CN115933349A - Intelligent awakening method, intelligent awakening device, intelligent awakening terminal and storage medium - Google Patents

Abstract

The application is suitable for the field of intelligent control, and provides an intelligent awakening method, an intelligent awakening device, an intelligent awakening terminal and a storage medium. The method comprises the following steps: acquiring current time; and if the current time is detected to reach the preset awakening time, controlling the color temperature and the luminous flux corresponding to the target lamp to continuously increase within the preset awakening time through the awakening function. The awakening mode enables the color temperature of light emitted by the lamp and the brightness of the light to be changed from weak to strong, and the color temperature and the brightness of the light are continuously and gradually enhanced in the whole awakening process, so that the color temperature and the brightness of the light are ensured to continuously and gently stimulate the user, the color temperature and the brightness of the light are more matched with the sleep state of the user, and the user is stimulated to gradually enter the light sleep state from the deep sleep state. Effectively prevent that the user from leading to the condition of uncomfortable and producing negative emotion because of receiving unexpected awakening stimulus, promoted intelligent awakening effect, be favorable to user's healthy.

Description

Intelligent awakening method, intelligent awakening device, intelligent awakening terminal and storage medium

Technical Field

The application belongs to the field of intelligent control, and particularly relates to an intelligent awakening method, an intelligent awakening device, an intelligent awakening terminal and a storage medium.

Background

In order to get up on time for work, people usually set an alarm clock to wake up, but the alarm clock wakened by conventional sounds is single in wakening mode, not intelligent and poor in wakening effect, so that uncomfortable getting up experience is brought to people, and particularly for users in deep sleep states, the alarm clock sounds suddenly sounded may cause headache, fatigue and the like of the users, and are not beneficial to the body health of the users.

Disclosure of Invention

In view of this, embodiments of the present application provide an intelligent wake-up method, an intelligent wake-up apparatus, an intelligent wake-up terminal, and a storage medium, so as to solve the problems in the prior art that an alarm clock wake-up mode is single and not intelligent, resulting in a poor wake-up effect and being not beneficial to the physical health of a user.

A first aspect of an embodiment of the present application provides an intelligent wake-up method, including:

acquiring current time;

and if the current time is detected to reach the preset awakening time, controlling the color temperature and the luminous flux corresponding to the target lamp to continuously increase within the preset awakening time through the awakening function, and continuously increasing the color temperature and the luminous flux corresponding to the target lamp within the preset awakening time for awakening the user.

Optionally, the wake-up function includes a color temperature change function and a luminous flux change function, and if it is detected that the current time reaches a preset wake-up time, the intelligent wake-up method further includes, before controlling, by the wake-up function, the color temperature and the luminous flux corresponding to the target lamp to continuously increase within a preset wake-up time period:

constructing the color temperature change function;

constructing the luminous flux variation function;

if it is detected that the current time reaches the preset wake-up time, controlling the color temperature and the luminous flux corresponding to the target lamp to continuously increase within the preset wake-up time through the wake-up function, including:

if the current time is detected to reach the preset awakening time, controlling the color temperature corresponding to the target lamp to continuously increase within the preset awakening time through the color temperature change function;

and controlling the luminous flux corresponding to the target lamp to continuously increase within the preset awakening time through the luminous flux change function.

Optionally, the preset wake-up time includes a wake-up start time and a wake-up end time, and the constructing the color temperature change function includes:

acquiring the awakening starting time and the awakening ending time;

acquiring a plurality of first time points between the awakening start time and the awakening end time, and acquiring the color temperature corresponding to each first time point;

and fitting to generate the color temperature change function according to the awakening starting time, the awakening ending time, each first time point and the color temperature corresponding to each first time point.

Optionally, the constructing the luminous flux variation function includes:

acquiring the awakening starting time and the awakening ending time;

acquiring a plurality of second time points between the awakening start time and the awakening end time, and acquiring the luminous flux corresponding to each second time point;

and fitting to generate the luminous flux change function according to the awakening start time, the awakening end time, each second time point and the luminous flux corresponding to each second time point.

Optionally, the wake-up function includes a fitting function, and before it is detected that the current time reaches a preset wake-up time and the color temperature and the luminous flux corresponding to the target lamp are controlled to continuously increase within a preset wake-up duration by the wake-up function, the intelligent wake-up method further includes:

acquiring geographical position information and time information corresponding to the user;

searching sunrise data matched with both the geographic position information and the time information;

fitting and generating the fitting function according to the sunrise data;

if the current time is detected to reach the preset awakening time, controlling the color temperature and the luminous flux corresponding to the target lamp to continuously increase within the preset awakening time through the awakening function, and the method comprises the following steps:

and if the current time is detected to reach the preset awakening time, controlling the color temperature and the luminous flux corresponding to the target lamp to continuously increase within the preset awakening time through the fitting function.

Optionally, after the fitting function is generated according to the sunrise data fitting, the smart wake-up method further includes:

acquiring preference data of the user, wherein the preference data comprises a color temperature change range and a luminous flux change range defined by the user;

adjusting the fitting function according to the preference data.

Optionally, when the number of the keywords is multiple, the determining, according to the information analysis model, the user preference corresponding to the keyword includes:

determining the user preference corresponding to each keyword according to the information analysis model;

and calculating an average value based on the user preference corresponding to each keyword to obtain the user preference corresponding to the information to be pushed.

A second aspect of the embodiments of the present application provides an intelligent wake-up apparatus, including:

an acquisition unit configured to acquire a current time;

and the control unit is used for controlling the color temperature and the luminous flux corresponding to the target lamp to continuously increase in the preset wake-up time through the wake-up function if the current time is detected to reach the preset wake-up time, and the color temperature and the luminous flux corresponding to the target lamp continuously increase in the preset wake-up time to wake up the user.

A third aspect of the embodiments of the present application provides an intelligent wake-up terminal, including a memory, a processor, and a computer program stored in the memory and executable on the processor, where the processor implements the steps of the intelligent wake-up method according to the first aspect when executing the computer program.

A fourth aspect of embodiments of the present application provides a computer-readable storage medium, which stores a computer program, and when the computer program is executed by a processor, the computer program implements the steps of the smart wake-up method according to the first aspect.

A fifth aspect of embodiments of the present application provides a computer program product, which, when running on an intelligent wake-up terminal, causes the terminal to execute the steps of the intelligent wake-up method according to the first aspect.

The intelligent awakening method, the intelligent awakening device, the intelligent awakening terminal and the storage medium have the following beneficial effects:

acquiring current time; and if the current time is detected to reach the preset awakening time, controlling the color temperature and the luminous flux corresponding to the target lamp to continuously increase within the preset awakening time through the awakening function. The mode of controlling the color temperature and the luminous flux corresponding to the target lamp to continuously increase within the preset awakening time through the awakening function enables the color temperature of light emitted by the lamp and the brightness of the light to be changed from weak to strong, and the color temperature and the brightness of the light are continuously and gradually enhanced in the whole awakening process, so that the color temperature and the brightness of the light are ensured to continuously and gently stimulate the user, the stimulation of the color temperature and the brightness of the light to the user is more matched with the sleep state of the user, and the user is stimulated to gradually enter a light sleep state from a deep sleep state. The situation that the user is uncomfortable and generates negative emotion due to sudden awakening stimulation is effectively prevented from occurring, the intelligent awakening effect is improved, and the physical health of the user is facilitated.

