CN108273197B

CN108273197B - method and device for configuring and adjusting light-emitting parameters of biological rhythm illumination device

Info

Publication number: CN108273197B
Application number: CN201810135405.4A
Authority: CN
Inventors: 马君显; 马捷; 赵滢滢
Original assignee: Shenzhen Huizhi Life Science & Technology Co Ltd
Current assignee: Shenzhen Huizhi Life Science & Technology Co Ltd
Priority date: 2018-02-09
Filing date: 2018-02-09
Publication date: 2019-12-17
Anticipated expiration: 2038-02-09
Also published as: WO2019153968A1; CN108273197A

Abstract

The invention relates to a method for configuring and adjusting luminous parameters of a biological rhythm illumination device, which comprises the following steps: the login server acquires the identity information and the configuration state of the illumination device and forwards the identity information and the configuration state to the server; verifying the identity information of the logged-in user and the identity information of the illumination device, and calling out the illumination record and the latest detection data of the user after the identity information of the logged-in user and the identity information of the illumination device are matched; selecting a parameter set that is closest; and after the selected parameter set is subjected to individual adjustment and confirmation, the obtained optical parameter set is sent to the mobile terminal and configured to the illumination device, and the illumination device drives the light-emitting unit to emit light by using the parameter set. The invention also relates to a device for realizing the method. The method and the device for configuring and adjusting the luminous parameters of the biorhythm illumination device have the following beneficial effects: can adjust illumination parameters according to human factors, has good adaptability and effect, and can reduce visual impairment.

Description

Method and device for configuring and adjusting light-emitting parameters of biological rhythm illumination device

Technical Field

The invention relates to the field of medical equipment, in particular to a method and a device for configuring and adjusting light-emitting parameters of a biological rhythm illumination device.

Background

the disorder of the biological rhythm of the human body is highly related to a plurality of diseases, such as AD (senile dementia), Parkinson's disease, depression, insomnia and the like, and the diseases not only bring pain to the patient and family members, but also cause serious burden to the society. Due to the complex causes and various symptoms caused by the imbalance of the biological rhythm of the human body, despite the continuous efforts of medical scientific research institutions and pharmaceutical factories worldwide, the treatment of the imbalance of the biological rhythm and most symptoms caused by the imbalance of the biological rhythm by medicines is still in an embarrassing situation so far. Optogenetic (Opto-genetics) research, which has begun to rise in recent years, has found that the emission of certain characteristic light signals to optical fibers implanted in the brain tissue of mice, and even to the eyes of mice, can significantly modify certain biological rhythms that have become deregulated in their body, thus leading to the appearance of cure of certain diseases associated with these rhythms. For example, the american academy of labor science Li-Huei Tsa, which is a paper published in Nature by 2016, reports that LED illumination with certain characteristics is respectively emitted to an optical fiber implanted into the brain of an AD mouse and the eyes of the AD mouse, and after 1 hour per day and one month, the originally disordered electroencephalogram gamma wave recurrent periodic rhythm of the AD mouse is measured and found, and some industry-recognized marked indexes of AD, such as a beta protein, Tau protein and the like related to AD in the brain tissue of the mouse, are found to be restored to normal levels by disfiguration. In the prior art, the adopted technical forms are different, but the principles are approximately the same, namely, the device which adopts the technology can effectively inhibit the fading and stimulating pigment secretion of human body by stimulating the retina of human eyes with light so as to play a role in adjusting the biological clock of the human body, so that in principle, all devices adopting the technology can be effective to some extent. However, with the increasing demand of use, especially with the development of recent research in optogenetics and the like, it is not difficult to find that the following significant disadvantages exist while the technology is successful: because the light-emitting parameters in the prior art are all in a plurality of preset modes, the light-emitting parameters can not be modified according to the illumination effect, and can not be modified according to different conditions of specific users, the adaptability is poor, the effect is not good, and visual damage can be brought to users.

disclosure of Invention

the technical problem to be solved by the present invention is to provide a method and an apparatus for adjusting the lighting parameters of a biorhythm lighting apparatus with a configuration that has good adaptability and good effect and can reduce the possibility of visual impairment, aiming at the defects of poor adaptability, poor effect and possible certain visual impairment in the prior art.

the technical scheme adopted by the invention for solving the technical problems is as follows: a method of constructing a configuration for adjusting the lighting parameters of a biorhythmic lighting device, comprising the steps of:

