CN115639697A - Relative illumination parameter-based light transmission assembly adjusting system - Google Patents

Abstract

The light transmission component adjusting system based on the relative illumination parameters comprises a controller, a collecting element and a light transmission component which are arranged in a matched mode, wherein the controller is used for setting a relative illumination parameter defining range A and transmitting a control instruction to the light transmission component to enable the light transmission component to carry out color and/or transmittance adjustment, and the adjusting method of the adjusting system comprises the following steps: s1, acquiring the action of an element, acquiring real-time illumination parameters fed back by external feedback and/or real-time illumination parameters fed back by irradiating the light-transmitting component, and transmitting the real-time illumination parameters to a controller in real time; and S2, the controller acts to receive the real-time illumination parameters transmitted by the acquisition element, and transmits a control instruction to the light transmission assembly according to a relative illumination parameter definition range A preset in the controller and the relative position relation between the acquisition element and the light transmission assembly so as to adjust the color and/or the transmittance of one or more specific areas of the light transmission assembly.

Description

Relative illumination parameter-based light transmission assembly adjusting system

The technical field is as follows:

the invention relates to a light transmission component adjusting system based on relative illumination parameters.

Background art:

optics is an important branch of physics and is also a subject related to optical engineering; in a narrow sense, optics is the science of light and sight, while optics, as it is often said today, is in a broad sense, studying the generation, transmission, reception and display of electromagnetic radiation in a broad band ranging from microwaves, infrared, visible light, ultraviolet, up to X-rays and gamma rays, and the science of interaction with matter, with emphasis on ranging from the infrared to the ultraviolet band.

In the process of optical theory practical application, the illumination parameters are important evaluation data on the light-transmitting component and mainly comprise illumination intensity, brightness and the like, the shape or color of the light-transmitting component is adjusted according to the acquired data parameters, so that the color or transmittance of the light-transmitting component is automatically adjusted to adapt to the ambient illumination conditions, the normal use of the light-transmitting component is prevented from being influenced due to overhigh or overlow illumination intensity, and the practical application of a user is met; by taking the front windshield color-changing glass of the automobile as an example, when the illumination intensity of the external driving environment is too high, the color of the front windshield color-changing glass is adjusted to reduce the incidence of strong light, so that the influence of the strong light of the external environment on a driver is reduced, the driver is protected, and the normal and safe driving of the driver is ensured.

In the adjusting process of the existing light-transmitting component, a specific illumination parameter defining range is generally preset, when the monitored illumination parameter exceeds the illumination parameter defining range, the light-transmitting component quickly responds, and the color and/or transmittance of the light-transmitting component are/is automatically adjusted to meet the actual requirements of users; although the adjusting and calculating method for limiting the numerical range can be applied under certain conditions, the adjusting and calculating method is greatly influenced by external environment adjustment, is poor in adjusting and calculating flexibility, cannot provide the most appropriate shading effect for a user according to difference change of the environment, and therefore image information acquired by the user is not comprehensive and accurate enough, subsequent operation of the user is influenced, and meanwhile, the existing system does not refer to the position of the user in the adjusting process, so that the actual application requirement of the user cannot be met.

The invention content is as follows:

the embodiment of the invention provides a light-transmitting component adjusting system based on relative illumination parameters, the method is reasonable in design, the relative illumination parameter defining range can be dynamically set, the color and/or the transmittance of the light-transmitting component can be accurately adjusted according to the difference and the change of the ambient external environment conditions, the operation is flexible, the light-transmitting component adjusting system can be suitable for most application scenes, the response speed is high, as long as the external environment conditions change, the controller can be triggered to accurately adjust the light-transmitting component at the first time, the comprehensive, accurate and reliable image information obtained by a user is ensured, the user can execute correct subsequent operation, meanwhile, protection and convenience can be provided for the user, the light-transmitting component adjusting system is convenient to popularize and solve the problems in the prior art.