Drawings

In order to more clearly illustrate the technical solutions in the embodiments of the present application, the drawings needed to be used in the embodiments or the prior art descriptions will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present application, and it is obvious for those skilled in the art to obtain other drawings based on these drawings without inventive exercise.

FIG. 1 is a schematic flow chart diagram of a smart wake-up method provided by an exemplary embodiment of the present application;

FIG. 2 is a schematic flow chart diagram illustrating a smart wake-up method according to yet another exemplary embodiment of the present application;

FIGS. 3a to 3c are schematic diagrams of the color temperature variation function shown in the present application;

fig. 4a to 4c are diagrams illustrating the luminous flux variation function shown in the present application;

FIG. 5 is a schematic diagram of a fitting function shown in the present application;

FIG. 6 is a schematic diagram of the adjusted fitting function shown in the present application;

fig. 7 is a schematic diagram of an intelligent wake-up apparatus according to an embodiment of the present application;

fig. 8 is a schematic diagram of an intelligent wake-up terminal according to another embodiment of the present application.

Detailed Description

In order to make the objects, technical solutions and advantages of the present application more apparent, the present application is described in further detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the present application and are not intended to limit the present application.

In the description of the embodiments of the present application, "/" means "or" unless otherwise specified, for example, a/B may mean a or B; "and/or" herein is merely an association describing an associated object, and means that there may be three relationships, e.g., a and/or B, which may mean: a exists alone, A and B exist simultaneously, and B exists alone. In addition, in the description of the embodiments of the present application, "a plurality" means two or more than two.

In the following, the terms "first", "second" are used for descriptive purposes only and are not to be understood as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include one or more of that feature. In the description of the present embodiment, "a plurality" means two or more unless otherwise specified.

In order to get up to work on time, people set the alarm clock to wake up usually, but the alarm clock that regular sound awakens up, the awakening mode is single, not intelligent, awaken the effect poor, can bring uncomfortable getting up experience for people more, especially to the user who is in the deep sleep state, the alarm clock sound of sounding suddenly can cause user's headache, tired etc. is unfavorable for user's healthy.

Recent medical research proves that human sleep has an inherent mechanism, and natural waking accords with the human body biological clock law. The light is a necessary condition for natural waking, and is a biological alarm clock in a human body. In the early morning, the human body feels increasingly strong sunlight, the melatonin secretion is reduced, the serotonin secretion is increased, the metabolism is accelerated, and the human body gradually transits from deep sleep to light sleep until the human body wakes up.

In view of this, the present application provides an intelligent wake-up method, which is different from the wake-up mode of the traditional ring alarm clock, and avoids the situations that the traditional alarm clock wakes up suddenly to cause discomfort to the user and generate negative emotions. The intelligent awakening method comprises the steps of obtaining current time; and if the current time is detected to reach the preset awakening time, controlling the color temperature and the luminous flux corresponding to the target lamp to continuously increase within the preset awakening time through the awakening function. The mode of controlling the color temperature and the luminous flux corresponding to the target lamp to continuously increase within the preset awakening time through the awakening function enables the color temperature of light emitted by the lamp and the brightness of the light to be changed from weak to strong, and the color temperature and the brightness of the light are continuously and gradually enhanced in the whole awakening process, so that the color temperature and the brightness of the light are ensured to continuously and gently stimulate the user, the stimulation of the color temperature and the brightness of the light to the user is more matched with the sleep state of the user, and the user is stimulated to gradually enter a light sleep state from a deep sleep state. Effectively prevent that the user from leading to the condition of uncomfortable and producing negative emotion because of receiving unexpected awakening stimulus, promoted intelligent awakening effect, be favorable to user's healthy.

The execution main body of the intelligent awakening method is the intelligent awakening terminal. The intelligent awakening terminal can be any type of lamp capable of realizing the intelligent awakening method, and can also be a mobile terminal such as a smart phone, a tablet computer, a Personal Digital Assistant (PDA), a desktop computer, a wearable device and the like, and the mobile terminal is connected with the lamp through a network and is used for controlling the lamp to realize the intelligent awakening method.

For example, the intelligent wake-up terminal may include, but is not limited to, any type of intelligent lamp (e.g., an intelligent ceiling lamp, an intelligent desk lamp, an intelligent wall-mounted lamp, an intelligent night lamp, etc.), and may also include a lamp to which an intelligent chip may be installed, where the intelligent chip may control the lamp to implement the above-mentioned intelligent wake-up method. The description is given for illustrative purposes only and is not intended to be limiting.

In order to better understand the embodiments of the present application, terms or concepts that may be referred to in the embodiments are described below.

1. Color temperature

The color temperature is a unit of measure representing the color component contained in the light. Theoretically, the blackbody temperature refers to the color that an absolute blackbody would appear after warming from absolute zero (-273 ℃). After being heated, the black body gradually turns from black to red, turns yellow and becomes white, and finally emits blue light. When heated to a certain temperature, the light emitted by a black body contains spectral components, referred to as the color temperature at that temperature, measured in "K" (kelvin).

A certain light source emits light having the same spectral composition as that of light emitted from a black body at a certain temperature, and is called a certain K color temperature. If the color of the light emitted from a 100W bulb is the same as the color of an absolute black body at 2527 ℃, then the color temperature of the light emitted from this bulb is: (2527 + 273) K =2800K.

2. Luminous flux

Luminous flux (luminous flux) refers to the radiation power perceived by the human eye, which is equal to the product of the radiation energy in a certain wavelength band per unit time and the relative visibility of that wavelength band. Because the relative visual rate of human eyes to different wavelengths of light is different, the luminous fluxes of different wavelengths of light are not equal when the radiation power of different wavelengths of light is equal. Can be understood colloquially as follows. When the areas are the same, the larger the light flux, the higher the luminance.

3. Illuminance of light

Illumination intensity, abbreviated as illumination, is a physical term that refers to the luminous flux of visible light received per unit area.

Referring to fig. 1, fig. 1 is a schematic flowchart of a smart wake-up method according to an exemplary embodiment of the present application. The smart wake-up method as shown in fig. 1 may include: s101 to S102 are as follows:

s101: and acquiring the current time.

In this embodiment, an intelligent lamp is taken as an example for explanation, and the intelligent lamp can implement the intelligent wake-up method provided by the present application. Illustratively, the intelligent luminaire is pre-connected to the network. For example, the user operates the intelligent lamp to enable the intelligent lamp to access a wireless network.

