CN111867195A - Intelligent household lamp control system - Google Patents

Abstract

The invention relates to an intelligent household lamp control system, which comprises a main lamp and a plurality of auxiliary lamps; the main lamp comprises a first control module, a first driving power module and a first light-emitting module; the auxiliary lamp comprises a light receiving module, a second control module, a second driving power module and a second light emitting module. The invention relates to an intelligent household lamp control system, which uses the function of optical communication to directly transmit a required lighting strategy to other auxiliary lamps in an optical communication mode through a main lamp, and after each auxiliary lamp receives an optical pulse signal of the main lamp, the parameters of brightness, color temperature and the like of each auxiliary lamp can be directly controlled, so that the integral optimization control of the whole household lighting system is realized, multiple switches or a complex lamp control system is avoided, the household lighting installation is simpler and more practical, the operation is simple, and the corresponding main lamp and the corresponding auxiliary lamps can be controlled to enter the corresponding working modes only by one instruction.

Description

Intelligent household lamp control system

Technical Field

The invention relates to the field of intelligent home furnishing, in particular to an intelligent home furnishing lamp control system.

Background

In the present home lighting system, generally, the level and the shape of the light are emphasized, and lamps with various functions are often used in combination to build different light levels, the primary and secondary are clear, and the effect of specific lighting is achieved, such as a crystal lamp, a ceiling lamp, a spot lamp, a lamp strip, a down lamp and the like. Generally, a main lamp is provided in an illumination system, and other lamps respectively perform auxiliary illumination according to different types of illumination functions, for example, the main lamp realizes functional illumination, and other auxiliary lamps respectively realize virtual and real collocation, for example, key illumination, backlight illumination, decorative illumination, and the like. When the lamps are used, a plurality of switches are arranged in a common home to control the lamps correspondingly, which is very troublesome and inconvenient for adjusting each lamp to be in the optimal lighting environment.

In a household lighting system, to create a nice environment, the brightness, color temperature, utility, etc. of each lamp are usually configured differently, so that each lamp plays its unique role in the lighting system. Thus, conventional simple switches are not satisfactory.

To meet the lighting requirements of lighting systems, smart phones APP or dedicated lighting integrated control systems are generally used to perform systematic and centralized control programming on the lamps, so as to implement strategies required for lighting. However, these systems require complicated system equipment, are inconvenient to operate, require relatively cumbersome wiring, or require complicated wireless connections.

Disclosure of Invention

In view of the above, it is necessary to provide a smart home lamp control system, which solves the problems of troublesome wiring and inconvenient operation.

An intelligent household lamp control system comprises a main lamp and a plurality of auxiliary lamps;

the main lamp comprises a first control module, a first driving power module and a first light-emitting module, wherein the first control module is used for storing an instruction set code corresponding to a preset light mode and sending a first control signal containing a plurality of instruction set codes to the first driving power module, and the first driving power module is used for sending corresponding pulse current according to the first control signal so as to drive the first light-emitting module to output a corresponding light pulse signal according to the pulse current;

The auxiliary lamp comprises a light receiving module, a second control module, a second driving power supply module and a second light emitting module, wherein the optical connection module is used for receiving a light pulse signal sent by the first light emitting module, converting the light pulse signal into a received signal and then transmitting the received signal to the second control module, the second control module is used for decoding an instruction set code in the received signal, comparing the instruction set code corresponding to a preset light mode and outputting a corresponding second control signal, and the second driving power supply module is used for sending corresponding current according to the second control signal so as to drive the second light emitting module to send corresponding light according to the current.

Preferably, the first control module, the first driving power module and the first light emitting module are sequentially connected, and the light receiving module, the second control module, the second driving power module and the second light emitting module are sequentially connected.

Preferably, the first control module and the second control module are both MCU controllers.

Preferably, the first light-emitting module and the second light-emitting module are both LED lamps.

Preferably, the first driving power supply and the second driving power supply are both PWM controllers.

