CN113692090B - Intelligent induction control method - Google Patents

Intelligent induction control method Download PDF

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Publication number
CN113692090B
CN113692090B CN202110892418.8A CN202110892418A CN113692090B CN 113692090 B CN113692090 B CN 113692090B CN 202110892418 A CN202110892418 A CN 202110892418A CN 113692090 B CN113692090 B CN 113692090B
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intelligent
lamp
sensing
induction
intelligent induction
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CN113692090A (en
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严飞飞
严少斌
牟金龙
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Shanghai Biny Electric Co ltd
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Shanghai Biny Electric Co ltd
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    • HELECTRICITY
    • H05ELECTRIC TECHNIQUES NOT OTHERWISE PROVIDED FOR
    • H05BELECTRIC HEATING; ELECTRIC LIGHT SOURCES NOT OTHERWISE PROVIDED FOR; CIRCUIT ARRANGEMENTS FOR ELECTRIC LIGHT SOURCES, IN GENERAL
    • H05B47/00Circuit arrangements for operating light sources in general, i.e. where the type of light source is not relevant
    • H05B47/10Controlling the light source
    • HELECTRICITY
    • H05ELECTRIC TECHNIQUES NOT OTHERWISE PROVIDED FOR
    • H05BELECTRIC HEATING; ELECTRIC LIGHT SOURCES NOT OTHERWISE PROVIDED FOR; CIRCUIT ARRANGEMENTS FOR ELECTRIC LIGHT SOURCES, IN GENERAL
    • H05B47/00Circuit arrangements for operating light sources in general, i.e. where the type of light source is not relevant
    • H05B47/10Controlling the light source
    • H05B47/105Controlling the light source in response to determined parameters
    • HELECTRICITY
    • H05ELECTRIC TECHNIQUES NOT OTHERWISE PROVIDED FOR
    • H05BELECTRIC HEATING; ELECTRIC LIGHT SOURCES NOT OTHERWISE PROVIDED FOR; CIRCUIT ARRANGEMENTS FOR ELECTRIC LIGHT SOURCES, IN GENERAL
    • H05B47/00Circuit arrangements for operating light sources in general, i.e. where the type of light source is not relevant
    • H05B47/10Controlling the light source
    • H05B47/105Controlling the light source in response to determined parameters
    • H05B47/11Controlling the light source in response to determined parameters by determining the brightness or colour temperature of ambient light
    • HELECTRICITY
    • H05ELECTRIC TECHNIQUES NOT OTHERWISE PROVIDED FOR
    • H05BELECTRIC HEATING; ELECTRIC LIGHT SOURCES NOT OTHERWISE PROVIDED FOR; CIRCUIT ARRANGEMENTS FOR ELECTRIC LIGHT SOURCES, IN GENERAL
    • H05B47/00Circuit arrangements for operating light sources in general, i.e. where the type of light source is not relevant
    • H05B47/10Controlling the light source
    • H05B47/105Controlling the light source in response to determined parameters
    • H05B47/115Controlling the light source in response to determined parameters by determining the presence or movement of objects or living beings
    • HELECTRICITY
    • H05ELECTRIC TECHNIQUES NOT OTHERWISE PROVIDED FOR
    • H05BELECTRIC HEATING; ELECTRIC LIGHT SOURCES NOT OTHERWISE PROVIDED FOR; CIRCUIT ARRANGEMENTS FOR ELECTRIC LIGHT SOURCES, IN GENERAL
    • H05B47/00Circuit arrangements for operating light sources in general, i.e. where the type of light source is not relevant
    • H05B47/10Controlling the light source
    • H05B47/155Coordinated control of two or more light sources
    • HELECTRICITY
    • H05ELECTRIC TECHNIQUES NOT OTHERWISE PROVIDED FOR
    • H05BELECTRIC HEATING; ELECTRIC LIGHT SOURCES NOT OTHERWISE PROVIDED FOR; CIRCUIT ARRANGEMENTS FOR ELECTRIC LIGHT SOURCES, IN GENERAL
    • H05B47/00Circuit arrangements for operating light sources in general, i.e. where the type of light source is not relevant
    • H05B47/10Controlling the light source
    • H05B47/16Controlling the light source by timing means
    • HELECTRICITY
    • H05ELECTRIC TECHNIQUES NOT OTHERWISE PROVIDED FOR
    • H05BELECTRIC HEATING; ELECTRIC LIGHT SOURCES NOT OTHERWISE PROVIDED FOR; CIRCUIT ARRANGEMENTS FOR ELECTRIC LIGHT SOURCES, IN GENERAL
    • H05B47/00Circuit arrangements for operating light sources in general, i.e. where the type of light source is not relevant
    • H05B47/10Controlling the light source
    • H05B47/165Controlling the light source following a pre-assigned programmed sequence; Logic control [LC]
    • HELECTRICITY
    • H05ELECTRIC TECHNIQUES NOT OTHERWISE PROVIDED FOR
    • H05BELECTRIC HEATING; ELECTRIC LIGHT SOURCES NOT OTHERWISE PROVIDED FOR; CIRCUIT ARRANGEMENTS FOR ELECTRIC LIGHT SOURCES, IN GENERAL
    • H05B47/00Circuit arrangements for operating light sources in general, i.e. where the type of light source is not relevant
    • H05B47/10Controlling the light source
    • H05B47/175Controlling the light source by remote control
    • H05B47/19Controlling the light source by remote control via wireless transmission
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02BCLIMATE CHANGE MITIGATION TECHNOLOGIES RELATED TO BUILDINGS, e.g. HOUSING, HOUSE APPLIANCES OR RELATED END-USER APPLICATIONS
    • Y02B20/00Energy efficient lighting technologies, e.g. halogen lamps or gas discharge lamps
    • Y02B20/40Control techniques providing energy savings, e.g. smart controller or presence detection