A) logging in a server on an application program of a mobile terminal, so that the application program is connected with a communication module on an illumination device, acquiring identity information and configuration state of the illumination device, and forwarding the identity information and configuration state to the server;

B) the server verifies the identity information of the logged user and the identity information of the illumination device, and calls out the illumination record and the latest detection data of the user after the identity information of the logged user and the identity information of the illumination device are matched;

C) Selecting a corresponding parameter set type from preset parameter sets of multiple types according to the detection data; selecting a closest one of the selected parameter set types in dependence of the illumination record;

D) And after the selected parameter set is subjected to individual adjustment and confirmation, sending the obtained parameter set to the mobile terminal, configuring the parameter set to the illumination device through a communication module of the illumination device, and driving a light-emitting unit to emit light by the illumination device by using the parameter set.

still further, the step C) further comprises the steps of:

C1) detecting whether a special parameter set for the user is stored, if yes, obtaining the special parameter set and replacing the previously selected parameter set by the special parameter set; if not, the previously selected parameter set is still used.

Still further, the step D) further comprises:

D1) detecting whether the user uploads the parameter value of the current brain wave setting component, if so, adjusting the corresponding parameter in the parameter set according to the parameter value, and executing the next step; if not, directly executing the next step;

D2) and sending the obtained parameter set as a configuration parameter set to the mobile terminal.

Further, the step D) further includes the steps of:

D3) detecting whether the user uploads user health condition data obtained by detection of other authenticated body state detection devices, if so, adjusting corresponding parameters in the parameter set according to the user health data and a set rule; if not, exiting the step; the health state data of the user comprise sleep time, deep sleep time and duration data which are uploaded by a bracelet or a watch capable of continuously detecting 24-hour pulse and respiratory states and are obtained according to the pulse and respiratory data;

after the above steps are executed after one login, step D) is repeatedly executed according to the set time.

still further, the method comprises the following steps:

E) After the illumination device emits light for a certain time interval, the brain waves of the user are collected and processed through the brain wave collecting device, and parameter values of set components in the brain waves are obtained and uploaded to the server.

Still further, the parameters in the parameter set include: a center wavelength and its spectral components, light intensity, spectral power density, temporal modulation frequency of light intensity, temporal modulation duty cycle of light intensity, light emission position and/or light emission and end time; the parameter values of the set components of the brain waves include frequency values corresponding to maximum power spectral density corresponding to beta waves or gamma waves in the brain waves.

further, the corresponding parameter adjustment in the step D1) includes: and comparing the frequency value corresponding to the maximum power spectral density corresponding to the beta wave or the gamma wave with the time modulation frequency of the light intensity in the parameter set, and if the frequency value has deviation, resetting the time modulation frequency of the light intensity to enable the time modulation frequency to be close to the time modulation frequency until the difference between the two frequencies is equal to or smaller than a set value.

Further, the setting rule in step D3) includes: comparing the sleep starting time measured by the peripheral equipment with the ideal sleep starting time set by the user, if the sleep starting time deviates, adjusting the blue LED irradiation starting time according to the deviation value, reminding the user of the starting time in a pop-up message mode, and obtaining the user approval until the sleep starting time measured by the peripheral equipment is equal to the ideal sleep starting time set by the user or is less than a certain set value approved by the user; and

And comparing the duration of the deep sleep with the duration set by the user, if the duration of the deep sleep is not reached, properly adjusting the blue light irradiation intensity and/or the irradiation duration of the illumination device according to a preset adjustment program until the duration of the deep sleep measured by the peripheral equipment is equal to or greater than the duration set by the user.

the invention also relates to a device for realizing the method, which comprises the following steps:

a login unit: the system comprises a server, a lighting device and a control module, wherein the server is used for logging in an application program of a mobile terminal, so that the application program is connected with a communication module on the lighting device, and the identity information and the configuration state of the lighting device are obtained and forwarded to the server;

an identity authentication unit: the server is used for verifying the identity information of the logged user and the identity information of the illumination device, and calling out the illumination record and the latest detection data of the user after the identity information of the logged user and the identity information of the illumination device are matched;

A parameter set selection unit: the parameter set type selection module is used for selecting a corresponding parameter set type in preset parameter sets of multiple types according to the detection data; selecting a closest one of the selected parameter set types in dependence of the illumination record;

A parameter set adjustment unit: and the mobile terminal is used for sending the obtained parameter set to the mobile terminal after the individual adjustment confirmation is carried out on the selected parameter set, configuring the parameter set to the illumination device through a communication module of the illumination device, and driving the light-emitting unit to emit light by the illumination device by using the parameter set.