Preferably, the light receiving module is a photosensor.

Preferably, the instruction set code is used for controlling a specific auxiliary light to emit specific auxiliary light in a specific light mode, and comprises: the at least one instruction is used for controlling the type of the working auxiliary lamp, the at least one instruction is used for indicating the light-emitting percentage of the working auxiliary lamp, and the at least one instruction is used for indicating the color temperature adjustment degree of the working auxiliary lamp.

Preferably, the command for controlling the auxiliary light type includes a, b, c, wherein a represents a spot light type, b represents a cylinder light type, and c represents a light band type.

Preferably, the instruction for controlling the lighting percentage of the auxiliary lamp comprises T ^ d {1,2} $, wherein T is used for identifying the lighting percentage, and ^ d {2} $isa regular expression and represents two digits and is used for controlling the lighting percentage of the auxiliary lamp.

Preferably, the instruction for controlling the color temperature adjustment degree of the auxiliary lamp comprises S ^ d {1, } $ K, wherein S is used for identifying the color temperature adjustment degree, and ^ d {1, } $ is a regular expression and represents at least one digit for controlling the size of the color temperature adjustment degree of the auxiliary lamp, and K identifies the unit of the color temperature adjustment degree.

The invention relates to an intelligent household lamp control system, which uses the function of optical communication to directly transmit a required lighting strategy to other auxiliary lamps in an optical communication mode through a main lamp, and after each auxiliary lamp receives an optical pulse signal of the main lamp, the parameters of brightness, color temperature and the like of each auxiliary lamp can be directly controlled, so that the integral optimization control of the whole household lighting system is realized, multiple switches or a complex lamp control system is avoided, the household lighting installation is simpler and more practical, the operation is simple, and the corresponding main lamp and the corresponding auxiliary lamps can be controlled to enter the corresponding working modes only by one instruction.

Drawings

Fig. 1 is a signal transmission block diagram of the intelligent home lamp control system of the invention.

Description of reference numerals:

100. a main lamp; 110. a first control module; 120. a first driving power supply module; 130. a first light-emitting module; 200. an auxiliary light; 210. a light receiving module; 220. a second control module; 230. a second driving power supply module; 240. and a second light emitting module.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more clearly understood, the following describes the smart home light control system in further detail with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

In the description of the present invention, "a plurality" means two or more unless otherwise specified; the terms "central," "longitudinal," "lateral," "upper," "lower," "left," "right," "inner," "outer," "front," "rear," "head," "tail," "vertical," "horizontal," "top," "bottom," "inner," "outer," and the like are used in the indicated orientations and positional relationships based on the orientation shown in the drawings for ease of describing the invention and to simplify the description, but do not indicate or imply that the referenced devices or elements must have a particular orientation, be constructed and operated in a particular orientation, and are therefore not to be construed as limiting the invention. Furthermore, the terms "first," "second," "third," and the like are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present invention, it should be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, e.g., as meaning either a fixed connection, a removable connection, or an integral connection; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meaning of the above terms in the present invention can be understood by those of ordinary skill in the art through specific situations.

Referring to fig. 1, the intelligent home light control system of the present invention includes a main light and a plurality of auxiliary lights;

the main lamp comprises a first control module, a first driving power module and a first light-emitting module, wherein the first control module is used for storing an instruction set code corresponding to a preset light mode and sending a first control signal containing a plurality of instruction set codes to the first driving power module, and the first driving power module is used for sending corresponding pulse current according to the first control signal so as to drive the first light-emitting module to output a corresponding light pulse signal according to the pulse current;

the auxiliary lamp comprises a light receiving module, a second control module, a second driving power supply module and a second light emitting module, wherein the optical connection module is used for receiving a light pulse signal sent by the first light emitting module, converting the light pulse signal into a received signal and then transmitting the received signal to the second control module, the second control module is used for decoding an instruction set code in the received signal, comparing the instruction set code corresponding to a preset light mode and outputting a corresponding second control signal, and the second driving power supply module is used for sending corresponding current according to the second control signal so as to drive the second light emitting module to send corresponding light according to the current.