The intelligent lamp accessed to the network can acquire the current time in real time through the network.

Optionally, in a possible implementation scenario, when the intelligent wake-up terminal is a mobile terminal, the mobile terminal is connected to the lamp in advance through a network, the mobile terminal obtains the current time in real time and sends the current time to the lamp, and the lamp receives the current time sent by the mobile terminal in real time.

S102: and if the current time is detected to reach the preset awakening time, controlling the color temperature and the luminous flux corresponding to the target lamp to continuously increase within the preset awakening time through the awakening function, and continuously increasing the color temperature and the luminous flux corresponding to the target lamp within the preset awakening time for awakening the user.

The preset wake-up time may include a wake-up start time and a wake-up end time. Wherein, the wake-up start time may be a user-defined start time that wants to wake up through the target luminaire. The wake-up end time may be a user-defined end time that wants to wake up the target luminaire.

The preset wake-up duration may be the user-defined total duration of time that he wants to wake up his/her wake-up through the target luminaire. For example, the user sets the entire length of time he wants to wake up his bed through the target luminaire according to his own preferences.

The preset awakening time length can be determined through the awakening start time and the awakening end time, the awakening end time can also be determined through the awakening start time and the preset awakening time length, the awakening start time can also be determined through the awakening end time and the preset awakening time length, and the awakening start time and the awakening end time are not limited.

For example, the wake-up start time may be 5. For another example, the wake-up start time is 7. For another example, the wake-up ending time is 8, the preset wake-up duration is 20 minutes, and the wake-up starting time is 8. The above description is merely exemplary, and may be adjusted according to actual situations, which is not limited herein.

Illustratively, when the user needs smart wake-up in noon break, the wake-up start time may also be set as 13.

Illustratively, when some users need to be woken intelligently during commute, night shift, etc., the wake-up start time is set to be 15. The above description is exemplary, and may be adjusted according to actual situations, which is not limited herein.

The awakening function is used for assisting the intelligent lamp to control the color temperature and the luminous flux corresponding to the intelligent lamp to continuously increase within a preset awakening time. Exemplarily, the abscissa of the wake-up function is used to represent the change in time and the ordinate is used to represent the change in color temperature and luminous flux. It can be understood in a popular way that the intelligent lamp controls the color temperature and the luminous flux corresponding to the intelligent lamp to slowly and continuously increase along with the time according to the numerical value changes in the horizontal coordinate and the vertical coordinate in the wake-up function.

The target lamp is a lamp currently used by the user to wake up the user to get up, and in this example, the target lamp is an intelligent lamp.

Illustratively, when it is detected that the current time reaches a wake-up start time included in the preset wake-up time, the intelligent lamp controls the color temperature of the target lamp (intelligent lamp) to slowly and continuously increase according to a change curve of time and color temperature in the wake-up function along with the time until the current time reaches a wake-up end time included in the preset wake-up time. That is, the entire process of the change of the color temperature starts from the wake-up start time until the current time reaches the wake-up end time.

Illustratively, when it is detected that the current time reaches a wake-up start time included in the preset wake-up time, the intelligent lamp controls the luminous flux of the target lamp (the intelligent lamp) to slowly and continuously increase along with the time according to a variation curve of time and luminous flux in the wake-up function until the current time reaches a wake-up end time included in the preset wake-up time. That is, the entire process of the change of the light flux starts from the wake-up start time until the current time reaches the wake-up end time.

The color temperature and luminous flux corresponding to the target lamp continuously increase within the preset awakening time, so that the color temperature of light emitted by the lamp and the brightness of the light are changed from weak to strong, the light is continuously and gradually enhanced in the whole awakening process, and the change process is closer to the change process of gradually enhancing the real sunlight.

In the above embodiment, the current time is obtained; and if the current time is detected to reach the preset awakening time, controlling the color temperature and the luminous flux corresponding to the target lamp to continuously increase within the preset awakening time through the awakening function. The mode of controlling the color temperature and the luminous flux corresponding to the target lamp to continuously increase within the preset awakening time through the awakening function enables the color temperature of light emitted by the lamp and the brightness of the light to be changed from weak to strong, and the color temperature and the brightness of the light are continuously and gradually enhanced in the whole awakening process, so that the color temperature and the brightness of the light are ensured to continuously and gently stimulate the user, the stimulation of the color temperature and the brightness of the light to the user is more matched with the sleep state of the user, and the user is stimulated to gradually enter a light sleep state from a deep sleep state. Effectively prevent that the user from leading to the condition of uncomfortable and producing negative emotion because of receiving unexpected awakening stimulus, promoted intelligent awakening effect, be favorable to user's healthy.

And because the change of the color temperature and the brightness of the light emitted by the simulated lamp is more like the change of real sunlight, after the body feels the change of the color temperature and the brightness of the light, the secretion of melatonin is reduced, the secretion of serotonin is increased, the metabolism is accelerated, and the person gradually transits from deep sleep to light sleep until waking up. The natural waking mode is beneficial to regulating the physiological rhythm of the human body, reducing the sleep inertia, improving the alertness of one day, enabling the user to feel more comfortable and bringing joyful mood to the user.

Referring to fig. 2, fig. 2 is a schematic flowchart illustrating a smart wake-up method according to another exemplary embodiment of the present application. The smart wake-up method as shown in fig. 2 may include: s201 to S204 are as follows:

s201: and acquiring the current time.

The implementation of step S201 in this embodiment is the same as the implementation of step S101, and reference may be made to the description in step S101, which is not repeated herein.

S202: and constructing a color temperature change function.

Illustratively, constructing the color temperature change function requires a wake-up start time and a wake-up end time, a number of first time points between the wake-up start time and the wake-up end time, and a color temperature corresponding to each first time point. And the color temperature corresponding to the awakening starting time point and the color temperature corresponding to the awakening ending time point can also be included.

The prototype of the color temperature change function may be a linear change function, a polynomial curve, a sigmoid curve, an exponential curve, a power curve, a logarithmic curve, or the like, and is not limited as long as it is a growth function.

The plurality of first time points between the awakening start time and the awakening end time, the color temperature corresponding to each first time point, the color temperature corresponding to the awakening start time point and the color temperature corresponding to the awakening end time can be defined by a user.

For example, the user-defined wake-up start time is 7. The user wants 7 to have a color temperature of 1800K at 00 and 5000K at 30. Several first time points are selected, namely, 7, 10, 7, 15, 7.

Taking a linear change function as an example, the color temperatures at the time points and the time points are substituted into the linear change function, and the coefficient of the linear change function is calculated, so as to obtain the color temperature change function based on the linear change function.

It should be noted that the color temperature customized by the user may also be a color temperature variation range. For example, the color temperature range at a certain time point is set to be 1500K-3200K, 3700K-7000K and the like. The smaller the time interval of each selected time point is, the more accurate the constructed color temperature change function is. Therefore, when the color temperature change corresponding to the intelligent lamp is controlled according to the color temperature change function, the expected effect of the user is better met.