The technical scheme adopted by the invention for solving the technical problems is as follows:

the adjusting system comprises a controller, a collecting element and a light-transmitting component which are arranged in a matched mode, wherein the controller is used for setting a relative illumination parameter defining range A and transmitting a control instruction to the light-transmitting component to enable the light-transmitting component to carry out color and/or transmittance adjustment, and the collecting element is used for collecting real-time illumination parameters fed out by external feedback and/or real-time illumination parameters fed back by irradiating the light-transmitting component and transmitting the real-time illumination parameters to the controller in real time;

the adjusting method of the adjusting system comprises the following steps:

s1, acquiring element action, acquiring real-time illumination parameters fed back from the outside and/or real-time illumination parameters fed back by irradiating the light-transmitting component, and transmitting the real-time illumination parameters to a controller in real time;

and S2, the controller acts to receive the real-time illumination parameters transmitted by the acquisition element, and transmits a control instruction to the light-transmitting component according to a relative illumination parameter definition range A and the relative position relation between the acquisition element and the light-transmitting component, which are preset in the controller in advance, so as to adjust the color and/or the transmittance of one or more specific areas of the light-transmitting component.

The action of the collecting element, collecting the real-time illumination parameters fed back from the outside and/or the real-time illumination parameters fed back by irradiating the light-transmitting component and transmitting the real-time illumination parameters to the controller in real time comprises the following steps:

s1.1, a controller divides a plurality of color and/or transmittance adjusting areas at different positions on a light transmitting component, divides a plurality of collecting areas on a collecting element, and divides the collecting areas and the color and/or transmittance adjusting areas into independent parts;

s1.2, collecting external environment change parameters and/or real-time illumination parameters fed back by irradiating the light-transmitting component by a collecting element in real time, and summarizing to form a real-time parameter set Q;

s1.3, transmitting the acquired real-time parameter set Q to a light-transmitting component and/or a controller in real time.

And the controller sets a relative illumination parameter defining range A according to the real-time illumination parameters fed back from the outside and/or the real-time illumination parameters fed back from the light-transmitting component irradiated on the light-transmitting component and/or a real-time parameter set Q.

The controller transmits a control instruction to the light-transmitting component according to the relative illumination parameter defining range A, the relative position relation between the acquisition element and the light-transmitting component and the relative dynamic position relation between the user, the light-transmitting component and the light source so as to adjust the color and/or the transmittance of one or more specific areas of the light-transmitting component, and the relative dynamic position relation between the user and the light-transmitting component can be determined by presetting and/or acquiring the position of the user in real time.

The controller transmits a control instruction to the light-transmitting component according to the relative illumination parameter defining range A, the relative position relation between the acquisition element and the light-transmitting component and the relative dynamic position relation between a user, the acquisition element and the light-transmitting component, so as to adjust the color and/or the transmittance of one or more specific areas of the light-transmitting component.

The controller dividing a plurality of color and/or transmittance adjustment regions at different positions on the light transmission component comprises the following steps:

s1.1.1, measuring a light transmission area S of a light transmission component by a controller;

s1.1.2, setting an effective monitoring area W of a color and/or transmittance adjusting area, and enabling the light-transmitting components to be N color and/or transmittance adjusting areas according to the light-transmitting area S and the effective monitoring area W, wherein N = int ((S + W)/W);

s1.1.3, defining each color and/or transmittance adjusting region of the light transmission component as R in sequence ₁ ——R _n ；

The acquisition element at least comprises a camera, a temperature sensor, a pressure sensor and a wind speed measuring instrument, and the external environment change parameters at least comprise illumination intensity, a temperature parameter, a pressure parameter and a wind speed parameter; the light transmission component comprises automobile front windshield color-changing glass, office building color-changing glass, a camera color-changing lens and a telescope color-changing lens.

The method for collecting the external environment change parameters in real time in each color and/or transmittance adjusting area and summarizing the parameters to form a real-time parameter set Q comprises the following steps:

s1.2.1, setting a plurality of time nodes T corresponding to the acquired external environment change parameters by a controller;

s1.2.2, at each time node T, the controller transmits trigger pulses to the acquisition elements, so that the acquisition elements enter a working state to acquire external environment change parameters in real time;

and S1.2.3, summarizing all external environment change parameters acquired in real time, and storing the parameters according to the sequence numbers of color and/or transmittance adjusting areas to form a real-time parameter set Q.

The maximum data storage capacity of the real-time parameter set Q is 50, and when the maximum data storage capacity is exceeded, the data at the front end is automatically deleted so as to ensure the real-time performance of the real-time parameter set Q.