Still further, the parameter set selection unit further includes:

A special parameter set judgment module: for detecting whether a special parameter set for the user is stored, if yes, obtaining the special parameter set and replacing the previously selected parameter set with the special parameter set; if not, the previously selected parameter set is still used;

The parameter set adjustment unit further includes:

an adjusting module: the system is used for detecting whether the user uploads the parameter value of the current brain wave setting component, if so, adjusting the corresponding parameter in the parameter set according to the parameter value, and executing the next step; if not, directly executing the next step;

A sending module: for sending the obtained parameter set as a configuration parameter set to the mobile terminal;

Further comprising:

a brain wave acquisition and processing unit: and the brain wave acquisition device is used for continuously acquiring and processing the brain waves of the user through the brain wave acquisition device after the illumination device emits light, continuously obtaining parameter values of set components in the brain waves and uploading the parameter values to the server.

The method and the device for configuring and adjusting the luminous parameters of the biorhythm illumination device have the following beneficial effects: due to the fact that the application program is used for logging in, parameters in the light-emitting parameter set can be optimized according to information provided by a user individual during registration and configuration information uploaded in the light-emitting process, and the light parameters obtained after the user logs in each time can be the light parameter set most suitable for the current state of the user; meanwhile, the introduction of brain waves enables optical parameter adjustment to be carried out according to the previous irradiation effect even in the irradiation process, so that the adaptability is good, the effect is good, and the possibility of visual damage can be reduced.

drawings

FIG. 1 is a flow chart of the method in an embodiment of the method and apparatus for adjusting the light parameters of a biorhythmic illumination device of the present invention;

Fig. 2 is a detailed flow chart of the individual adjustment of the selected parameter set in the embodiment;

FIG. 3 is a schematic structural view of the system in the embodiment;

fig. 4 is a schematic structural view of the device in the embodiment.

Detailed Description

The embodiments of the present invention will be further described with reference to the accompanying drawings.

as shown in fig. 1, in an embodiment of a method and an apparatus for configuring and adjusting a lighting parameter of a biorhythm lighting apparatus of the present invention, the method for configuring and adjusting the lighting parameter of the biorhythm lighting apparatus comprises the following steps:

Step S11 login server: in the present embodiment, a system including an illumination device for adjusting a biorhythm is taken as an example to describe a configuration process of a light emission parameter of the device. Fig. 3 is a schematic configuration of the system, which includes a server, a mobile terminal, an illumination device, and brain wave processing equipment. The server is used for storing user data, including user registration data and various data after the user adopts illumination, such as electroencephalogram data and data obtained during examination and test; the server is connected with an application program running on the mobile terminal through a network, receives data uploaded by the application program, performs corresponding processing and storage, and simultaneously sends the data to the application program; the illumination device generates and outputs a light beam according to the light-emitting parameters transmitted to the illumination device through the mobile terminal, and illuminates a set part (such as a non-visual area of a pupil) of a human body; the electroencephalogram processing device receives the electroencephalogram of the user irradiated by the light beam, processes the electroencephalogram to obtain parameter values of the set components, and uploads the parameter values to the server through the mobile terminal. In these operations, the determination of identity is very important. For example, brain wave data is uploaded, and the server needs to know to which user the data belongs; when the lighting parameters are issued, it is also necessary to know that the data are suitable for the user. Therefore, in this step, the user logs in the server on the application program of the mobile terminal, so that the application program is connected with the communication module on the illumination device, obtains the identity information and the configuration state of the illumination device, and forwards the identity information and the configuration state to the server; it is worth mentioning that the identity information herein may include the identity information of the user, for example, a name used in registration, etc.; identity information of the lighting device, e.g., a hardware identification code of the lighting device, etc., may also be included; binding information of user information and lighting device identity information, etc. may also be included.

Step S12, verifying identity information, acquiring user data: in this step, the server verifies the identity information of the logged-in user and the identity information of the illumination device, and calls out the illumination record and the latest detection data of the user after the identity information of the logged-in user and the identity information of the illumination device are matched; that is, in this step, the server may verify the multiple identity information, finally confirm that the user is a legitimate user, and search past registration information and historical data of the user using light irradiation, including effect evaluation information obtained after regular and field tests, and the like, in its database.

