阅读说明：本技术 助眠方法、助眠系统及具有该助眠系统的移动体 (Sleep aiding method, sleep aiding system and moving body with sleep aiding system ) 是由 王岩 于 2018-08-03 设计创作，主要内容包括：本申请涉及一种助眠方法、助眠系统及具有该助眠系统的移动体,用于移动的可封闭空间内,该封闭空间内布置有若干光源和座位,封闭空间周围设置有电子玻璃,所述助眠方法包括步骤：设定各光源于休息模式时的第一光源亮度值；接收进入休息模式信号；关闭电子玻璃；展开座位；以及分别逐渐调整各光源的亮度,以使各光源分别达到各自所设定的第一光源亮度值,因此,能为用户提供有助于睡眠的灯光,且能提供自然的休息环境。(The application relates to a sleep-aiding method, a sleep-aiding system and a moving body with the sleep-aiding system, which are used in a movable closed space, wherein a plurality of light sources and seats are arranged in the closed space, electronic glass is arranged around the closed space, and the sleep-aiding method comprises the following steps: setting a first light source brightness value of each light source in a rest mode; receiving a signal for entering a rest mode; closing the electronic glass; unfolding the seat; and gradually adjusting the brightness of each light source respectively to enable each light source to reach the first light source brightness value set by each light source respectively, so that the light helpful for sleeping can be provided for the user, and a natural rest environment can be provided.)

1. A sleep-aiding method is used in a movable closed space, a plurality of light sources and seats are arranged in the closed space, and a plurality of pieces of electronic glass are arranged around the closed space, and is characterized by comprising the following steps:

respectively setting the brightness value of each light source in a rest mode;

receiving a signal for entering a rest mode;

closing the electronic glass;

deploying the seat; and

and gradually adjusting the brightness of each light source respectively to enable each light source to reach the preset first light source brightness value respectively.

2. A sleep-aiding method as claimed in claim 1, wherein the first light source brightness value is set in the light source control module.

3. A sleep-aiding method as claimed in claim 1, wherein when the first light source brightness value of each light source in the rest mode is set, the first light source color temperature value of each light source in the rest mode and the first transmittance value of each electronic glass in the rest mode and the first electronic glass color temperature value of the color to be presented are also set, and when the brightness of each light source is gradually adjusted, the color temperature of each light source and the transmittance of each electronic glass and the color temperature of the color to be presented are also adjusted, respectively, so that the color temperature of each light source also reaches the respective first light source color temperature value, the transmittance of each electronic glass reaches the respective set first transmittance value, and the color to be presented of each electronic glass reaches the respective set first electronic glass color temperature value.

4. A sleep-aiding method is used in a movable closed space, a plurality of light sources and seats are arranged in the closed space, and electronic glass is arranged around the closed space, and is characterized by comprising the following steps:

respectively setting a plurality of preset positions on the inner side of the electronic glass and in the vehicle, and setting a first environment brightness value and a first environment color temperature value in a rest mode;

receiving a signal for entering a rest mode;

monitoring a second environment brightness value and a second environment light color value of light on the outer side of the electronic glass, and calculating a first transmittance value of the electronic glass according to a difference value between the second environment brightness value and the first environment brightness value; calculating a first electronic glass color temperature value of the color presented by the electronic glass according to the difference value of the second environment light color value and the first environment light color value; respectively adjusting the light transmittance and the presented color of the electronic glass to enable the light transmittance of each electronic glass to respectively reach a respective first transmittance value and enable the color presented by each electronic glass to respectively reach a first electronic glass color temperature value;

deploying the seat;

monitoring a current second environment brightness value and a current second environment light color value of each preset position in the vehicle, respectively taking the difference value between the second environment brightness value and the first environment brightness value as a first light source brightness value of each light source, and taking the difference value between the second environment light color value and the first environment light color value as a first light source color temperature value of each light source; and gradually adjusting the brightness and the color temperature of each light source respectively to enable each light source to reach the respectively set first light source brightness value and first light source color temperature value.