The controller updates the illumination parameter definition range A in real time, corrects the illumination parameter definition range A in combination with a real-time parameter set Q of the next time node change, repeats the step, and selects an abnormal color and/or transmittance adjusting area on the light transmission assembly for self-adjustment, so that the color or transmittance adjusting effect of the light transmission assembly meets the actual requirements of users.

The real-time transmission of the collected real-time parameter set Q to the controller comprises the following steps:

s1.3.1, the controller stores the external environment change parameters in the real-time parameter set Q in a classified manner, and removes data with large errors in the real-time parameter set Q;

s1.3.2, calculating the mean value of each external environment change parameter in a classified manner, and comparing the mean value with the standard set in the database, so that the accuracy of the real-time parameter set Q in the controller is further improved.

By adopting the structure, the light-transmitting component is divided into a plurality of acquisition monitoring areas at different positions, so that the acquisition of external environment change parameters is accurate and reliable; a plurality of external environment change parameters are acquired in real time through the acquisition elements on each monitoring area and are summarized to form a real-time parameter set Q, so that data omission can be prevented, and large errors of the data can be avoided; through the combination of the controller, the material of the light-transmitting component, the external illumination condition of the light-transmitting component and the real-time parameter set Q, the relative illumination parameter definition range corresponding to the light-transmitting component can be dynamically set, and guidance is provided for the automatic adjustment of the form of the light-transmitting component; through controller to printing opacity subassembly transmission control instruction, the colour and/or the transmittance of automatic trigger regulation printing opacity subassembly are in order to satisfy user's practical application, have convenient practicality, accurate efficient advantage.

Description of the drawings:

FIG. 1 is a schematic structural diagram of the present invention.

Fig. 2 is a schematic structural diagram of the light-transmitting assembly of the present invention.

FIG. 3 is a schematic flow chart of the conditioning method of the present invention.

The specific implementation mode is as follows:

in order to clearly explain the technical features of the present invention, the present invention will be explained in detail by the following embodiments and the accompanying drawings.

As shown in fig. 1 to 3, the light transmission component adjustment system based on relative illumination parameters comprises a controller, a collecting element and a light transmission component, which are cooperatively arranged, wherein the controller is used for setting a relative illumination parameter defining range a and transmitting a control instruction to the light transmission component to adjust the color and/or transmittance of the light transmission component, and the collecting element is used for collecting real-time illumination parameters fed back from the outside and/or real-time illumination parameters fed back by irradiating the light transmission component and transmitting the real-time illumination parameters to the controller in real time;

the adjusting method of the adjusting system comprises the following steps:

s1, acquiring element action, acquiring real-time illumination parameters fed back from the outside and/or real-time illumination parameters fed back by irradiating the light-transmitting component, and transmitting the real-time illumination parameters to a controller in real time;

and S2, the controller acts to receive the real-time illumination parameters transmitted by the acquisition element, and transmits a control instruction to the light transmission assembly according to a relative illumination parameter definition range A preset in the controller and the relative position relation between the acquisition element and the light transmission assembly so as to adjust the color and/or the transmittance of one or more specific areas of the light transmission assembly.

The action of the collecting element, collecting the real-time illumination parameters fed back from the outside and/or the real-time illumination parameters fed back by irradiating the light-transmitting component and transmitting the real-time illumination parameters to the controller in real time comprises the following steps:

s1.1, a controller divides a plurality of color and/or transmittance adjusting areas at different positions on a light transmission component, divides a plurality of collecting areas on a collecting element, and divides the collecting areas and the color and/or transmittance adjusting areas into independent parts;

s1.2, collecting external environment change parameters and/or real-time illumination parameters fed back by irradiating the light-transmitting component by a collecting element in real time, and summarizing to form a real-time parameter set Q;

s1.3, transmitting the acquired real-time parameter set Q to a light-transmitting component and/or a controller in real time.

The controller sets a relative illumination parameter defining range A according to the real-time illumination parameters fed back from the outside and/or the real-time illumination parameters fed back from the light-transmitting component irradiated by the light and/or the real-time parameter set Q.