Step S13 selects a parameter set type and a parameter set: in this step, a corresponding parameter set type is selected from a plurality of preset parameter sets according to the detection data; selecting a closest one of the selected parameter set types in dependence of the illumination record; specifically, since there are many types of the lighting devices themselves and types of biorhythms that can be adjusted by each lighting device, and the lighting parameters of each type are different, the lighting parameters are classified into a plurality of types according to the type of biorhythm to be adjusted, and in each type, the lighting parameters are classified into a plurality of parameter sets according to the set conditions, for example, the degree of lightness or the degree of a certain index; each parameter set comprises all parameters of the biological rhythm of the type of the illumination device to adjust, when the parameter set is transmitted to the illumination device, the illumination device directly uses the parameters in the parameter set to configure, and then the illumination device can emit light beams conforming to the definition of the parameter set to illuminate the used designated part, usually a non-visual area, thereby realizing the adjustment of the safe and effective biological rhythm.

It is worth mentioning that in this step, in some cases, there may be a special set of parameters for an individual, for example, an illumination scheme or recommendation for the user's detection result by a doctor or expert approved by the user, which of course needs to be preferentially adopted. Therefore, in some cases, it is also possible to check whether a special parameter set is stored for the user after performing the above steps, and if so, retrieve the special parameter set and replace it with the previously selected parameter set; if not, the previously selected parameter set is still used. Step S14 outputs the parameter set after individual adjustment or directly to the illumination device: although the parameter set obtained as described above can be used as it is, it has a certain effect. However, since the parameter set is determined for the degree of an index, there is room for an individual to fine-tune some of the parameters. Such a fine tuning may enable the effect of the parameter set on the individual to be enhanced. Therefore, in this step, after the selected parameter set is confirmed to be individually adjusted, the obtained light parameter set is sent to the mobile terminal and configured to the illumination device through the communication module of the illumination device, and the illumination device drives the light emitting unit to emit light by using the parameter set. In some cases, the parameter set obtained in the above step may be directly transmitted to the lighting device without performing individual parameter fine adjustment. Such an operation, while saving some steps, may not work well. But in some cases, for example, individual data is missing, no prior associated illumination effect data is available, and so on, as an acceptable alternative.

In this embodiment, the step S14) may be repeatedly executed at set time intervals, so as to facilitate parameter adjustment at any time according to the lighting effect during the lighting process, so as to obtain a better lighting effect.

As described above, in the present embodiment, the system includes the brain wave processing apparatus which acquires and processes the brain waves of the user before or during the start of the lighting, continuously obtains the parameter values of the set components therein, and uploads the parameter values to the server via the mobile terminal. And according to the parameter values of the set components in the obtained brain waves, the corresponding parameters in the parameter set currently used by the user are adjusted, so that the biological rhythm of the user and the illumination can achieve a certain relation similar to resonance, and a better adjusting effect is further obtained. Therefore, in this embodiment, the relevant parameters in the parameter set may also be individually adjusted during the illumination process.

as shown in fig. 2, when the selected parameter set is individually adjusted during the lighting process (including the initial execution and the repeated execution), the following steps may be included:

If the processed electroencephalogram data is not input in step S21, otherwise, the process goes to step S24; if yes, executing the next step; in this step, it is determined whether electroencephalogram data is input through the mobile terminal.

step S22 is to obtain the set component parameter values in the electroencephalogram data: in this step, the parameter values of the electroencephalogram setting component are extracted from the data uploaded by the mobile terminal.

Step S23 adjusts the corresponding parameter in the selected parameter set to be the above-mentioned setting component value adaptation: in this step, the corresponding parameters in the parameter set are adjusted based on the parameter values of the obtained setting components of the electroencephalogram. For example, according to the frequency value of the beta wave or the gamma wave in the electroencephalogram data, the time modulation frequency of the light intensity in the parameter set is close to or equal to the frequency of the received beta wave or gamma wave.

Step S24 outputs the selected parameter set: in this step, the parameter sets with or without individual adjustment are output.

it is worth mentioning that, in this embodiment, the parameters in the parameter set include: the center wavelength and its spectral components, the light intensity, the spectral power density, the temporal modulation frequency of the light intensity, the temporal modulation duty cycle of the light intensity, the light emission location and/or the light emission and end times; the parameter values of the set components of the brain waves comprise frequency values of beta waves or gamma waves in the brain waves; the corresponding parameter corresponding to the set component in the brain waves includes a time modulation frequency of light intensity.