5. A sleep aid method according to claim 4, wherein the first ambient brightness value and the first ambient color temperature value are obtained from one or more received photographs of the daily sleeping environment or are preset by the user.

6. A sleep-aid system, comprising:

a seat provided in the mobile body;

a wall portion disposed around the seat;

a plurality of light sources, and a plurality of pieces of electronic glass arranged on the wall;

a seat control module that controls the seat to deploy and stow;

the light source control module controls the light sources to emit light;

the electronic glass control module is used for adjusting the light transmittance of the electronic glasses; and

and the control part enables the electronic glass control module to adjust the light transmittance of the electronic glass and the seat control module to unfold the seat after receiving a signal of entering a rest mode, and the light source control module respectively adjusts the brightness of each light source.

7. A sleep aid system according to claim 6, wherein: the control part also enables the light source control module to adjust the color temperature of each light source, or enables the electronic glass control module to adjust the color temperature of the colors presented by the electronic glass.

8. A sleep aid system according to claim 6, wherein: the sleep-assisting system further comprises an optical sensor part, wherein the optical sensor part monitors the brightness value and the light color value of the current environment and provides the monitored brightness value and the monitored light color value for the control part, so that the control part adjusts the light transmittance of the electronic glass, the color temperature of the color presented by the electronic glass and the brightness and the color temperature of each light source according to the difference value between the brightness value of the current environment and the brightness value of the expected environment and the difference value between the color temperature value of the current environment and the color temperature value of the expected environment.

9. A sleep aid system according to claim 8, wherein: the sleep-aiding system further comprises a detection part, and the detection part acquires the expected environment brightness value and the expected environment color temperature value according to one or more received photos of the daily sleep environment.

10. A moving body having the sleep-assisting system according to any one of claims 6 to 9.

Technical Field

The application relates to the technical field of automobile interaction, in particular to a sleep-assisting method and a sleep-assisting system which can be applied to an automobile and a moving body with the sleep-assisting system.

Background

With the rapid development of automobile technology, automobiles become more intelligent, and ordinary users can go out more freely through the automobiles.

In addition, the development of the existing roads cannot keep up with the growth of automobiles, the automobiles are often blocked in every holiday in large cities and high-speed roads, and people driving for a long distance often feel tired.

However, the existing vehicles cannot provide a good rest environment, so that the rest in the vehicles is still a difficult problem, and the travel quality is seriously influenced.

Disclosure of Invention

An object of the present application is to provide a sleep-aiding method, a sleep-aiding system, and a moving body having the sleep-aiding system.

The application provides a sleep-aiding method, which is used in a movable closed space, wherein a plurality of light sources and seats are arranged in the closed space, and a plurality of pieces of electronic glass are arranged around the closed space, and the sleep-aiding method comprises the following steps: respectively setting the brightness value of each light source in a rest mode; receiving a signal for entering a rest mode; closing the electronic glass; deploying the seat; and gradually adjusting the brightness of each light source respectively to enable each light source to reach the set first light source brightness value respectively.

The first light source brightness value is set in the light source control module.

In an embodiment, when the first light source brightness value of each light source in the rest mode is set, the first light source color temperature value of each light source in the rest mode, the first transmittance value of each electronic glass in the rest mode, and the color temperature value of the first electronic glass in the presented color are also set, and when the brightness of each light source is gradually adjusted, the color temperature of each light source and the transmittance and the presented color temperature of each electronic glass are also adjusted, so that the color temperature of each light source also reaches the respective set first light source color temperature value, the transmittance of each electronic glass reaches the respective set first transmittance value, and the color presented by each sub-glass reaches the respective set first electronic glass color temperature value.