The controller transmits a control instruction to the light-transmitting component according to the relative illumination parameter defining range A, the relative position relation between the acquisition element and the light-transmitting component and the relative dynamic position relation between the user, the light-transmitting component and the light source so as to adjust the color and/or the transmittance of one or more specific areas of the light-transmitting component, and the relative dynamic position relation between the user and the light-transmitting component can be determined by presetting and/or acquiring the position of the user in real time.

The controller transmits a control instruction to the light-transmitting component according to the relative illumination parameter defining range A, the relative position relation between the acquisition element and the light-transmitting component and the relative dynamic position relation between a user, the acquisition element and the light-transmitting component, so as to adjust the color and/or the transmittance of one or more specific areas of the light-transmitting component.

The controller dividing a plurality of color and/or transmittance adjustment regions at different positions on the light transmission component comprises the following steps:

s1.1.1, measuring a light transmission area S of a light transmission component by a controller;

s1.1.2, setting an effective monitoring area W of a color and/or transmittance adjusting area, and enabling the light-transmitting components to be N color and/or transmittance adjusting areas according to the light-transmitting area S and the effective monitoring area W, wherein N = int ((S + W)/W);

s1.1.3, defining each color and/or transmittance adjusting region of the light-transmitting component as R in sequence ₁ ——R _n ；

The acquisition element at least comprises a camera, a temperature sensor, a pressure sensor and a wind speed measuring instrument, and the external environment change parameters at least comprise illumination intensity, temperature parameters, pressure parameters and wind speed parameters; the light-transmitting component comprises automobile front windshield color-changing glass, office building color-changing glass, a camera color-changing lens and a telescope color-changing lens.

The method for collecting external environment change parameters in real time in each color and/or transmittance adjusting area and summarizing the external environment change parameters to form a real-time parameter set Q comprises the following steps:

s1.2.1, setting a plurality of time nodes T corresponding to the collected external environment change parameters by a controller;

s1.2.2, at each time node T, a controller transmits trigger pulses to an acquisition element, so that the acquisition element enters a working state to acquire external environment change parameters in real time;

and S1.2.3, summarizing all external environment change parameters acquired in real time, and storing the parameters according to the sequence numbers of color and/or transmittance adjusting areas to form a real-time parameter set Q.

The maximum data storage capacity of the real-time parameter set Q is 50, and when the maximum data storage capacity is exceeded, the data at the front end is automatically deleted so as to ensure the real-time performance of the real-time parameter set Q.

The controller updates the illumination parameter definition range A in real time, corrects the illumination parameter definition range A in combination with a real-time parameter set Q of the next time node change, repeats the step, and selects a color and/or transmittance adjusting area with abnormal color and/or transmittance on the light transmission assembly for self adjustment, so that the color or transmittance adjusting effect of the light transmission assembly meets the actual requirements of users.

The real-time transmission of the collected real-time parameter set Q to the controller comprises the following steps:

s1.3.1, the controller stores the external environment change parameters in the real-time parameter set Q in a classified mode, and data with large errors in the real-time parameter set Q are removed;

s1.3.2, calculating the mean value of each external environment change parameter in a classified mode, comparing the mean value with the standard set in the database, and further improving the accuracy of the real-time parameter set Q in the controller.

The working principle of the light-transmitting component adjusting system based on relative illumination parameters in the embodiment of the invention is as follows: the device can dynamically set a relative illumination parameter defining range, accurately adjust the color and/or transmittance of the light-transmitting component according to the difference and change of the ambient external environment conditions, is flexible to operate, can be applied to most application scenes, has high response speed, can trigger the controller to accurately adjust the light-transmitting component at the first time as long as the external environment conditions change, ensures that image information acquired by a user is comprehensive, accurate and reliable, enables the user to execute correct subsequent operation, can provide protection and convenience for the user, and is convenient to popularize; by taking vehicle driving as an example, when the external environment is in the strong light state, the method and the device can determine which acquisition monitoring area on the light-transmitting component needs to be subjected to color and/or transmittance adjustment, so that the influence of the strong light on a user is reduced; by setting the relative illumination parameter defining range A and combining a dynamic parameter change set of dynamic changes of a plurality of time nodes, the form self-adjustment of the designated position on the light-transmitting component can be accurately and quickly realized.