In this embodiment, the above parameters may be adjusted according to the biological rhythm of the user during or after the illumination, and the adjustment may be performed for some parameters in a preset parameter set. For example, the current parameter set is adjusted according to the characteristics of the brain waves of the user during the illumination process. For example, in the above-described adjustment according to the components set in the brain waves, the corresponding parameter adjustment includes: comparing the frequency value corresponding to the maximum power spectral density corresponding to the beta wave or the gamma wave with the time modulation frequency of the light intensity in the parameter set, if the frequency value has deviation, resetting the time modulation frequency of the light intensity to enable the light intensity to be close, and repeating the steps for multiple times to enable the difference value of the two frequencies to be gradually reduced until the difference value of the two frequencies is equal to or smaller than a set value.

in this embodiment, the parameters that are adjusted when lighting for a symptom may be different. For example, in one case, for insomnia, the step of adjusting the parameters is performed according to a set rule, and the set rule includes: comparing the sleep starting time measured by the peripheral with the ideal sleep starting time set by the user, if the sleep starting time deviates, adjusting the blue LED irradiation starting time according to the deviation equivalent value, reminding the user of the starting time in a pop-up message mode, and obtaining the user approval until the sleep starting time measured by the peripheral is equal to the ideal sleep time set by the user or is less than a certain set value approved by the user; in addition, the duration of the deep sleep may also be compared with a duration set by the user, and if not, the blue light irradiation intensity and/or the irradiation duration of the illumination device may be appropriately adjusted according to a preset adjustment program until the duration of the deep sleep measured by the peripheral device is equal to or greater than the duration set by the user.

in general, in this embodiment, the illumination device includes a device frame designed in the shape of eyeglasses to be worn on a person's face, a control module, a light modulation module, a plurality of LED light sets, a communication module, an ambient light sensor, a power supply module, and the like on the device frame. The control module comprises a core processor and a simple input key, is directly connected with the light modulation module, the communication module, the ambient light sensor and the power supply module respectively, and is indirectly connected with the LED lamp sets to play a role in regulating and controlling the whole device in real time; the light modulation module controls specific light parameters output by the plurality of LED lamp groups; the plurality of LED lamp groups are driven by the signals modulated by the light modulation module to emit light which accords with set parameters; the communication module provides a connection channel and is connected with an intelligent device APP (application program) on the mobile terminal; the ambient light sensor transmits device background light information collected in real time to the control module to assist in adjusting the light modulation module; the power module is controlled by the control module and is used for supplying power to the whole human body biological rhythm adjusting device. In this embodiment, the device frame is in the shape of full-frame glasses. The outline of the glasses is slightly larger than that of the conventional glasses used in the existing market, so that the glasses can be used when the user does not wear the glasses, and the glasses can be used when the user wears the glasses, and the normal use effect is not influenced. The frame design of the device meets the use conditions of different users, the use range is expanded, and the practicability and effectiveness of the device are improved. The LED lamp sets are arranged at the upper and lower positions of the lens ring of the device frame, the LED lamp sets can be one group or two groups or three groups or four groups or five groups or six groups or seven groups or eight groups, each group of the LED lamp sets comprises one group or two groups or three groups of LED lamps, and the distance from the front ends of the luminous bodies of the LED lamp sets to the iris of human eyes is 12-16 mm. In a preferred example, the distance from the front end of the luminous body of the LED lamp group to the iris of a human eye is about 14 mm. Can effectively control the stimulation to the retina around the human eye. Because the multiple groups of LED lamp groups illuminate different areas respectively, the power density distribution is reduced, and the illumination damage is reduced; the multiple LED lamp groups can realize multi-wavelength combination, the stimulation range is increased, and simultaneously, the combination of multi-color light can reduce discomfort caused by stimulation of a visual area due to monochromatic light. Effectively realizes the illumination of the peripheral retina under the condition of not influencing the normal vision. Provides a substantially uniform illumination and may allow a range of eye movements, such as opening or rotation of the eye. In the present embodiment, the effective light intensity of the corneal surface is made to be 8-8000lux, and the incident light power from the pupil is made to be 8-800 uw/cm.