In the above manner, the color temperature change function is constructed by using the data such as the user-defined first time points and the color temperature corresponding to each first time point, and when the color temperature change corresponding to the intelligent lamp is controlled according to the color temperature change function, the intelligent lamp is more suitable for the preference of the user and more suitable for the expected effect of the user.

For example, some users sleep deeply and need strong color temperature stimulation to wake up naturally, so that the whole color temperature variation process can be set higher according to their own preference. For another example, some users may sleep more lightly and wake up naturally with a slight color temperature stimulus, so that the whole color temperature variation process can be set lower according to their own preference.

Optionally, in some possible implementations of the present application, the S202 may include S2021 to S2023, which are specifically as follows:

s2021: and acquiring a wakeup starting time and a wakeup ending time.

S2022: the method comprises the steps of obtaining a plurality of first time points between a wakeup start time and a wakeup end time, and obtaining a color temperature corresponding to each first time point.

For example, the data of the wake-up start time, the wake-up end time, the number of first time points between the wake-up start time and the wake-up end time, the color temperature corresponding to each first time point, the color temperature corresponding to the wake-up start time point, and the color temperature corresponding to the wake-up end time may be pre-counted data more suitable for most users.

For example, data such as getting-up time, getting-up duration, and receiving condition of color temperature of getting-up time of a plurality of users are obtained in advance through market research, network questionnaire, practice, etc., and data such as wake-up start time, wake-up end time, a plurality of first time points between wake-up start time and wake-up end time, color temperature corresponding to each first time point, color temperature corresponding to wake-up start time point, and color temperature corresponding to wake-up end time suitable for most users are determined.

S2023: and fitting to generate a color temperature change function according to the awakening start time, the awakening end time, each first time point and the color temperature corresponding to each first time point.

And selecting any function from the prototype of the color temperature change function, substituting the data of the awakening start time, the awakening end time, each first time point, the color temperature corresponding to each first time point and the like into the selected function, and fitting to generate the color temperature change function.

For example, the data of the wake-up start time, the wake-up end time, a plurality of first time points between the wake-up start time and the wake-up end time, the color temperature corresponding to each first time point, the color temperature corresponding to the wake-up start time point, and the color temperature corresponding to the wake-up end time are substituted into the sigmoid curve, and the color temperature change function based on the sigmoid curve is obtained through calculation.

Optionally, in some possible implementation manners of the present application, no matter what the finally constructed color temperature change function is, the color temperature change function may be adjusted according to a wakeup start time, a wakeup end time, and a preset wakeup duration defined by a user. For example, a section of curve matched with the user-defined wake-up start time and wake-up end time can be intercepted from a curve drawn according to the color temperature change function according to the user-defined wake-up start time and wake-up end time, and the color temperature change corresponding to the intelligent lamp is controlled in the actual process by taking the intercepted section of curve as the reference. The description is given for illustrative purposes only and is not intended to be limiting.

In the implementation mode, due to the fact that the data for constructing the color temperature change function are collected in advance, the final color temperature change function can be obtained only by adjusting the awakening start time, the awakening end time and the preset awakening duration defined by the user, the speed for constructing the color temperature change function is improved, the user does not need to wait too long time when using the intelligent lamp for the first time, and then user experience is improved.

Fig. 3a to 3c are schematic diagrams of the color temperature change function shown in the present application. The color temperature change functions shown in fig. 3a have time on the abscissa and color temperature on the ordinate, and the three curves in fig. 3a are, from left to right and from top to bottom, a fitted polynomial curve 1, an exponential curve, and a polynomial curve 2.

A plurality of color temperature variation functions as shown in fig. 3b, the abscissa represents time, and the ordinate represents color temperature, and the two curves in fig. 3b are respectively a fitted linear curve and a sigmoid curve.

The color temperature change function shown in fig. 3c has the abscissa representing time and the ordinate representing color temperature, and the curve in fig. 3c is a fitted power function curve.

In the plurality of color temperature change functions shown in fig. 3a to 3c, the color temperature is continuously increased with time. Illustratively, the initial color temperature range of the color temperature variation functions may be 1500K-3200K, and the final color temperature range may be 3700K-7000K. The description is given for illustrative purposes only and is not intended to be limiting.

S203: a luminous flux variation function is constructed.

Exemplarily, constructing the light flux variation function requires a wake-up start time and a wake-up end time, several second time points between the wake-up start time and the wake-up end time, and a light flux corresponding to each second time point. The luminous flux corresponding to the wake-up start time point and the luminous flux corresponding to the wake-up end time point may also be included.

The prototype of the luminous flux variation function may be a linear variation function, a polynomial curve, an S-shaped curve, an exponential curve, a power curve, a logarithmic curve, or the like, and is not limited as long as it is a growth function.

The plurality of second time points between the awakening start time and the awakening end time, the luminous flux corresponding to each second time point, the luminous flux corresponding to the awakening start time point and the luminous flux corresponding to the awakening end time can be defined by a user.

For example, the user-defined wake-up start time is 7. The user wants a luminous flux of 0lm (unit: lumen) at 7. Several second points in time were chosen, respectively 7, 10, 7, 15, 7, 20, 7.

Taking a linear variation function as an example, the light fluxes at the time points and the time points are substituted into the linear variation function, and the coefficient of the linear variation function is calculated, so as to obtain the light flux variation function based on the linear variation function.

It should be noted that the user-defined luminous flux may be a luminous flux variation range. For example, the luminous flux range at a certain point of time is set to 0lm to 20lm, 40lm to 50lm, or the like. The smaller the time interval of each selected time point is, the more accurate the constructed luminous flux change function is. Therefore, when the luminous flux change corresponding to the intelligent lamp is controlled according to the luminous flux change function, the expected effect of the user is better met.

In the above manner, the light flux change function is constructed by using the user-defined second time points and the data such as the light flux corresponding to each second time point, and when the light flux change corresponding to the intelligent lamp is controlled according to the light flux change function, the intelligent lamp is more suitable for the preference of the user and better meets the expected effect of the user.

For example, some users sleep deeply and need strong light stimulation to wake up naturally, so that the whole light flux variation process can be set higher according to their own preference. For another example, some users sleep shallowly and can wake up naturally only by a slight light stimulus, so that the whole light flux variation process can be set to be lower according to their own preference.

Optionally, in some possible implementations of the present application, S203 may include S2031 to S2033, which are as follows:

s2031: and acquiring a wakeup starting time and a wakeup ending time.

S2032: acquiring a plurality of second time points between the awakening start time and the awakening end time, and acquiring the luminous flux corresponding to each second time point.

Illustratively, the data of the wake-up start time, the wake-up end time, a number of second time points between the wake-up start time and the wake-up end time, the light flux corresponding to each second time point, the light flux corresponding to the wake-up start time point, and the light flux corresponding to the wake-up end time may be pre-counted data more suitable for most users.