In the whole scheme, the adjusting system comprises a controller, an acquisition element and a light transmission component which are arranged in a matched mode, wherein the controller is used for setting a relative illumination parameter defining range A and transmitting a control instruction to the light transmission component to enable the light transmission component to carry out color and/or transmittance adjustment, and the acquisition element is used for acquiring real-time illumination parameters fed out by external feedback and/or real-time illumination parameters fed back by irradiating the light transmission component and transmitting the real-time illumination parameters to the controller in real time; under the mutual cooperation of the controller and the acquisition element, the color and/or transmittance of a specific area or specific areas on the light transmission component are dynamically adjusted, so that the influence of strong light on a user is avoided, and the normal operation of the light transmission component is ensured.

Preferably, the step of dividing the collection monitoring area of the plurality of different positions on the light transmission component by the controller comprises the following steps: the controller measures the light transmission area S of the light transmission component; setting an effective monitoring area W of the acquisition monitoring area, and enabling the light-transmitting components to be N acquisition monitoring areas according to the light-transmitting area S and the effective monitoring area W, wherein N = int ((S + W)/W); defining each collecting and monitoring area of the light transmission component as R in sequence ₁ ——R _n (ii) a The number of the acquisition monitoring areas is calculated by the light transmission area S and the effective monitoring area W of the light transmission component, and the acquisition monitoring areas with corresponding number are obtained in a further mode, so that omission and blank areas on the light transmission component are avoided; according to the sequence definition, the controller can quickly and accurately position the area needing to be adjusted.

Preferably, the collecting elements at least comprise a camera, a temperature sensor, a pressure sensor and a wind speed measuring instrument, the external environment change parameters at least comprise an illumination intensity, a temperature parameter, a pressure parameter and a wind speed parameter, and the number types of the collecting elements can be increased or decreased according to actual application scenes so as to meet application requirements of users.

For the dynamic parameter change set, external environment change parameters are collected in real time from each defined collection monitoring area and are collected in a unified mode, and omission or data errors are avoided.

Specifically, a plurality of time nodes corresponding to the acquisition of external environment change parameters are set by a controller, the setting of the time nodes can be adjusted according to the actual application requirements, and the controller transmits trigger pulses to the acquisition elements at each time node to enable the acquisition elements to enter a working state to acquire the external environment change parameters in real time, so that a dynamic parameter change set can be formed at each time node; meanwhile, the data can be stored according to the sequence number of the collected monitoring area, and convenience can be provided for a user to inquire and call the data.

Particularly, the maximum data storage amount of the dynamic parameter change set is 50, and when the maximum data storage amount is exceeded, the data at the front end is automatically deleted, so that the real-time dynamic property of the dynamic parameter change set is ensured; the maximum data storage capacity can be adjusted according to actual application, and the data storage condition is met.

The method comprises the following steps of transmitting a collected real-time parameter set Q to a controller in real time, and dynamically setting a relative illumination parameter definition range A corresponding to the light-transmitting component by combining a database in the controller, wherein the relative illumination parameter definition range A comprises the following steps: the controller stores the external environment change parameters in the real-time parameter set Q in a classified manner, and removes data with large errors in the real-time parameter set Q; calculating the mean value of each external environment change parameter in a classified manner, and comparing the mean value with the standard set in the database; and according to the comparison result, the controller dynamically sets the relative illumination parameter definition range A corresponding to the light-transmitting component.

For the external environment change parameters, the controller adopts classified storage, removes and corrects data with larger errors, and then integrates the mean values calculated by classification and the standards set by the database, so as to ensure the accuracy of the relative illumination parameter definition range.

The key improvement of the application lies in the self-adjusting step of the light-transmitting component, namely, the light irradiation parameter defining range A is updated in real time and then transmitted and fed back to the sensing element on each acquisition monitoring area; the sensing element senses the change of the external illumination parameters and judges whether the light-transmitting component needs to be adjusted or not according to the sum/or relation between the relative illumination parameter defining range A and the real-time illumination parameters; and then correcting by combining with a real-time parameter set Q of the change of the next time node, repeating the step, and selecting an abnormal acquisition monitoring area on the light-transmitting component for self-adjustment, so that the color or transmittance adjusting effect of the light-transmitting component meets the actual requirement of a user.