Each LED tube tip (namely the LED light-emitting surface) of the LED lamp groups inclines by a certain angle and points to the pupil, so that the direct yellow spot area is avoided, and meanwhile, different areas of the peripheral retina can be effectively irradiated, including the nose area and the side area, without affecting normal vision. Each LED in the LED lamp group is high in directivity. The LED lamp group is generally packaged by pointed epoxy, or packaged by a metal reflecting cavity, or additionally provided with a condensing lens, and no scattering agent is added, the light-emitting angle is 15-20 degrees, the pupil is ensured not to depart from the light-emitting coverage range of the LED lamp group during movement, and meanwhile, excessive stray light is prevented from irradiating the vicinity of eyes. The diameter of the spot at the iris surface can be considered to be substantially equal to the iris diameter.

The light modulation module adopts light modulation and spectrum mixing to enable the LED lamp set to output light with different time modulation frequencies, different wavelengths and different intensities, multiple groups of LED lamp sets can be used for enabling the light with different combinations to form composite light at pupils, the light modulation module controls specific light parameters output by the LED lamp sets to comprise time frequency, luminous intensity and duty ratio, the modulation effect comprises wavelength combination, frequency combination and intensity combination, the light modulation module controls specific light parameters output by the LED lamp sets to comprise time modulation frequency, wavelength modulation, intensity modulation and duty ratio modulation of a single group of the LED lamp sets, the light modulation module controls specific light parameters output by the LED lamp sets to comprise depth modulation, color temperature modulation and power modulation of the multiple groups of the LED lamp sets, the frequency modulation range of the single group of the LED lamp sets is 0-80Hz, the wavelength modulation range is 450-, The intensity modulation range is 2-2000lux, the duty ratio modulation range is 0-100%, the light modulation module can modulate a plurality of groups (for example, 2-8 groups) of depth modulation, color temperature modulation and power modulation of the LED lamp set compared with the background light, and the depth modulation range is 0-100%. In short, the light modulation module 11 controls specific light parameters output by the plurality of LED lamp sets, and the specific modulation mode mainly includes: time frequency, luminous intensity, duty cycle; the final modulation effect is represented as: wavelength combinations, frequency combinations, intensity combinations.

The light modulation module controls specific light parameters output by the multiple groups of LED lamp groups, and the specific light parameters comprise time modulation frequency, wavelength modulation, intensity modulation and duty ratio modulation of a single group of LED lamps, and depth modulation, color temperature modulation and power modulation of the multiple groups of LED lamps. The modulated light is within acceptable range for the human eye and meets the conventional requirements of photobiological research, including recent data showing that blue light of fixed frequency 40Hz may have a greater effect on AD patients (patients with senile dementia).

In this embodiment, the smart device or the mobile terminal is a smart phone and must be provided with a bluetooth communication module, and it is ensured that enough storage space is available for loading and operating the mobile phone APP. The operating system of the smart phone can comprise common Windows, Android, apple IOS and the like. The APP provides a series of common language interfaces for the user, such as login, registration, authentication, evaluation and the like, so that the APP is convenient for the user to use; and the system is provided with a Wi-Fi (wireless fidelity), a 4G (fourth generation) and other general communication interfaces so as to communicate with the cloud server. The user can register personal information including disease information to be conditioned, fill in professional scales for disease evaluation, share and communicate use experience with other users and the like by means of the APP interface.

it is worth mentioning that the light-operated device is provided with a mechanical switch, so that the user can use the human body biological rhythm adjusting device only by turning on and off the switch under the condition of not logging in the cloud server, and only the formula used at the moment is data downloaded during last login; the system supports uploading information of the last use condition when logging in next time.

In this embodiment, the above-mentioned one parameter set may be regarded as a "lighting recipe", which is classified according to different adaptation symptoms, and a plurality of such parameter sets may be included in each class.