The application also provides a sleep-aiding method, which is used in a movable closed space, a plurality of light sources and seats are arranged in the closed space, electronic glass is arranged around the closed space, and the sleep-aiding method comprises the following steps: respectively setting a plurality of preset positions on the inner side of the electronic glass and in the vehicle, and setting a first environment brightness value and a first environment color temperature value in a rest mode;

receiving a signal for entering a rest mode;

monitoring a second environment brightness value and a second environment light color value of light on the outer side of the electronic glass, and calculating a first transmittance value of the electronic glass according to a difference value between the second environment brightness value and the first environment brightness value; calculating a first electronic glass color temperature value of the color presented by the electronic glass according to the difference value of the second environment light color value and the first environment light color value; respectively adjusting the light transmittance and the presented color of the electronic glass to enable the light transmittance of each electronic glass to respectively reach a respective first transmittance value and enable the color presented by each electronic glass to respectively reach a first electronic glass color temperature value;

deploying the seat;

monitoring a current second environment brightness value and a current second environment light color value of each preset position in the vehicle, respectively taking the difference value between the second environment brightness value and the first environment brightness value as a first light source brightness value of each light source, and taking the difference value between the second environment light color value and the first environment light color value as a first light source color temperature value of each light source; and gradually adjusting the brightness and the color temperature of each light source respectively to enable each light source to reach the first light source brightness value and the first light source color temperature value which are set respectively.

In an embodiment, the first environment brightness value and the first environment color temperature value are obtained according to one or more received pictures of the daily sleeping environment, or are preset by a user.

The present application further provides a sleep-aid system comprising: a seat provided in the mobile body; a wall portion disposed around the seat; a plurality of light sources, a plurality of pieces of electronic glass, and a plurality of light sensors arranged on the wall portion; a seat control module that controls the seat to deploy and stow; the light source control module controls the light sources to emit light; the electronic glass control module is used for adjusting the light transmittance of the electronic glasses; and the control part enables the electronic glass control module to adjust the light transmittance of the electronic glass and the seat control module to unfold the seat after receiving the signal of entering the rest mode, and the light source control modules respectively adjust the brightness of the light sources.

In one embodiment, the control unit further causes the light source control module to adjust a color temperature of each light source, or further causes the electronic glass control module to adjust a color temperature of a color presented by the plurality of pieces of electronic glass.

In an embodiment, the sleep-assisting system further includes a light sensor portion, where the light sensor portion monitors a brightness value and a light color value of a current environment and provides the monitored brightness value and light color value to the control portion, so that the control portion adjusts a light transmittance of the electronic glass, a color temperature of a color presented by the electronic glass, and brightness and color temperature of each of the light sources according to a difference between the brightness value of the current environment and a desired brightness value of the environment and a difference between the light color value of the current environment and a desired color value of the environment.

In an embodiment, the sleep-aiding system further includes a detection portion, and the detection portion obtains the expected environment brightness value and the expected environment color temperature value according to one or more received pictures of the daily sleep environment.

The present application further provides a mobile body having any one of the sleep-assisting systems described above.

The sleep-assisting method, the sleep-assisting system and the moving body with the sleep-assisting system gradually weaken light for the user according to expected values of brightness and color temperature of the light source of the user, so that the user can sleep.

The foregoing description is only an overview of the technical solutions of the present application, and in order to make the technical means of the present application more clearly understood, the present application may be implemented in accordance with the content of the description, and in order to make the above and other objects, features, and advantages of the present application more clearly understood, the following preferred embodiments are described in detail with reference to the accompanying drawings.

Drawings

Fig. 1 is a schematic flow chart of a sleep-aiding method according to a first embodiment of the present application.

Fig. 2 is a schematic flow chart of a sleep-aiding method according to a second embodiment of the present application.

Fig. 3 is a schematic flow chart of a sleep-aiding method according to a third embodiment of the present application.

Fig. 4 is a schematic structural diagram of a sleep-assisting system according to a fourth embodiment of the present application.

