens 20 to adjust the light transmittance by the third compensation value Δ B3 and make the liquid crystal lens 20 maintain the adjusted light transmittance. The setting purpose of this step S500 is: when the automatic adjusting switch 70 is turned off, the liquid crystal lens 20 adjusts the eyeglass lens by using the whole process from the first adjustment to the last adjustment of the transmittance as a reference system and setting a third compensation value Δ B3 according to the reference system, so that the eyeglass lens can be suitable for the surrounding large environment after being adjusted by the third compensation value Δ B3, and therefore, when the automatic adjusting switch 70 is turned on next time, the final determination value of the first compensation value Δ B1 is smaller, that is, the adjustment range of the transmittance of the liquid crystal lens 20 is smaller. Specifically, the third compensation value Δ B3 is calculated as follows: (wherein Δ B2(1) represents the output value of the second compensation value Δ B2 at the first time, Δ B2(2) represents the output value of the second compensation value Δ B2 at the second time in step S400, and so on)

It should be noted that the order of one of the preferred embodiments of the intelligent visual interaction system control method of the present invention is: step S010, step S100, step S200, step S310, step S320, step S330, step S400, and step S500, but is not limited thereto.

The present invention is not limited to the above embodiments, and other intelligent visual interaction systems and control methods thereof for different light and dark environments, which are obtained by adopting the same or similar structures, devices, processes or methods as those of the above embodiments of the present invention, are within the protection scope of the present invention.

Claims (10)

1. An intelligent visual interaction system control method is characterized in that: the method comprises the following steps:

s100: when the control module receives the first signal, the control module simultaneously sends a monitoring instruction to the light sensor, the timing device and the displacement sensor so as to start the light sensor, the timing device and the displacement sensor at the same time, and then the step S200 is carried out;

s200: the light sensor records the brightness L1 of the environment where the liquid crystal lens of the intelligent visual interaction system is located when the monitoring instruction is received, the displacement sensor monitors the displacement change value delta S of the intelligent visual interaction system, when the displacement change value delta S is larger than a first preset distance, the timing device records the time from the receiving of the monitoring instruction to the time when the displacement change value delta S is larger than the first preset distance as time T1 and sends the time T1 to the control module, the light sensor records the brightness L2 of the environment where the liquid crystal lens is located when the displacement change value delta S is larger than the first preset distance, then the light sensor simultaneously sends L1 and L2 to the control module, and then the process goes to the step S300;

s300: the light sensor, the timing device and the displacement sensor enter a sleep mode, the control module calculates a first compensation value delta B1 of the liquid crystal lens according to the received information, and adjusts the light transmittance of the liquid crystal lens according to the first compensation value delta B1.

2. The intelligent visual interaction system control method of claim 1, wherein: the first compensation value Δ B1 is calculated as follows:

k1 is a first adjustment parameter that can be set by the control module, and the value of the first adjustment parameter K1 is positive.

3. The intelligent visual interaction system control method of claim 1, wherein: before the step S100, the following steps are further included:

s010: when the automatic adjusting switch is turned on, the moving distance of the intelligent visual interaction system is monitored in real time through the starting device, and when the moving distance is larger than a second preset distance, the starting device sends the first signal to the control module.

4. The intelligent visual interaction system control method of claim 2, wherein: after the step S300, the method further includes the following steps:

s400: the control module sends a monitoring instruction to the light sensor at an interval of a first preset time T2 after the light transmittance of the liquid crystal lens is adjusted, and the light sensor monitors the brightness L3 of the current environment where the liquid crystal lens is located after receiving the monitoring instruction; when L3 is less than K2 Δ B1, the control module automatically adjusts the interval time for the next monitoring command to be transmitted to K3 × T2; when L3 is greater than K2 × Δ B1, the control module adjusts the transmittance of the liquid crystal lens according to the second compensation value Δ B1, adjusts the interval time of the next sending of the monitoring command to K4 × T2, and then repeats the step S400 a plurality of times; the K2 is a second adjusting parameter which can be manually set, the K3 is a third adjusting parameter which can be manually set, the K4 is a fourth adjusting parameter which can be manually set, the K4 is a positive number which is less than 1, and the K2 and the K3 are positive numbers which are more than 1.

5. The intelligent visual interaction system control method of claim 4, wherein: the second compensation value Δ B1 is calculated as follows:

6. the intelligent visual interaction system control method of claim 1, wherein: in the step S300, the specific step of adjusting the transmittance of the liquid crystal lens according to the first compensation value includes:

s310: the control module judges whether the first compensation value delta B1 is larger than a preset compensation value delta B; if yes, go to step S320, otherwise, go directly to step S330;

s320: the control module firstly controls the liquid crystal lens to perform first light transmittance adjustment according to a value obtained by multiplying the first compensation value delta B1 by K5, and after the first light transmittance adjustment is maintained for a second preset time T3, the step S330 is performed;

s330: the control module controls the liquid crystal lens to adjust the light transmittance according to the first compensation value delta B1;

the preset compensation value Δ B and the second preset time T3 can be manually set according to needs, K5 is a fifth adjusting parameter that can be manually set, and K5 is a positive number less than 1.

7. The intelligent visual interaction system control method of claim 5, wherein: after the step S400, the following steps are further included:

s500: when the automatic adjusting switch is turned off, the control module controls the liquid crystal lens to adjust the light transmittance by a third compensation value Δ B3 and maintains the adjusted light transmittance of the liquid crystal lens.

8. The intelligent visual interaction system control method of claim 7, wherein: the third compensation value Δ B3 is calculated as follows:

9. an intelligent visual interaction system for different light and shade environments, characterized in that: the intelligent visual interaction system adopts the control method of the intelligent visual interaction system according to any one of claims 1 to 8, and comprises a frame, at least two liquid crystal lenses, a control module, a light sensor, a timing device and a displacement sensor, wherein the liquid crystal lenses are symmetrically arranged on the frame, the light sensor is arranged on a position of the frame between the two liquid crystal lenses, the displacement sensor is arranged below the light sensor, and the control module and the timing device are both arranged on the legs of the frame.

10. The intelligent visual interaction system applicable to different light and dark environments of claim 9, wherein: still include automatic regulating switch and starting drive, automatic regulating switch with starting drive all install in on the mirror leg of picture frame, just automatic regulating switch with the starting drive electricity is connected.

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