For example, four parameter sets may be included under one category of adaptation symptoms (e.g., AD), as follows:

1: the outer sides of the noses of the left eye and the right eye totally have 4 blue LEDs which emit light, and the modulation frequency of each LED is 40Hz, the wavelength is 463nm, the duty ratio is 40 percent, and the power is 2 mW;

2: the external side of the nose of the left eye and the right eye only emits 2 blue light LEDs at the upper parts, and the modulation frequency of each LED is 40Hz, the wavelength is 463nm, the duty ratio is 40 percent, and the power is 2 mW;

3: 4 blue light LEDs on the outer sides of the noses of the left eye and the right eye emit light, and the modulation frequency of each LED is 40Hz, the wavelength is 463nm, the duty ratio is 40%, and the power is 2 mW; the red light LEDs located at the same position and the same position of the LEDs emit light, and the modulation frequency of each LED is 0Hz, the wavelength is 675nm, and the power is 1 mW. The formula can weaken the tingling feeling caused by the simple blue light irradiation on the retina visual area and can not weaken the stimulation effect of the blue light on the retina non-visual area by mixing the red light and the blue light;

4: only the upper 2 blue LEDs at the outer sides of the noses of the left eye and the right eye emit light, and the modulation frequency of each LED is 40Hz, the wavelength is 463nm, the duty ratio is 40%, and the power is 2 mW; the 2 red LEDs located at the same position and the same position of the LEDs emit light, and the modulation frequency of each LED is 0Hz, the wavelength is 675nm, and the power is 1 mW. The formula can reduce the tingling feeling of the retina visual area caused by the pure blue light irradiation by mixing the red light and the blue light, and can not reduce the stimulation effect of the blue light on the retina non-visual area.

In general, the system recommends an appropriate illumination "recipe" to the user through an optimization algorithm according to the personal conditions of the user, including the state of illness, and automatically turns on the adjustment unit through the APP to perform illumination. The treatment data is sent to a cloud server through the APP, and the treatment data comprises starting time, ending time, a formula and the like; at the same time, the human body biological rhythm regulation device records the illumination formula selected by the user. Meanwhile, the recorded information can be stored in the intelligent equipment of the user and the name of the registrant synchronized to the cloud server.

As another example, another set of parameters under a category adapted for symptoms (e.g., insomnia) may also include 4, as follows:

1: the outer sides of the noses of the left eye and the right eye totally have 4 blue LEDs which emit light, and the modulation frequency of each LED is 0Hz, the wavelength is 465nm, the duty ratio is 40%, and the power is 2 mW;

2: the outer sides of the noses of the left eye and the right eye only emit 2 blue light LEDs, and the modulation frequency of each LED is 0Hz, the wavelength is 465nm, the duty ratio is 40%, and the power is 2 mW;

3: 4 blue light LEDs on the outer sides of the noses of the left eye and the right eye emit light, and the modulation frequency of each LED is 0Hz, the wavelength is 465nm, the duty ratio is 40%, and the power is 2 mW; the red light LEDs located at the same position and the same position of the LEDs emit light, and the modulation frequency of each LED is 0Hz, the wavelength is 675nm, and the power is 1 mW. The formula can weaken the tingling feeling caused by the simple blue light irradiation on the retina visual area and can not weaken the stimulation effect of the blue light on the retina non-visual area by mixing the red light and the blue light;

4: only 2 blue LEDs on the upper part of the outer sides of the noses of the left eye and the right eye emit light, and the modulation frequency of each LED is 0Hz, the wavelength is 465nm, the duty ratio is 40%, and the power is 2 mW; the 2 red LEDs located at the same position and the same position of the LEDs emit light, and the modulation frequency of each LED is 0Hz, the wavelength is 675nm, and the power is 1 mW. The formula can reduce the tingling feeling of the retina visual area caused by the pure blue light irradiation by mixing the red light and the blue light, and can not reduce the stimulation effect of the blue light on the retina non-visual area.

the invention also relates to a device for realizing the method, which comprises a login unit 1, an identity verification unit 2, a parameter set selection unit 3, a parameter set adjustment unit 4 and a brain wave acquisition and processing unit 5, as shown in fig. 4. The login unit 1 is used for logging in a server on an application program of the mobile terminal, so that the application program is connected with a communication module on the illumination device, the identity information and the configuration state of the illumination device are obtained, and the identity information and the configuration state are forwarded to the server; the identity authentication unit 2 is used for authenticating the identity information of the logged user and the identity information of the illumination device at the server, and calling out the illumination record and the latest detection data of the user after the identity information of the logged user and the identity information of the illumination device are matched; the parameter set selection unit 3 is configured to select a corresponding parameter set type from among preset parameter sets of multiple types according to the detection data; selecting a closest one of the selected parameter set types in dependence of the illumination record; the parameter set adjusting unit 4 is configured to send the obtained light parameter set to the mobile terminal after performing individual adjustment and confirmation on the selected parameter set, and configure the light parameter set to the illumination device through a communication module of the illumination device, where the illumination device drives the light emitting unit to emit light using the parameter set; the brain wave collecting and processing unit 5 is used for continuously collecting and processing the brain waves of the user through the brain wave collecting device after the illuminating device emits light, continuously obtaining the parameter values of the set components and uploading the parameter values to the server.