In this embodiment, the first control module is connected to the control system or the APP on the mobile phone through the communication module, and the first control module is controlled to send the instruction set code corresponding to the selected light mode through the external control system or the APP on the mobile phone.

Specifically, the communication module may be a bluetooth communication module or a WiFi communication module.

Of course, the first control module may also be connected to an external control system through a wire.

Specifically, a first control module in the main lamp sends out a first control signal containing an instruction set code, a first driving power module receives the first control signal and sends out a pulse current containing the instruction set code according to the first control signal, and the first light-emitting module outputs a light pulse signal with a frequency of more than two thousand under the action of the pulse current.

Specifically, after receiving the optical pulse signal, the light receiving module of the auxiliary lamp generates a receiving signal corresponding to the optical pulse signal and transmits the receiving signal to the second control module, the second control module decodes the receiving signal after receiving the receiving signal sent by the light receiving module, extracts an instruction set code therein, compares the instruction set code with an instruction set code preset in the second control module, if the instruction set code is matched with the instruction set code, enters a corresponding lamp tube mode, outputs a second control signal to the second driving power supply module, and after receiving the second control signal, the second driving power supply module outputs a corresponding current to drive the second light emitting module to operate in the specified lamp tube mode.

Specifically, the first control module, the first driving power module and the first light emitting module are sequentially connected, and the light receiving module, the second control module, the second driving power module and the second light emitting module are sequentially connected.

Specifically, the first control module and the second control module are both MCU controllers.

Specifically, the Micro Control Unit (MCU) is also called a single chip Microcomputer (single chip Microcomputer) or a single chip Microcomputer.

Specifically, the first light-emitting module and the second light-emitting module are both LED lamps.

Specifically, the first driving power supply and the second driving power supply are both PWM controllers.

Specifically, the light receiving module is a photoelectric sensor.

Specifically, the instruction set code is used for controlling a specific auxiliary lamp to emit specific auxiliary light in a specific light mode, and comprises the following steps: the at least one instruction is used for controlling the type of the working auxiliary lamp, the at least one instruction is used for indicating the light-emitting percentage of the working auxiliary lamp, and the at least one instruction is used for indicating the color temperature adjustment degree of the working auxiliary lamp.

In this embodiment, the information included in the instruction set code includes, but is not limited to, the type of auxiliary light, the lighting percentage, and the color temperature adjustment, which are respectively identified by different instructions.

Specifically, the command for controlling the auxiliary lamp type includes a, b and c, wherein a represents a spot lamp type, b represents a tube lamp type, and c represents a lamp strip type.

In the present embodiment, the auxiliary light types include, but are not limited to, spot lights, tube lights, and light strips, which are respectively identified by a, b, and c in the command.

For example: and a, indicating that the command is a spot light auxiliary light command.

Specifically, the instruction for controlling the lighting percentage of the auxiliary lamp comprises T ^ d {1,2} $, wherein T is used for identifying the lighting percentage, and ^ d {2} $isa regular expression and represents two digits and is used for controlling the lighting percentage of the auxiliary lamp.

In the present embodiment, generally, the lighting percentage command follows the auxiliary lamp type command, denoted by T, followed by the value of the percentage, which ranges from 1 to 99, and in particular, when the value is 0, the auxiliary lamp does not light, and when the value is 100, the auxiliary lamp emits light with the highest light intensity.

For example: aT50, which indicates that the command is a spot light type auxiliary light command, and the light-emitting percentage is 50%.

Specifically, the instruction for controlling the color temperature adjustment degree of the auxiliary lamp comprises S ^ d {1, } $ K, wherein S is used for identifying the color temperature adjustment degree, and ^ d {1, } $ is a regular expression and represents at least one digit and is used for controlling the size of the color temperature adjustment degree of the auxiliary lamp, and K identifies the unit of the color temperature adjustment degree.