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  • Engineering & Computer Science (AREA)
  • Computer Networks & Wireless Communication (AREA)
  • Circuit Arrangement For Electric Light Sources In General (AREA)

Abstract

The intelligent induction control method is based on an intelligent induction control system and comprises an intelligent induction lamp and an intelligent sensor; the number of the intelligent induction lamps is N, N is more than or equal to 1, the intelligent induction lamps are divided into N groups according to the area or the number, N is more than or equal to 1, and each intelligent induction lamp in each group is in a unidirectional linkage illumination mode or a non-unidirectional linkage illumination mode; the intelligent sensing lamps are arranged in a wireless communication mode, and the intelligent sensing lamps are connected with the corresponding intelligent sensors in an interactive wireless communication mode; in the uncorrelated illumination mode, the sensing area parts between two adjacent groups of intelligent sensing lamps are overlapped. The invention can self-define and set the automatic starting time, the number of the induction lamps and the type of the illumination scene modes, and realize the automatic switching to different illumination scene modes according to different application scenes, different time periods and the outdoor illumination intensity of the environment, thereby achieving the maximum energy saving under the condition of not affecting the normal operation of the induction lamps.

Description

Intelligent induction control method
Technical Field
The invention relates to an intelligent induction control method.
Background
The novel intelligent illumination product can automatically control the light source to be lightened through the induction module when the lamp is inducted, and can automatically turn on illumination and automatically delay to turn off after people leave; the induction lamp is often installed in larger buildings such as residential buildings, markets, hospitals, airports, urban roads and other public areas in daily use so as to bring light to users in dark areas or when the light is dim; however, existing induction lamps suffer from the following drawbacks: firstly, the interval distance between the induction lamps arranged in a plurality of public areas is far, so that the trouble of wiring and unnecessary waste of resources can be reduced as far as possible under the condition of meeting the use requirement, and people walk in the building because the two induction lamps are far away, when the people leave the induction area of the current induction lamp and do not walk to the induction area of the next induction lamp, the people usually experience a section of area with dim light or no light, the user experience is influenced, and the potential safety hazard is large; secondly, in two adjacent areas, because of being blocked by a wall body or a door, when a user leaves a current area and enters another area, the user often experiences a state of being blackened before eyes and cannot predict the condition of the other area because the induction lamp of the other area cannot be started in advance, so that the use of the user is inconvenient and the user experience is affected; thirdly, the existing induction lamp can only be started when sensing someone, and the brightness of lamplight cannot be adjusted. However, under different ambient light brightness, the light brightness needs to be different, for example, in cloudy days, the light brightness can be lower, and at night, the light brightness needs to be higher, and the brightness of the existing sensing lamp is constant and cannot be adjusted.
Disclosure of Invention
Aiming at the defects of the prior art, the invention provides an intelligent induction control method.
In order to achieve the above purpose, the present invention is realized by the following technical scheme:
the intelligent induction control method is based on an intelligent induction control system, and the system comprises an intelligent induction lamp and an intelligent sensor; the intelligent induction lamp comprises a power supply module, a light emitting module, a controller, a wireless communication module, an induction module and an environment monitoring module, wherein the power supply module, the light emitting module, the wireless communication module, the induction module and the environment monitoring module of the intelligent induction lamp are all electrically connected with the controller of the intelligent induction lamp; the intelligent sensor also comprises a power supply module, a controller, a wireless communication module, an induction module and an environment monitoring module, wherein the power supply module, the wireless communication module, the induction module and the environment monitoring module of the intelligent sensor are all electrically connected with the controller; the number of the intelligent induction lamps is N, N is more than or equal to 1, N intelligent induction lamps are divided into N groups according to the area or the number, N is more than or equal to 1, and each intelligent induction lamp of each group is in interactive wireless communication connection and is in a linkage illumination mode; the linkage illumination mode comprises a unidirectional linkage illumination mode and a non-unidirectional linkage illumination mode; the intelligent sensing lamps are arranged in a wireless communication mode, and the intelligent sensing lamps are connected with the corresponding intelligent sensors in an interactive wireless communication mode; in the uncorrelated illumination mode, the sensing area parts between two adjacent groups of intelligent sensing lamps are overlapped.