And repeating the steps for many times to correct so as to ensure the dynamic real-time self-adjustment calculation of the light-transmitting component, and then combining the dynamic parameter change set to update the characteristic in real time, thereby ensuring that the self-adjustment of the light-transmitting component can be completely suitable for the user requirements.

In order to ensure that the adjustment effect meets the actual requirements of a user, the controller needs to refer to the relative position relation between the user and the light source for each correction, which is a main innovation point of the light transmission assembly compared with the prior art, and the color and/or transmittance can be further adjusted in an area with higher precision on the light transmission assembly; and when the relative position of the user and the light source changes, the controller can respond in time to adjust a new area on the light-transmitting component.

The light-transmitting component mainly comprises automobile front windshield color-changing glass, helmet color-changing lenses, color-changing glasses lenses, house color-changing glass, camera color-changing lenses and telescope color-changing lenses; the method has the advantages that the universality and the expandability are realized, the self-regulation calculation of the light-transmitting assembly can be realized according to the change of the external illumination parameters, the comprehensive, accurate and reliable image information acquired by a user is ensured, the user can execute correct subsequent operation, and meanwhile, the protection and the convenience can be provided for the user.

Furthermore, the number of the acquisition elements can be flexibly set according to different practical application scenes, and can be in various forms such as one-to-one, one-to-many, many-to-one or many-to-many, so long as the normal, safe and stable use of a user is ensured; taking a front windshield of a vehicle as an example, in the driving process of a driver, a certain range of acquisition and monitoring areas exist on the front windshield for key monitoring, and at the moment, a plurality of acquisition elements are usually uniformly distributed in one acquisition and monitoring area for monitoring; for other typical application scenarios, the setting can also be adjusted according to actual requirements.

In summary, the light transmission component adjustment system based on relative illumination parameters in the embodiment of the present invention can dynamically set the relative illumination parameter definition range, and accurately adjust the color and/or transmittance of the light transmission component according to the difference and change of the ambient external environmental conditions, is flexible in operation, can be applied to most application scenarios, has a fast response speed, can trigger the controller to accurately adjust the light transmission component in the first time as long as the external environmental conditions change, ensures that the image information obtained by the user is comprehensive, accurate and reliable, enables the user to perform correct subsequent operations, and simultaneously can provide protection and convenience for the user, thereby facilitating popularization and promotion.

The above-described embodiments should not be construed as limiting the scope of the present invention, and any alternative modifications or alterations to the embodiments of the present invention will be apparent to those skilled in the art.

The present invention is not described in detail, but is known to those skilled in the art.

Claims (10)

1. Printing opacity subassembly governing system based on relative illumination parameter, its characterized in that: the adjusting system comprises a controller, an acquisition element and a light transmission assembly which are arranged in a matched mode, wherein the controller is used for setting a relative illumination parameter defining range A and transmitting a control instruction to the light transmission assembly to enable the light transmission assembly to carry out color and/or transmittance adjustment, and the acquisition element is used for acquiring real-time illumination parameters fed out by external feedback and/or real-time illumination parameters fed back by irradiating the light transmission assembly and transmitting the real-time illumination parameters to the controller in real time;

the adjusting method of the adjusting system comprises the following steps:

s1, acquiring the action of an element, acquiring real-time illumination parameters fed back by external feedback and/or real-time illumination parameters fed back by irradiating the light-transmitting component, and transmitting the real-time illumination parameters to a controller in real time;

and S2, the controller acts to receive the real-time illumination parameters transmitted by the acquisition element, and transmits a control instruction to the light transmission assembly according to a relative illumination parameter definition range A preset in the controller and the relative position relation between the acquisition element and the light transmission assembly so as to adjust the color and/or the transmittance of one or more specific areas of the light transmission assembly.

2. A system for adjusting a light transmitting module according to claim 1, wherein the operation of the collecting element to collect the real-time illumination parameters fed back from the outside and/or the real-time illumination parameters fed back from the light transmitting module and transmitted to the controller in real time comprises the following steps:

s1.1, a controller divides a plurality of color and/or transmittance adjusting areas at different positions on a light transmitting component, divides a plurality of collecting areas on a collecting element, and divides the collecting areas and the color and/or transmittance adjusting areas into independent parts;

s1.2, collecting external environment change parameters and/or real-time illumination parameters fed back by irradiating the light-transmitting component by a collecting element in real time, and summarizing to form a real-time parameter set Q;

and S1.3, transmitting the acquired real-time parameter set Q to a light-transmitting component and/or a controller in real time.