For example, data such as getting-up time, getting-up duration, and receiving condition of light flux when getting-up of a plurality of users are obtained in advance through market research, network questionnaire, practice, and the like, and data such as wake-up start time, wake-up end time, a plurality of second time points between the wake-up start time and the wake-up end time, light flux corresponding to each second time point, light flux corresponding to the wake-up start time point, and light flux corresponding to the wake-up end time are determined from the data.

S2033: and fitting and generating a luminous flux change function according to the awakening start time, the awakening end time, each second time point and the luminous flux corresponding to each second time point.

And selecting any function from the prototype of the luminous flux change function, substituting the awakening start time, the awakening end time, the luminous flux at each second time point and the data of the luminous flux corresponding to each second time point into the selected function, and fitting to generate the luminous flux change function.

For example, the wake-up start time, the wake-up end time, a plurality of second time points between the wake-up start time and the wake-up end time, the light flux corresponding to each second time point, the light flux corresponding to the wake-up start time point, and the light flux corresponding to the wake-up end time are substituted into the S-shaped curve, and the light flux change function based on the S-shaped curve is calculated.

Optionally, in some possible implementation manners of the present application, no matter what the finally constructed light flux variation function is, the finally constructed light flux variation function may be adjusted according to the wake-up start time, the wake-up end time, and the preset wake-up duration defined by the user. For example, a section of curve matched with the user-defined wake-up start time and wake-up end time can be intercepted from a curve drawn according to the light flux change function according to the user-defined wake-up start time and wake-up end time, and the intercepted section of curve is taken as the reference to control the light flux change corresponding to the intelligent lamp in the actual process. This is merely an example and is not intended to be limiting.

In the implementation mode, due to the fact that the data for constructing the luminous flux variation function are collected in advance, the final luminous flux variation function can be obtained only by adjusting the awakening start time, the awakening end time and the preset awakening duration defined by the user, the speed for constructing the luminous flux variation function is increased, the user does not need to wait too long time when using the intelligent lamp for the first time, and user experience is improved.

Optionally, in a possible implementation manner, the sunrise time of the area where the user is located may also be automatically obtained by the intelligent lamp, a time point corresponding to a plurality of durations before sunrise is set as the wakeup start time, a time point corresponding to the moment of sunrise is set as the wakeup end time, and the final color temperature change function and the final luminous flux change function are adjusted according to the wakeup start time and the wakeup end time.

Alternatively, the user may set a preset wake-up time, and the wake-up start time is automatically adjusted according to the local sunrise time. For example, the user sets the preset wake-up time to be 0.5 hour, the wake-up start time is set to be 0.5 hour before sunrise, the intelligent lamp starts wake-up work 0.5 hour before sunrise after reading the local sunrise time, and wake-up at sunrise is finished.

Fig. 4a to 4c are diagrams illustrating the luminous flux variation function shown in the present application. As shown in fig. 4a, the abscissa of the plurality of luminous flux variation functions represents time, the ordinate represents luminous flux, and the three curves in fig. 4a are a fitted polynomial curve 1, an exponential curve, and a polynomial curve 2 in sequence from left to right and from top to bottom.

A plurality of luminous flux variation functions as shown in fig. 4b, the abscissa represents time, the ordinate represents luminous flux, and the two curves in fig. 4b are respectively a fitted logarithmic curve and a sigmoid curve.

As shown in fig. 4c, the abscissa represents time, and the ordinate represents luminous flux, and the two curves in fig. 4c are respectively a fitted linear variation curve and a power function curve.

In the plurality of luminous flux variation functions shown in fig. 4a to 4c, the luminous flux continuously increases with time. Illustratively, the initial luminous flux range of these luminous flux variation functions may be 0lm to 5lm, and the final luminous flux range may be 290lm to 300lm. The description is given for illustrative purposes only and is not intended to be limiting.

S204: if the current time is detected to reach the preset awakening time, controlling the color temperature corresponding to the target lamp to continuously increase within the preset awakening time through the color temperature change function; and controlling the luminous flux corresponding to the target lamp to continuously increase within the preset wake-up time through the luminous flux change function.

Illustratively, when it is detected that the current time reaches a wake-up start time included in the preset wake-up time, the intelligent lamp controls the color temperature of the target lamp (intelligent lamp) to slowly and continuously increase along with the time according to a change curve of time and color temperature in the color temperature change function until the current time reaches a wake-up end time included in the preset wake-up time. That is, the entire process of the change of the color temperature starts from the wake-up start time until the current time reaches the wake-up end time.

Illustratively, when it is detected that the current time reaches a wake-up start time included in the preset wake-up time, the intelligent lamp controls the luminous flux of the target lamp (the intelligent lamp) to slowly and continuously increase along with the time according to a variation curve of time and luminous flux in the luminous flux variation function until the current time reaches a wake-up end time included in the preset wake-up time. That is, the entire process of the change of the light flux starts from the wake-up start time until the current time reaches the wake-up end time.

The color temperature and luminous flux corresponding to the target lamp continuously increase within the preset awakening time, so that the color temperature of light emitted by the lamp and the brightness of the light are changed from weak to strong, the light is continuously and gradually enhanced in the whole awakening process, and the change process is closer to the change process of gradually enhancing the real sunlight.

It should be noted that S202 and S203 may be executed before S201, which is not limited.

In the above embodiment, the color temperature and the luminous flux corresponding to the target lamp are respectively controlled by the color temperature change function and the luminous flux change function to continuously increase in the preset wake-up time, so that the color temperature of the light emitted by the lamp and the brightness of the light are continuously and gradually increased in the whole wake-up process, the color temperature of the light and the brightness of the light are continuously and gently stimulated by the user, the user sleep state is more matched with the user, and the stimulated user gradually enters the light sleep state from the deep sleep state. Effectively prevent that the user from leading to the condition of uncomfortable and producing negative emotion because of receiving unexpected awakening stimulus, promoted intelligent awakening effect, be favorable to user's healthy.

Optionally, in a possible implementation manner, an exemplary embodiment of the present application provides an intelligent wake-up method, where the intelligent wake-up method may include: s301 to S305 are as follows:

s301: and acquiring the current time.

The implementation of step S201 in this embodiment is the same as the implementation of step S101, and reference may be made to the description in step S101, which is not repeated herein.

S302: and acquiring the geographic position information and the time information corresponding to the user.

The geographical location information is location information corresponding to a region where the user is located, and is also location information corresponding to a place where a target lamp (intelligent lamp) works. The geographical location information may include provinces, districts, counties, towns, etc. For example, the geographic location information corresponding to a certain user is a tombstone area in west-security city of shanxi province, a sub-county in yangan city of shanxi province, and the like. The time information may include season, date, etc.

And acquiring the current region of the user or the current region of the intelligent lamp in the network. The current date (year, month, day), the current season, and the current weather conditions are also acquired.

S303: and finding sunrise data matched with both the geographic position information and the time information.