Fig. 5 is a schematic signal flow diagram according to a fourth embodiment of the present application.

Detailed Description

To further explain the technical means and effects of the present application for achieving the intended application, the following detailed description of embodiments, methods, steps, structures, features and effects of the sleep-assisting method, the sleep-assisting system and the moving body with the sleep-assisting system according to the present application will be made with reference to the accompanying drawings and preferred embodiments.

The foregoing and other technical matters, features and effects of the present application will be apparent from the following detailed description of preferred embodiments, which is to be read in connection with the accompanying drawings. While the present application is susceptible to embodiment and specific details, specific reference will now be made in detail to the present disclosure for the purpose of illustrating the general principles of the invention.

The sleep-aiding method of the present application is described below with reference to fig. 1, 2, and 3.

Fig. 1 is a schematic flow chart of a sleep-aiding method according to a first embodiment of the present application. The sleep-aiding method is used in a movable closed space, a plurality of light sources and seats are arranged in the closed space, and electronic glass is arranged around the closed space. The sleep-aiding method of the embodiment comprises the following steps:

step S20: respectively setting the brightness value of each light source in a rest mode; setting the electronic glass, wherein the first light transmittance value is set when the electronic glass is in a rest mode;

specifically, a light source control module is configured, and a storage unit is set in the light source control module and used for storing the first light source brightness value. Similarly, an electronic glass control module is also provided, in which a memory unit is provided for storing the first light transmittance value. In this embodiment, the first light source brightness value is initially set to be that the light source is completely turned off, and the first transmittance value is initially set to be that the glass is completely opaque. In other embodiments, the first light source brightness value is initially set to the light source not being completely off, e.g., the first brightness value is set to 10% of the maximum brightness value of the light source; the first transmittance value is initially set to a value at which the electronic glass is partially transparent, e.g., the first transmittance value is 20%.

Step S40: receiving a signal for entering a rest mode;

step S60: closing the electronic glass;

specifically, the electronic glass is, for example, an electronic glass window of an automobile. When a signal sent by a user for entering a rest mode is received, the system adjusts the light transmittance of the electronic glass to the minimum value, namely, the electronic glass is closed. The manner in which the user inputs the signal to enter the rest mode may be, but is not limited to: the user inputs the information through a physical device, and the physical device can be an entity key or a mobile terminal carried by the user; user input via voice, etc.

Step S70: unfolding the seat;

in particular, the seat is deployed to a form that prevents falling. In other embodiments, the seat may also be deployed in a swing mode, a massage mode, etc. suitable for use by a child.

Step S80: gradually adjusting the brightness of each light source respectively to enable each light source to reach the brightness value of the first light source set by each light source respectively;

specifically, the light source control module is provided with a switch circuit and a timing circuit which are connected with a power supply circuit, a trigger circuit connected with the timing circuit, and a dimming circuit connected with the trigger circuit. The dimming circuit is simultaneously connected with the switching circuit. The light sources are respectively connected between the trigger circuit and the timing circuit, and the dimming circuit performs brightness gradient adjustment on the brightness of each light source. Thus, the light source gradually becomes dark from bright as time goes on, and people are prompted to fall asleep. When the first brightness value is set to be completely extinguished, the light source is gradually extinguished from being lit.

More specifically, the power control module, the seat control module and the curtain control module are all connected to the same control part in the mobile body, and the control part receives a signal of entering a rest mode of a user at the same time. When the control part receives the signal of entering the rest mode, the power supply control module, the seat control module and the electronic glass control module are respectively instructed to complete different instructions.