3. A light transmission component adjustment system according to claim 2, characterized in that: and the controller sets a relative illumination parameter defining range A according to the real-time illumination parameters fed back from the outside and/or the real-time illumination parameters fed back from the light-transmitting component irradiated on the light-transmitting component and/or a real-time parameter set Q.

4. A light transmission component adjustment system according to claim 3, characterized in that: the controller transmits a control instruction to the light-transmitting component according to the relative illumination parameter defining range A, the relative position relation between the acquisition element and the light-transmitting component and the relative dynamic position relation between the user, the light-transmitting component and the light source so as to adjust the color and/or the transmittance of one or more specific areas of the light-transmitting component, and the relative dynamic position relation between the user and the light-transmitting component can be determined by presetting and/or acquiring the position of the user in real time.

5. A light transmission component adjustment system according to claim 3, characterized in that: the controller transmits a control instruction to the light-transmitting component according to the relative illumination parameter definition range A, the relative position relation between the acquisition element and the light-transmitting component and the relative dynamic position relation between a user, the acquisition element and the light-transmitting component so as to adjust the color and/or the transmittance of one or more specific areas of the light-transmitting component.

6. A light transmission component adjustment system according to claim 2, wherein the controller divides the plurality of differently positioned color and/or transmittance adjustment areas on the light transmission component comprising the steps of:

s1.1.1, measuring the light transmission area S of the light transmission component by a controller;

s1.1.2, setting an effective monitoring area W of a color and/or transmittance adjusting area, and enabling the light-transmitting components to be N color and/or transmittance adjusting areas according to the light-transmitting area S and the effective monitoring area W, wherein N = int ((S + W)/W);

s1.1.3, defining each color and/or transmittance adjusting region of the light-transmitting component as R in sequence ₁ ——R _n ；

The acquisition element at least comprises a camera, a temperature sensor, a pressure sensor and a wind speed measuring instrument, and the external environment change parameters at least comprise illumination intensity, temperature parameters, pressure parameters and wind speed parameters; the light transmission component comprises automobile front windshield color-changing glass, office building color-changing glass, a camera color-changing lens and a telescope color-changing lens.

7. A relative illumination parameter based light transmission component adjustment system according to claim 2, wherein the step of collecting in real time the external environment variation parameters in each color and/or transmittance adjustment region and summarizing to form a real-time parameter set Q comprises the steps of:

s1.2.1, setting a plurality of time nodes T corresponding to the collected external environment change parameters by a controller;

s1.2.2, at each time node T, a controller transmits trigger pulses to an acquisition element, so that the acquisition element enters a working state to acquire external environment change parameters in real time;

and S1.2.3, summarizing all external environment change parameters acquired in real time, and storing the parameters according to the sequence numbers of color and/or transmittance adjusting areas to form a real-time parameter set Q.

8. A light transmission component adjustment system according to claim 2, characterized in that: the maximum data storage capacity of the real-time parameter set Q is 50, and when the maximum data storage capacity is exceeded, the most front data is automatically deleted to ensure the real-time performance of the real-time parameter set Q.

9. A light transmission component adjustment system based on relative illumination parameters according to claim 2, characterized in that: the controller updates the illumination parameter definition range A in real time, corrects the illumination parameter definition range A in combination with a real-time parameter set Q of the next time node change, repeats the step, and selects an abnormal color and/or transmittance adjusting area on the light transmission assembly for self-adjustment, so that the color or transmittance adjusting effect of the light transmission assembly meets the actual requirements of users.

10. A relative illumination parameter based light transmission assembly adjustment system according to claim 2, wherein transmitting the collected real-time parameter set Q to the controller in real-time comprises the steps of:

s1.3.1, the controller stores the external environment change parameters in the real-time parameter set Q in a classified manner, and removes data with large errors in the real-time parameter set Q;

s1.3.2, calculating the mean value of each external environment change parameter in a classified mode, comparing the mean value with the standard set in the database, and further improving the accuracy of the real-time parameter set Q in the controller.

Images