Illustratively, a plurality of different regions are collected in advance, and sunrise data corresponding to different seasons and different times of the regions are collected in advance. And storing sunrise data corresponding to each region and different seasons in the database.

The sunrise data may include: the sunrise time of each region in different time and different seasons (including the time when the sun just appears and the time when the sun rises), a plurality of third time points in the sunrise process, the color temperature corresponding to each third time point, the illumination corresponding to each third time point, the luminous flux corresponding to each third time point, and the like. It is worth noting that the sunrise data is actually measured.

Illustratively, according to the geographic position information and the time information corresponding to the user, sunrise data matched with the geographic position information and the time information are searched in the database.

S304: and fitting according to the sunrise data to generate a fitting function.

The prototype of the fitting function may be a linear variation function, a polynomial curve, an exponential curve, or the like, as long as it is a growth function, which is not limited.

And selecting any one function from the prototype of the fitting function, and substituting the sunrise time, a plurality of third time points in the sunrise process, the color temperature corresponding to each third time point, the illumination corresponding to each third time point and other data into the selected function to generate the fitting function.

Or selecting any one function from the prototype of the fitting function, and substituting the sunrise time, a plurality of third time points in the sunrise process, the color temperature corresponding to each third time point, the luminous flux corresponding to each third time point and other data into the selected function to generate the fitting function.

Fig. 5 is a schematic diagram of a fitting function shown in the present application. The plurality of fitting functions shown in fig. 5 have the abscissa representing time, the ordinate representing illuminance values to the left and color temperature to the right.

The darker colored dots in fig. 5 are determined according to time and color temperature, and the dotted lines connecting the dots are used to indicate the fitted fitting function. The first fitting function from top to bottom of fig. 5 is a polynomial function, whose corresponding expression is:

y＝1.44E+05x2.00E+00-5.49E+04x+6.53E+03

the lighter dots in fig. 5 are determined according to time and illumination, and the dotted line connecting the dots is used to indicate the fitted function. The fitting function is also a polynomial function, and the corresponding expression is:

y＝5.03E-04e5.68E+01x

illustratively, an exponential function may also be fitted according to the time point and the illuminance, and the corresponding expression may be:

y＝-2.18E+06x2.00E+00+3.06E+06x-7.12E+05

the description is exemplary, and not limiting.

S305: and if the current time is detected to reach the preset awakening time, controlling the color temperature and the luminous flux corresponding to the target lamp to continuously increase within the preset awakening time through the fitting function.

Illustratively, when it is detected that the current time reaches a wake-up start time included in the preset wake-up time, the intelligent lamp controls the color temperature of the target lamp (the intelligent lamp) to slowly and continuously increase according to a change curve of time and color temperature in the fitting function along with the time until the current time reaches a wake-up end time included in the preset wake-up time.

Illustratively, when it is detected that the current time reaches the wake-up start time included in the preset wake-up time, the intelligent lamp controls the luminous flux of the target lamp (the intelligent lamp) to slowly and continuously increase along with the time of the change curve of the time and the luminous flux in the fitting function until the current time reaches the wake-up end time included in the preset wake-up time. And controlling the color temperature and luminous flux corresponding to the target lamp to continuously increase within a preset awakening time through the fitting function so as to awaken the user.

It should be noted that S302, S303, and S304 may be executed before S301, which is not limited.

In the above mode, the fitting function is generated according to the actual test data, and is closer to the change process of the gradual enhancement of the real sunlight, namely, the change of the color temperature of the light emitted by the lamp and the change of the brightness of the light are more similar to the change of the real sunlight, so that the stimulation of the color temperature of the light and the brightness of the light to the user is ensured to be continuous and mild, the stimulation is more matched with the sleep state of the user, and the user is stimulated to gradually enter the light sleep state from the deep sleep state. Effectively prevent that the user from leading to the condition of uncomfortable and producing negative emotion because of receiving unexpected awakening stimulus, promoted intelligent awakening effect, be favorable to user's healthy.

Optionally, in some possible implementation manners of the present application, after the generating the fitting function, the intelligent wake-up method provided by the present application may further include: and acquiring preference data of the user, and adjusting the fitting function according to the preference data.

Illustratively, the preference data may include a user-defined color temperature variation range, a luminous flux variation range, an illuminance variation range, a wake-up start time, a wake-up end time, a preset wake-up duration, and the like.

And after the preference data input by the user are acquired, substituting the preference data into the fitting function, and readjusting the fitting function.

For example, a user feels that a dynamically changing environment with high color temperature and high illumination can wake up sleep more effectively, improve alertness and stimulate emotion. Therefore, the user sets preference data specifically including, according to his/her comfort: the color temperature change range is 1800K-6500K, the luminous flux change range is 0lm-300lm, the preset awakening time is 30 minutes, and the awakening starting time is 6:00, wake-up end time 6:30.

and extracting a plurality of time nodes in the fitting function, readjusting the color temperature and the luminous flux corresponding to each time node according to preference data of a user, and regenerating the fitting function according to the adjusted color temperature and the adjusted luminous flux corresponding to each time node.

For another example, a user feels that a dynamically changing medium color temperature and medium illumination environment can wake up sleep more effectively and stimulate emotions. The preference data set by the user according to his comfort therefore specifically includes: the color temperature variation range is 1800K-4000K, the luminous flux variation range is 0lm-150lm, the preset awakening time is 40 minutes, and the awakening starting time is 6:00, wake-up end time 6:40.

and extracting a plurality of time nodes in the fitting function, readjusting the color temperature and the luminous flux corresponding to each time node according to preference data of a user, and regenerating the fitting function according to the adjusted color temperature and the adjusted luminous flux corresponding to each time node.

For another example, the preference data of a certain user specifically includes: the color temperature change range is 1800K-6500K, the luminous flux change range is 0-300lux, the preset wake-up time is 30 minutes, and the wake-up start time is 6:00, wake-up end time 6:30.

and extracting 19 time nodes in the fitting function, and readjusting the color temperature and the illumination corresponding to each time node according to the preference data of the user. The color temperature and the illuminance corresponding to the adjusted 19 time nodes are shown in table 1.

The color temperature (CCT) and the illuminance at each time node shown in table 1 are merely examples, and are not limited thereto.

For example, the fitting function may be regenerated according to the adjusted color temperature and illumination intensity corresponding to each time node.