Fig. 2 is a schematic flow chart of a sleep-aiding method according to a second embodiment of the present application. The sleep-aiding method is used in a movable closed space, a plurality of light sources and seats are arranged in the closed space, and electronic glass is arranged around the closed space. The sleep-aiding method of the embodiment comprises the following steps:

step S22: respectively setting a first light source brightness value and a first light source color temperature value of each light source in a rest mode; setting the first transmittance value and the color temperature value of the electronic glass in the rest mode;

specifically, in the present embodiment, when the first light source luminance value of each light source in the rest mode is set, the first light source color temperature value of each light source in the rest mode is also set at the same time. The first light source brightness value and the first light source color temperature value of each light source may be, but are not limited to: when the user uses the LED lamp for the first time, presetting a first light source brightness value and a first light source color temperature value of each light source in a rest mode; when the use environment is changed or the user is changed, the user resets the first light source brightness value and the first light source color temperature value of each light source; and the system acquires the expected environment brightness value and the expected environment color temperature value according to one or more received photos of the daily sleeping environment. For example, the system calculates a first light source brightness value and a first light source color temperature value of each light source according to one or more pictures uploaded by the user above, below, in front of, behind, to the left of and to the right of the daily sleeping environment. More specifically, the algorithm controller determines an ambient light color value around the sleeping environment according to the daily photos of the sleeping environment uploaded by the user, correspondingly determines an ambient light color value around the user seat, and determines a first light source brightness value and a first light source color temperature value of each light source according to the number of the light sources in each direction around the seat and the positions of the light sources.

In the present embodiment, when the first transmittance value of the electronic glass is set, the first color temperature value of the electronic glass, which is required to be a color exhibited by the electronic glass, is also set. In other words, when the light transmittance of the electronic glass is changed to enable the electronic glass to emit light with different intensities, the color of the electronic glass can be changed to enable the electronic glass to emit light with different color temperatures like a light source, so that the electronic glass can be matched with other light sources to form different light environments in a vehicle.

In one embodiment, the rest mode has a plurality of rest modes, and each light source has a first light source brightness value and a first light source color temperature value in each rest mode. Different environment atmospheres are constructed by the lamplight with different brightness values and different color temperature values, and a user can select one of the environment atmospheres through a rest mode key, a display panel, a wireless communication device and other terminals.

Step S42: receiving a signal for entering a rest mode;

step S62: adjusting the light transmittance and color of the electronic glass to enable the light transmittance of the electronic glass to reach a first light transmittance value and enable the color presented by the electronic glass to reach a first electronic glass color temperature value;

specifically, the light transmittance of the electronic glass is changed to reach a first light transmittance value; the electronic glass emits light with different color temperatures by changing the color of the electronic glass. In this embodiment, the light transmittance and the color of the electronic glass are changed by the control part and the electronic glass control module, and after the control part receives the signal of entering the rest mode, the control part instructs the electronic control module to respectively adjust the light transmittance and the color to the pre-stored first light transmittance value and the first electronic glass color temperature value. In other words, the electronic glass of the present embodiment is electrochromic, and in other embodiments, the electronic glass may be photochromic, thermochromic, mechanochromic, or the like.

Step S72: unfolding the seat;

step S82: and respectively adjusting the brightness and the color temperature of each light source so as to enable each light source to respectively reach a first light source brightness value and a first light source color temperature value which are respectively preset.

By adjusting the brightness and the color temperature of the light source, the implementation not only can gradually weaken the ambient light in the mobile body, but also can change the ambient light color between cold and warm, thereby promoting the drowsiness of the user and providing a more natural rest environment for the user.

Fig. 3 is a schematic flow chart of a sleep-aiding method according to a third embodiment of the present application. The sleep-aiding method is still used in a movable closed space, a plurality of light sources and seats are arranged in the closed space, and electronic glass is arranged around the closed space. The sleep-aiding method comprises the following steps:

step S24: respectively setting a plurality of preset positions on the inner side of the electronic glass and in the vehicle, and setting a first environment brightness value and a first environment color temperature value in a rest mode;

step S44: receiving a signal for entering a rest mode;