Furthermore, the parameter set selection unit 3 further comprises a special parameter set determination module 31, which is used to detect whether a special parameter set for the user is stored, and if so, the special parameter set is obtained and replaced with the previously selected parameter set; if not, the previously selected parameter set is still used. The parameter set adjusting unit 4 further comprises an adjusting module 41 and a sending module 42; the adjusting module 41 is configured to detect whether the user uploads a parameter value of a current brain wave setting component, if yes, adjust a corresponding parameter in the parameter set according to the parameter value, and execute the next step; if not, directly executing the next step; the sending module 42 is configured to send the obtained parameter set to the mobile terminal as a configuration parameter set.

the above-mentioned embodiments only express several embodiments of the present invention, and the description thereof is more specific and detailed, but not construed as limiting the scope of the present invention. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the inventive concept, which falls within the scope of the present invention. Therefore, the protection scope of the present patent shall be subject to the appended claims.

Claims

1. a method for configuring and adjusting a lighting parameter of a biorhythmic lighting device, comprising the steps of:

2. The method for configuring and adjusting parameters of light emission of a biorhythmic illumination device of claim 1, wherein the step C) further comprises the steps of:

3. The method for configuring and adjusting parameters of light emission of a biorhythmic illumination device of claim 2, further comprising in step D):

4. The method for adjusting the lighting parameters of a biorhythmic lighting device according to claim 3, wherein the step D) further includes the steps of:

D3) detecting whether the user uploads user health condition data obtained by detection of other authenticated physical state detection devices, if so, adjusting corresponding parameters in the parameter set according to the user health condition data and a set rule; if not, exiting the step; the health condition data of the user comprises sleep time, deep sleep time and duration data which are uploaded by a bracelet or a watch capable of continuously detecting 24-hour pulse and respiratory states and are obtained according to the pulse and respiratory data;

5. The method for configuring and adjusting parameters of light emission of a biorhythmic illumination device of claim 3, further comprising the steps of:

6. The method for configuring adjusting a lighting parameter of a biorhythmic lighting device of claim 5, wherein the parameters in the parameter set include: a center wavelength and its spectral components, light intensity, spectral power density, temporal modulation frequency of light intensity, temporal modulation duty cycle of light intensity, light emission position and/or light emission and end time; the parameter values of the set components of the brain waves include frequency values corresponding to maximum power spectral density corresponding to beta waves or gamma waves in the brain waves.

7. the method for configuring and adjusting parameters of light emission of a biorhythmic illumination device according to claim 6, wherein the corresponding parameter adjustment in the step D1) includes: and comparing the frequency value corresponding to the maximum power spectral density corresponding to the beta wave or the gamma wave with the time modulation frequency of the light intensity in the parameter set, and if the frequency value has deviation, resetting the time modulation frequency of the light intensity to enable the time modulation frequency to be close to the time modulation frequency until the difference between the two frequencies is equal to or smaller than a set value.

8. The method for configuring and adjusting light emission parameters of a biorhythmic illumination device according to claim 4, wherein the setting rule of the step D3) includes: comparing the sleep starting time measured by the peripheral equipment with the ideal sleep starting time set by the user, if the sleep starting time deviates, adjusting the blue LED irradiation starting time according to the deviation value, reminding the user of the starting time in a pop-up message mode, and obtaining the user approval until the sleep starting time measured by the peripheral equipment is equal to the ideal sleep starting time set by the user or is less than a certain set value approved by the user; and

9. an apparatus implementing the method of configuring an adjustment of a lighting parameter of a biorhythmic lighting device as set forth in claim 1, comprising:

10. The apparatus of claim 9, wherein the parameter set selection unit further comprises:

The parameter set adjustment unit further includes:

further comprising:

a brain wave acquisition and processing unit: the brain wave acquisition device is used for acquiring and processing the brain waves of the user after the illumination device emits light, obtaining parameter values of the set components in the brain waves and uploading the parameter values to the server.