Table 1 is as follows:

node point	Time	CCT	Illuminance of light
				Node 1	6:00:00	1817	1
Node 2	6:01:40	1950	18
				Node 3	6:03:20	2099	34
Node 4	6:05:00	2263	51
				Node 5	6:06:40	2442	68
Node 6	6:08:20	2637	85
				Node 7	6:10:00	2846	102
Node 8	6:11:40	3072	119
				Node 9	6:13:20	3312	135
Node 10	6:15:00	3568	152
				Node 11	6:16:40	3840	169
Node 12	6:18:20	4126	186
				Node 13	6:20:00	4428	203
Node 14	6:21:40	4746	220
				Node 15	6:23:30	4945	240
Node 16	6:25:00	5426	254
				Node 17	6:26:40	5790	271
Node 18	6:28:20	6169	288
				Node 19	6:30:00	6563	305

Fig. 6 is a schematic diagram of the adjusted fitting function shown in the present application. Two adjusted fitting functions as shown in fig. 6, the abscissa represents time, the left of the ordinate represents color temperature, and the right represents illuminance. Fig. 6 shows a first adjusted fitting function (represented by a curve) from top to bottom and from left to right as a polynomial function corresponding to illuminance, and the corresponding expression is:

y＝7.34E+03x2.00E+00+1.08E+04x-3.16E+03

fig. 6 shows a second adjusted fitting function (represented by a straight line) from top to bottom and from left to right as a polynomial function corresponding to color temperature, where the corresponding expression is:

y＝6E+06x2.00E+00-3E+06x+332644

among the above-mentioned embodiment, according to the fitting function that different users ' preference adjustment belongs to it, when changing according to the colour temperature, luminous flux, illuminance that the fitting function control intelligence lamps and lanterns after the adjustment correspond, more laminating user's hobby more accords with user's anticipated effect, awakening the mode diversification, intellectuality of awakening up, has promoted the effect of awakening up.

Optionally, in an implementation scenario, the current may be controlled to further control a change of a color temperature and a luminous flux corresponding to the intelligent lamp. Illustratively, the color temperature increase is controlled by the proportion of different branch currents, and the luminous flux increase is controlled by the magnitude of the power supply output current.

Optionally, in a possible implementation, when the intelligent luminaire starts to be used, a user may select the type of the wake-up function by himself, for example, select the color temperature change function and the luminous flux change function, or select the fitting function. The intelligent lamp realizes awakening according to the type of the awakening function selected by the user.

Optionally, when the user selects the fitting function and uses the intelligent lamp for the first time, the user needs to patiently wait for the intelligent lamp to acquire the geographical position information, the time information and the sunrise data corresponding to the user, and the fitting function is generated according to the sunrise data in a fitting manner. Over time, the fit function may be continually optimized. For example, when the season changes, thereby affecting the sunrise data, the fitting function is also adjusted according to the updated sunrise data.

Referring to fig. 7, fig. 7 is a schematic diagram of an intelligent wake-up device according to an embodiment of the present application. The intelligent wake-up device includes units for executing the steps in the embodiments corresponding to fig. 1 to fig. 2. Please refer to the related description of the embodiments in fig. 1-2. For convenience of explanation, only the portions related to the present embodiment are shown. Referring to fig. 7, including:

an obtaining unit 310, configured to obtain a current time;

a control unit 320, configured to control, through a wake-up function, a color temperature and a luminous flux corresponding to the target lamp to continuously increase within a preset wake-up time if it is detected that the current time reaches a preset wake-up time, where the color temperature and the luminous flux corresponding to the target lamp continuously increase within the preset wake-up time for waking up a user.

Optionally, the wake-up function includes a color temperature change function and a luminous flux change function, and the intelligent wake-up device further includes:

a first construction unit for constructing the color temperature change function;

a second construction unit for constructing the luminous flux variation function;

the control unit 320 is specifically configured to:

if the current time is detected to reach the preset awakening time, controlling the color temperature corresponding to the target lamp to continuously increase within the preset awakening time through the color temperature change function;

and controlling the luminous flux corresponding to the target lamp to continuously increase within the preset awakening time through the luminous flux change function.

Optionally, the preset wake-up time includes a wake-up start time and a wake-up end time, and the first constructing unit is specifically configured to:

acquiring the awakening starting time and the awakening ending time;

acquiring a plurality of first time points between the awakening start time and the awakening end time, and acquiring the color temperature corresponding to each first time point;

and fitting to generate the color temperature change function according to the awakening start time, the awakening end time, each first time point and the color temperature corresponding to each first time point.

Optionally, the second building unit is specifically configured to:

acquiring the awakening starting time and the awakening ending time;

acquiring a plurality of second time points between the awakening start time and the awakening end time, and acquiring the luminous flux corresponding to each second time point;

and fitting to generate the luminous flux change function according to the awakening start time, the awakening end time, each second time point and the luminous flux corresponding to each second time point.

Optionally, the wake-up function includes a fitting function, and the smart wake-up apparatus further includes a first fitting unit, where the first fitting unit is configured to:

acquiring geographic position information and time information corresponding to the user;

searching sunrise data matched with the geographical position information and the time information;

fitting and generating the fitting function according to the sunrise data;

the control unit 320 is further configured to:

and if the current time is detected to reach the preset awakening time, controlling the color temperature and the luminous flux corresponding to the target lamp to continuously increase within the preset awakening time through the fitting function.

Optionally, the sunrise data includes a plurality of third time points, a color temperature corresponding to each of the third time points, and an illuminance corresponding to each of the third time points.

Optionally, the smart wake-up apparatus further includes a second fitting unit, and the second fitting unit is configured to:

acquiring preference data of the user, wherein the preference data comprises a color temperature change range and a luminous flux change range customized by the user;

adjusting the fitting function according to the preference data.

Referring to fig. 8, fig. 8 is a schematic diagram of an intelligent wake-up terminal according to another embodiment of the present application. As shown in fig. 8, the terminal 4 of this embodiment includes: a processor 40, a memory 41 and a computer program 42 stored in said memory 41 and executable on said processor 40. The processor 40, when executing the computer program 42, implements the steps in the above-mentioned various embodiments of the smart wake-up method, such as S101 to S102 shown in fig. 1. Alternatively, the processor 40, when executing the computer program 42, implements the functions of the units in the embodiments, such as the functions of the units 310 to 320 shown in fig. 7.

Illustratively, the computer program 42 may be divided into one or more units, which are stored in the memory 41 and executed by the processor 40 to accomplish the present application. The one or more units may be a series of computer instruction segments capable of performing specific functions, which are used to describe the execution of the computer program 42 in the terminal 4. For example, the computer program 42 may be divided into an acquisition unit and a control unit, each unit functioning specifically as described above.

The terminal may include, but is not limited to, a processor 40, a memory 41. It will be appreciated by those skilled in the art that fig. 8 is only an example of a terminal 4 and does not constitute a limitation of the terminal, and that it may include more or less components than those shown, or some components may be combined, or different components, for example, the terminal may also include input output terminals, network access terminals, buses, etc.

The Processor 40 may be a Central Processing Unit (CPU), other general purpose Processor, a Digital Signal Processor (DSP), an Application Specific Integrated Circuit (ASIC), an off-the-shelf Programmable Gate Array (FPGA) or other Programmable logic device, discrete Gate or transistor logic, discrete hardware components, etc. A general purpose processor may be a microprocessor or the processor may be any conventional processor or the like.