step S64: monitoring a second environment brightness value and a second environment light color value of light on the outer side of the electronic glass, and calculating a first transmittance value of the electronic glass according to a difference value between the second environment brightness value and the first environment brightness value; calculating a first electronic glass color temperature value of the color presented by the electronic glass according to the difference value of the second environment light color value and the first environment light color value; respectively adjusting the light transmittance and the color of the electronic glass to enable the light transmittance of each electronic glass to respectively reach a respective first transmittance value and enable the color presented by each electronic glass to respectively reach a first electronic glass color temperature value;

specifically, an external light sensor is disposed on the outer side of each piece of electronic glass, and is configured to monitor a brightness value and a color temperature value of light outside the piece of electronic glass, that is, the second ambient brightness value and the second ambient color value, and output an electrical signal having a corresponding intensity to the control unit. The control part calculates a first transmittance value of the electronic glass according to the difference value between the second environment brightness value and a first environment brightness value prestored in the electronic control module; similarly, the control part calculates a first electronic glass color temperature value of the color presented by the electronic glass according to the difference value of the second environment light color value and the first environment light color value prestored in the electronic glass control module. And then, the control part instructs the electronic glass control module to respectively adjust the light transmittance and the color of the electronic glass, so that the light transmittance of each electronic glass respectively reaches a respective first light transmittance value, and the color presented by each electronic glass respectively reaches a first electronic glass color temperature value.

Step S74: deploying the seat;

step S84: monitoring a current second environment brightness value and a current second environment light color value of each preset position in the vehicle, respectively taking the difference value between the second environment brightness value and the first environment brightness value as a first light source brightness value of each light source, and taking the difference value between the second environment light color value and the first environment light color value as a first light source color temperature value of each light source; gradually adjusting the brightness and the color temperature of each light source respectively to enable each light source to reach a first light source brightness value and a first light source color temperature value which are set respectively;

specifically, in the present embodiment, the current environment information is detected by the photosensor section. After the electronic glass is closed, the light sensor part monitors the brightness and the light color of the current environment at each light source position through the internal sensor arranged at each light source position in the vehicle. The optical sensor defines the monitoring values obtained at this time as a second environment luminance value and a second environment luminance value, respectively, and transmits them to the control section. Then, the control part informs the control part of the difference between the second environment brightness value and the first environment brightness value and the difference between the second environment color temperature value and the preset first environment color temperature value, and the control part instructs the light source control module to respectively adjust the color temperature and the brightness of each light source so that the brightness and the color temperature of each light source respectively reach the preset first light source brightness value and the preset first light source color temperature value, thereby gradually mixing and dimming the ambient light color. When the light source control module adjusts the color temperature and the brightness of each light source, the color temperature and the brightness of the light sources can be directly and greatly adjusted according to the difference value, so that the ambient light color instantly reaches the preset light color; or gradually and slowly adjusting the color temperature and the brightness of the light source according to the difference value to enable the ambient light color to slowly reach the preset light color. More specifically, the adjusted color temperature value and brightness value of the light sources located at different positions are different.

In this embodiment, the first light source luminance value and the first light source color temperature value are input in the system by the user in advance. In another embodiment, the first light source luminance value and the first light source color temperature value are predetermined by a detection section. The detection part acquires the expected environment brightness value and the expected environment color temperature value according to one or more received photos of the daily sleeping environment. The one or more photos are, for example, one or more photos of the upper side, the lower side, the front side, the rear side, the left side and the right side of the daily sleeping environment uploaded by the user. Different from the first two embodiments, the present embodiment presets the ambient light color of the light source after adjustment, so that the ambient light color of the formed sleep-aid light structure can be always kept constant, and the rest environment provided for the user can be more constant and more natural. To achieve the above objective, the present embodiment adds a current ambient light color monitoring step, and further uses the monitoring value obtained in the step to determine the adjustment range of the light parameter and control the light variation of the light source.