In this embodiment, in general, the color temperature adjustment degree follows the light emission percentage command by the letter S, which follows the color temperature adjustment degree value by at least one digit, and the letter K follows the numerical value by the unit.

For example: aT50S1000K, which shows that the command is a spot light type auxiliary light command, the light-emitting percentage is 50%, and the color temperature adjustment degree is 1000K.

The letters are not in upper case and lower case.

Although the present invention has been described with reference to the preferred embodiments, it should be understood that various changes, substitutions and alterations can be made herein without departing from the spirit and scope of the invention as defined by the appended claims.

Claims (10)

1. The utility model provides an intelligence house lamp control system which characterized in that: comprises a main lamp (100) and a plurality of auxiliary lamps (200); the main lamp (100) comprises a first control module (110), a first driving power supply module (120) and a first light-emitting module (130), wherein the first control module (110) is used for storing an instruction set code corresponding to a preset light mode and sending a first control signal containing a plurality of instruction set codes to the first driving power supply module (120), and the first driving power supply module (120) is used for sending a corresponding pulse current according to the first control signal so as to drive the first light-emitting module (130) to output a corresponding light pulse signal according to the pulse current;

The auxiliary lamp (200) comprises a light receiving module (210), a second control module (220), a second driving power supply module (230) and a second light emitting module (240), the optical connection module is used for receiving a light pulse signal sent by the first light emitting module (130), converting the light pulse signal into a received signal and transmitting the received signal to the second control module (220), the second control module (220) is used for decoding an instruction set code in the received signal, comparing the instruction set code corresponding to a preset light mode and outputting a corresponding second control signal, and the second driving power supply module (230) is used for sending a corresponding current according to the second control signal so as to drive the second light emitting module (240) to send corresponding light according to the current.

2. The smart home light control system of claim 1, wherein: the first control module (110), the first driving power module (120) and the first light emitting module (130) are sequentially connected, and the light receiving module (210), the second control module (220), the second driving power supply and the second light emitting module (240) are sequentially connected.

3. The smart home light control system of claim 1, wherein: the first control module (110) and the second control module (220) are both MCU controllers.

4. The smart home light control system of claim 1, wherein: the first light-emitting module (130) and the second light-emitting module (240) are both LED lamps.

5. The smart home light control system of claim 1, wherein: the first driving power supply and the second driving power supply are both PWM controllers.

6. The smart home light control system of claim 1, wherein: the light receiving module (210) is a photoelectric sensor.

7. The smart home light control system of claim 1, wherein: the instruction set is encoded for controlling a particular auxiliary light (200) to emit a particular auxiliary light in a particular lighting mode, comprising: the at least one instruction is used for controlling the type of the working auxiliary lamp (200), the at least one instruction is used for indicating the light-emitting percentage of the working auxiliary lamp (200), and the at least one instruction is used for indicating the color temperature adjustment degree of the working auxiliary lamp (200).

8. The smart home light control system of claim 7, wherein: the command for controlling the types of the auxiliary lamps (200) comprises a, b and c, wherein a represents a spot lamp type, b represents a tube lamp type, and c represents a lamp strip type.

9. The smart home light control system of claim 7, wherein: the instruction for controlling the light-emitting percentage of the auxiliary lamp (200) comprises T ^ d {1,2} $, wherein T is used for identifying the light-emitting percentage, and ^ d {2} $isa regular expression and represents two digits and is used for controlling the light-emitting percentage of the auxiliary lamp (200).

10. The smart home light control system of claim 7, wherein: the instruction for controlling the color temperature adjustment degree of the auxiliary lamp (200) comprises S ^ d {1, } $ K, wherein S is used for identifying the color temperature adjustment degree, and ^ d {1, } $ is a regular expression and represents at least one digit and is used for controlling the size of the color temperature adjustment degree of the auxiliary lamp (200), and K is used for identifying the unit of the color temperature adjustment degree.

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