The memory 41 may be an internal storage unit of the terminal, such as a hard disk or a memory of the terminal. The memory 41 may also be an external storage terminal of the terminal, such as a plug-in hard disk, a Smart Media Card (SMC), a Secure Digital (SD) Card, a Flash memory Card (Flash Card), and the like, provided on the terminal. Further, the memory 41 may also include both an internal storage unit of the terminal and an external storage terminal. The memory 41 is used for storing the computer instructions and other programs and data required by the terminal. The memory 41 may also be used to temporarily store data that has been output or is to be output.

The embodiments of the present application further provide a computer storage medium, where the computer storage medium may be nonvolatile or volatile, and the computer storage medium stores a computer program, and the computer program is executed by a processor to implement the steps in the foregoing intelligent wake-up method embodiments.

The present application further provides a computer program product, which when running on a terminal, causes the terminal to execute the steps in the above-mentioned various embodiments of the intelligent wake-up method.

An embodiment of the present application further provides a chip or an integrated circuit, where the chip or the integrated circuit includes: and the processor is used for calling and running the computer program from the memory so that the terminal provided with the chip or the integrated circuit executes the steps in each intelligent awakening method embodiment.

It will be apparent to those skilled in the art that, for convenience and brevity of description, only the above-mentioned division of the functional units and modules is illustrated, and in practical applications, the above-mentioned function distribution may be performed by different functional units and modules according to needs, that is, the internal structure of the apparatus is divided into different functional units or modules, so as to perform all or part of the functions described above. Each functional unit and module in the embodiments may be integrated in one processing unit, or each unit may exist alone physically, or two or more units are integrated in one unit, and the integrated unit may be implemented in a form of hardware, or in a form of software functional unit. In addition, specific names of the functional units and modules are only for convenience of distinguishing from each other, and are not used for limiting the protection scope of the present application. The specific working processes of the units and modules in the system may refer to the corresponding processes in the foregoing method embodiments, and are not described herein again.

In the above embodiments, the descriptions of the respective embodiments have respective emphasis, and reference may be made to the related descriptions of other embodiments for parts that are not described or illustrated in a certain embodiment.

Those of ordinary skill in the art will appreciate that the various illustrative elements and algorithm steps described in connection with the embodiments disclosed herein may be implemented as electronic hardware or combinations of computer software and electronic hardware. Whether such functionality is implemented as hardware or software depends upon the particular application and design constraints imposed on the implementation. Skilled artisans may implement the described functionality in varying ways for each particular application, but such implementation decisions should not be interpreted as causing a departure from the scope of the present application.

The above-mentioned embodiments are only used for illustrating the technical solutions of the present application, and not for limiting the same; although the present application has been described in detail with reference to the foregoing embodiments, it should be understood by those of ordinary skill in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some technical features may be equivalently replaced; such modifications and substitutions do not cause the essential features of the corresponding technical solutions to depart from the spirit scope of the technical solutions of the embodiments of the present application, and are intended to be included within the scope of the present application.

Claims (10)

1. A smart wake-up method, comprising:

acquiring current time;

and if the current time is detected to reach the preset awakening time, controlling the color temperature and the luminous flux corresponding to the target lamp to continuously increase in the preset awakening time through the awakening function, wherein the color temperature and the luminous flux corresponding to the target lamp continuously increase in the preset awakening time for awakening the user.

2. The smart wake-up method according to claim 1, wherein the wake-up function includes a color temperature variation function and a luminous flux variation function, and the smart wake-up method further includes, before controlling the color temperature and the luminous flux corresponding to the target luminaire to continuously increase within a preset wake-up time period through the wake-up function if it is detected that the current time reaches a preset wake-up time:

constructing the color temperature change function;

constructing the luminous flux variation function;

if the current time is detected to reach the preset awakening time, controlling the color temperature and the luminous flux corresponding to the target lamp to continuously increase within the preset awakening time through the awakening function, and the method comprises the following steps:

if the current time is detected to reach the preset awakening time, controlling the color temperature corresponding to the target lamp to continuously increase within the preset awakening time through the color temperature change function;

and controlling the luminous flux corresponding to the target lamp to continuously increase within the preset awakening time through the luminous flux change function.

3. The smart wake-up method according to claim 2, wherein the preset wake-up time comprises a wake-up start time and a wake-up end time, and the constructing the color temperature change function comprises:

acquiring the awakening starting time and the awakening ending time;

acquiring a plurality of first time points between the awakening start time and the awakening end time, and acquiring the color temperature corresponding to each first time point;

and fitting to generate the color temperature change function according to the awakening starting time, the awakening ending time, each first time point and the color temperature corresponding to each first time point.

4. The smart wake-up method according to claim 3, wherein the constructing the luminous flux variation function comprises:

acquiring the awakening starting time and the awakening ending time;

acquiring a plurality of second time points between the awakening start time and the awakening end time, and acquiring the luminous flux corresponding to each second time point;

and fitting to generate the luminous flux change function according to the awakening start time, the awakening end time, each second time point and the luminous flux corresponding to each second time point.

5. The smart wake-up method according to claim 1, wherein the wake-up function includes a fitting function, and the smart wake-up method further includes, before controlling the color temperature and the luminous flux corresponding to the target luminaire to continuously increase within a preset wake-up time period through the wake-up function if it is detected that the current time reaches a preset wake-up time, the smart wake-up method further includes:

acquiring geographic position information and time information corresponding to the user;

searching sunrise data matched with the geographical position information and the time information;

fitting and generating the fitting function according to the sunrise data;

if it is detected that the current time reaches the preset wake-up time, controlling the color temperature and the luminous flux corresponding to the target lamp to continuously increase within the preset wake-up time through the wake-up function, including:

and if the current time is detected to reach the preset awakening time, controlling the color temperature and the luminous flux corresponding to the target lamp to continuously increase within the preset awakening time through the fitting function.

6. The smart wake-up method according to claim 5, wherein after the fitting function is generated from the sunrise data fitting, the smart wake-up method further comprises:

acquiring preference data of the user, wherein the preference data comprises a color temperature change range and a luminous flux change range customized by the user;

adjusting the fitting function according to the preference data.

7. The smart wake-up method according to claim 5, wherein the sunrise data comprises a number of third time points, a color temperature corresponding to each of the third time points, and an illumination corresponding to each of the third time points.

8. An intelligent wake-up device, comprising:

an acquisition unit configured to acquire a current time;

and the control unit is used for controlling the color temperature and the luminous flux corresponding to the target lamp to continuously increase in the preset wake-up time through the wake-up function if the current time is detected to reach the preset wake-up time, and the color temperature and the luminous flux corresponding to the target lamp to continuously increase in the preset wake-up time for waking up the user.

9. An intelligent wake-up terminal comprising a memory, a processor and a computer program stored in the memory and executable on the processor, characterized in that the processor implements the method according to any of claims 1 to 7 when executing the computer program.

10. A computer-readable storage medium, in which a computer program is stored which, when being executed by a processor, carries out the method according to any one of claims 1 to 7.

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