In describing the three embodiments described above, reference is made to fig. 1-3 for clarity of explanation of the methods of the present application, and the steps involved in the methods are described in order in the usual order, but in practice, the steps of each method may be performed out of the order described above, and each step is not limited to being performed only once.

Fig. 4 and 5 illustrate a fourth embodiment of the present application. Fig. 4 illustrates the structure of a sleep-assisting system 100 according to a fourth embodiment of the present application, and fig. 5 illustrates the signal flow direction according to the fourth embodiment of the present application. Referring to fig. 4 and 5 together, a sleep-aiding system 100 according to a fourth embodiment of the present application includes a seat 20, a wall 40, a plurality of light sources 60, a plurality of pieces of electronic glass 80, and a light sensor part 70. The photosensor section 70 includes a plurality of external photosensors 72 and a plurality of internal photosensors 74. The seat 20 is provided in the moving body, the wall portion 40 is disposed around the seat 20, both the light source 60 and the electronic glass 80 are disposed on the wall portion 40, and the plurality of external light sensors 72 and the plurality of internal light sensors 74 are also disposed on the wall portion 40. The sensor unit 70 is connected to the control unit 10. The seat 20 is controlled to be deployed and retracted by the seat control module 22, the light source 60 is controlled to emit light by the light source control module 62, and the electronic glass 80 is adjusted in light transmittance and color temperature of the color to be presented by the electronic glass control module 82. The seat control module 22, the light source control module 62 and the electronic glass control module 82 all receive control information from the control section 10. The light sensor unit 70 transmits the monitored ambient light information to the control unit 10 via the detection unit 30, and the control unit 10 adjusts the light transmittance of the electronic glass 80 and the brightness and color temperature of the light source 60 according to the detection information from the detection unit 30.

Specifically, in the present embodiment, the moving object to which the seat 20 is applied is an automobile, the wall portion 40 is an automobile body, the light source 60 is an atmosphere lamp for automobile interior decoration, and the electronic glass 80 is a window made of electronic glass. In other embodiments, the mobile body may also be a train, an airplane, or the like.

More specifically, in the present embodiment, the light source 60 includes a light source 60a, a light source 60b, and a light source 60c, the electronic glass 80 includes an electronic glass 80a and an electronic glass 80b, the external light sensor 72 includes an external light sensor 72a and an external light sensor 72b, and the internal light sensor 74 includes an internal light sensor 74a, an internal light sensor 74b, and an internal light sensor 74 c. The external light sensor 72a is disposed outside the electronic glass 80a, and the external light sensor 72b is disposed outside the electronic glass 80 b. The interior light sensor 74a is disposed in the vicinity of the light source 60a, the interior light sensor 74b is disposed in the vicinity of the light source 60b, and the interior light sensor 74c is disposed in the vicinity of the light source 60 c. In other words, in the present embodiment, the external light sensors 72a and 72b are disposed outside the electronic glass to monitor the second ambient brightness value and the second ambient chromaticity value of the light outside the electronic glass. Interior light sensors 74a, 74b, and 74c are disposed adjacent to the interior lights 60a, 60b, and 60c to monitor a second ambient brightness value and a second ambient light color value at these locations within the vehicle. In other embodiments, the external light sensor and the internal light sensor may not be provided or may be disposed at other positions, for example, the internal light sensor may be provided according to the line-of-sight direction of the user or the driver, or the line-of-sight distance from the user.

In one operation state of the present embodiment, when the user inputs a signal for entering the rest mode through the input unit 12, the control unit 10 instructs the electronic glass control module 82 to adjust the light transmittance of the electronic glass, the seat control module 22 to unfold the chair, and the light source control module 62 adjusts the color temperature and the brightness of the light source 60. More specifically, the electronic glass 80 has a plurality of pieces, and the light source 60 has a plurality of pieces each arranged at a different position, as shown in fig. 4, the electronic glass 80 includes 80a and 80b, and the light source 60 includes 60a, 60b, and 60 c. The transmittance value of each electronic glass 80, and the brightness value and the color temperature value of the light emitted from each light source 60 are initially set by the system, and the user may set the respective values in the initial setting module.

In another operating state of the present embodiment, in order to simulate a relatively natural sleeping environment and enable the ambient light color to promote the drowsiness of the user, the control portion 10 is configured to calculate, by using an algorithm provided therein, a transmittance value to be achieved by each of the electronic glasses 80a and 80b, a color temperature of a color represented by each of the electronic glasses, and a brightness and a color of light emitted by each of the light sources 60a, 60b, and 60c, and further, to preset a first brightness value and a first color temperature value of each of the light sources 60a, 60b, and 60c in the initial setting module when the light sources are in the rest mode. For example, the daily home environment of the european and american user is generally different from the daily home environment of the asian user, and the ambient light color is also different, so that the control unit 10 can change the light atmosphere in the vehicle by changing the required value or even the algorithm, thereby satisfying the requirements of different users.

In still another operating state of the present embodiment, the control section 10 also adjusts the ambient light color based on information from the photosensor section 70. At this time, the user sets in advance a first ambient brightness value and a first ambient color temperature value when each predetermined position in the vehicle is placed in the rest mode according to the expected requirement for the ambient light color, and the predetermined position is provided with the internal light sensor 70. When the electronic glass 80 is turned off or the light transmittance is adjusted to the minimum value, the light sensor 70 monitors a second environment brightness value and a second environment color temperature value of the current environment at each light source through the internal sensor 74 disposed around each light source 60, and notifies the control part 10 of a difference between the second environment brightness value and the first environment brightness value and a difference between the second environment color temperature value and the expected first environment color temperature value, and the control part 10 instructs the light source control module 62 to adjust the color temperature and the brightness of each light source 60 respectively, so as to provide a natural sleeping environment for the user, and enable the user to sleep comfortably. Since the positions of the light sources are different and the colors of ambient light at the light sources are also different, the brightness values and the color temperature values of the light sources 60a, 60b, and 60c are generally adjusted within different ranges.

In another embodiment, the control unit 10 further adjusts the ambient light color based on information from the detection unit 30. At this time, the detection unit 30 obtains the desired environment brightness value and the desired environment color temperature value, i.e., the first environment brightness value and the first environment color temperature value, according to the received one or more photographs of the daily sleeping environment, and transmits them to the control unit 10. In yet another embodiment, the detection unit 10 may also be used to detect other information, such as detecting the geographical position of a moving body, to alert the user when the user is about to reach a destination. In yet another embodiment, the information originally obtained by the optical sensor unit 70 is directly input to the control unit 10 through the detection unit 30, for example, the information originally obtained by the external optical sensor is directly obtained from the internet of vehicles, and the information originally obtained by the internal optical sensor is directly sensed by a mobile terminal held by the hand of the user, and in this case, the sleep-assisting system provided by the present application is not provided with the optical sensor unit 70.

According to the sleep-assisting method, the sleep-assisting system and the moving body with the sleep-assisting system, after a user starts a rest mode key by one key, the electronic glass can be turned off and the seat can be unfolded simultaneously, and light can be gradually weakened for the user according to the brightness setting of the light source by the user so as to help the user to sleep; the brightness of the light can be gradually weakened for the user according to the expected values of the brightness and the color temperature of the light source of the user, the temperature of the light can be adjusted, different light atmospheres can be formed, and a natural rest environment can be provided; and the adjusted ambient light color information can be maintained in a constant range by further detecting the ambient information, so that a more constant and natural rest environment can be created for a user.

Although the present application has been described with reference to a preferred embodiment, it should be understood that various changes, substitutions and alterations can be made herein without departing from the spirit and scope of the application, and all changes, substitutions and alterations that fall within the spirit and scope of the application are to be understood as being covered by the following claims.