The specific intelligent induction control method comprises the following steps:
s1, pre-configuring a preset trigger strategy of an intelligent induction lamp and an intelligent sensor;
if the current intelligent induction lamp senses a signal of a target object, a controller of the current intelligent induction lamp invokes a preset trigger strategy of the current intelligent induction lamp, and compares the preset trigger strategy with monitoring data of an environment monitoring module of the current intelligent induction lamp to judge whether the preset trigger strategy is met or not; if the trigger strategy is established and the trigger strategy is not the trigger strategy in the unidirectional linkage illumination mode, executing the step S2; if the trigger strategy is established and triggered by the trigger strategy in the unidirectional linkage illumination mode, executing the step S3; if not, jumping back to the step S1;
if the current intelligent sensor senses a signal of a target object, a controller of the current intelligent sensor invokes a preset trigger strategy of the current intelligent sensor, and compares the preset trigger strategy with monitoring data of an environment monitoring module of the current intelligent sensor to judge whether the preset trigger strategy is established or not; if yes, executing step S4; if not, jumping back to the step S1;
s2, the current intelligent induction lamp sends a non-unidirectional linkage instruction to other intelligent induction lamps in the same group, and the other intelligent induction lamps in the same group are informed to execute linkage actions of the non-unidirectional linkage illumination mode;
s3, the current intelligent induction lamp sends a unidirectional linkage instruction to other intelligent induction lamps in the same group adjacent to the current intelligent induction lamp, and the other intelligent induction lamps in the same group adjacent to the current intelligent induction lamp are informed to execute linkage action of the unidirectional linkage illumination mode;
s4, the current intelligent sensor sends an association instruction to the intelligent sensing lamp associated with the current intelligent sensor, and the intelligent sensing lamp associated with the current intelligent sensor is informed to execute the association action of the association lighting mode.
In the above technical solution, the linkage action of the non-unidirectional linkage illumination mode in the step S2 includes the following steps:
s2.1, comparing the current intelligent induction lamp with monitoring data of an environment monitoring module according to the preset trigger strategy, and controlling the lighting scene mode of the lighting module through a controller according to a comparison result; meanwhile, sending a non-unidirectional linkage instruction to other intelligent induction lamps in the same group as the current intelligent induction lamp;
s2.2, when other intelligent induction lamps in the same group of the current intelligent induction lamps receive the non-unidirectional linkage instruction, judging whether an illumination scene mode is required to be started or not according to monitoring data of an environment monitoring module of the current intelligent induction lamps, if not, responding to a linkage illumination request of the non-unidirectional linkage instruction, and if so, responding to the linkage illumination request of the non-unidirectional linkage instruction and controlling the illumination scene mode of a light emitting module of the current intelligent induction lamps through respective controllers according to respective monitoring data.
In the above technical solution, the linkage action of the unidirectional linkage illumination mode in the step S3 specifically includes the following steps:
s3.1, comparing the current intelligent induction lamp with monitoring data of an environment monitoring module according to the preset trigger strategy, and controlling the lighting scene mode of the lighting module through a controller according to a comparison result; simultaneously, sending unidirectional linkage instructions to other intelligent sensing lamps in the same group adjacent to the unidirectional linkage instructions;
s3.2, when other intelligent sensing lamps in the same group adjacent to the current intelligent sensing lamp receive the unidirectional linkage instruction, firstly checking the validity of the unidirectional linkage instruction, if the unidirectional linkage instruction is valid, judging whether an illumination scene mode needs to be started according to monitoring data of an environment monitoring module of the unidirectional linkage instruction, if not, responding to a linkage illumination request of the unidirectional linkage instruction, if so, responding to the linkage illumination request of the unidirectional linkage instruction and controlling the illumination scene mode of a light emitting module of the unidirectional linkage instruction through a controller according to the monitoring data of the unidirectional linkage instruction; and if the unidirectional linkage instruction is invalid, not responding to the linkage illumination request of the unidirectional linkage instruction.
In the above technical solution, the validity auditing method of the unidirectional linkage instruction in step S3.2 is as follows:
defining the preset induction duration of the current intelligent induction lamp as T, and defining the real-time induction duration of the current intelligent induction lamp as T; defining an intelligent induction lamp A and an intelligent induction lamp B which are in the same group as the current intelligent induction lamp and are adjacent to each other, wherein the intelligent induction lamp A and the intelligent induction lamp B are not adjacent to each other;
assume that the intelligent sensing lamp A senses a target object signal and effectively and unidirectionally links the current intelligent sensing lamp;
if the real-time sensing duration T of the current intelligent sensing lamp is less than T, when the current intelligent sensing lamp senses a signal of a target object, the unidirectional linkage instruction sent to the intelligent sensing lamp B by the current intelligent sensing lamp is valid at the moment, and the unidirectional linkage instruction sent to the intelligent sensing lamp A is invalid, namely unidirectional linkage, until the real-time sensing duration T of the current intelligent sensing lamp is released;
if the real-time sensing duration T of the current intelligent sensing lamp is less than T, when the intelligent sensing lamp B senses a signal of a target object, the unidirectional linkage instruction sent by the intelligent sensing lamp B to the current intelligent sensing lamp is still valid;
if the real-time sensing duration T of the current intelligent sensing lamp is more than or equal to T, and the current intelligent sensing lamp senses the signal of the target object, the unidirectional linkage instruction sent by the current intelligent sensing lamp to the intelligent sensing lamp A and the intelligent sensing lamp B is effective.
In the above technical solution, the associating operation of the associated lighting pattern in the step S4 includes the following steps
S4.1, when the intelligent sensor compares the preset trigger strategy with the monitoring data of the environment monitoring module, an associated instruction is sent to an intelligent induction lamp associated with the intelligent sensor according to a comparison result;
s4.2, when the intelligent induction lamp associated with the intelligent induction lamp receives the association instruction, judging whether the lighting scene mode needs to be started or not according to the monitoring data of the environment monitoring module of the intelligent induction lamp, if not, not responding to the association lighting request of the association instruction, if so, responding to the association lighting request of the association instruction and controlling the lighting scene mode of the lighting module of the intelligent induction lamp through the controller according to the monitoring data of the intelligent induction lamp.
In the above technical solution, the triggering mode of the preset triggering strategy is one or more of a timing triggering mode, a satellite positioning triggering mode and a light sensing triggering mode; if the triggering mode of the preset triggering strategy is a timing triggering mode, presetting a timing time interval, and when the set timing starting node and timing ending node are reached, controlling the controller of the intelligent induction lamp or the intelligent sensor and controlling the lighting scene mode of the corresponding intelligent induction lamp lighting module; if the triggering mode of the preset triggering strategy is a satellite positioning triggering mode, the controller of the intelligent induction lamp or the intelligent sensor acquires longitude and latitude information of the current region by receiving satellite positioning information, configures a sunrise and sunset time table according to the longitude and latitude information, and controls the illumination scene mode of the corresponding intelligent induction lamp light-emitting module according to the sunrise and sunset time table; and if the triggering mode of the preset triggering strategy is a light sensing triggering mode, controlling the illumination scene mode of the corresponding intelligent sensing lamp light-emitting module by the controller of the intelligent sensing lamp or the intelligent sensor according to the illumination condition of the current region.
In the above technical scheme, the lighting scene mode includes four modes of turning on a lamp, turning off the lamp, self-defining dimming and color temperature adjustment.
In the above technical scheme, the self-defined dimming comprises linear dimming and fixed-grid dimming, and the self-defined dimming is realized by controlling the output duty ratio of each set of lamp by the lighting control unit through PWM signals or 0-10V.
In the above technical scheme, the sensing modules of the intelligent sensing lamp and the intelligent sensor comprise one or more of a human body sensor, a light sensor and a radar sensor.
In the above technical scheme, the environment monitoring module comprises one or more of a GPS satellite positioning element, an illuminance element, a fog sensing element, a haze sensing element, a wind speed sensing element, a human body sensing element, a temperature sensing element, a rainfall sensing element, a speed sensing element and a radar detection element.
According to the technical scheme, the intelligent sensing lamp monitoring system further comprises a main control unit, wherein the main control unit is in interactive communication connection with each intelligent sensing lamp and each intelligent sensor, and the main control unit is used for storing, comparing, analyzing and processing according to the acquired running state parameters of the intelligent sensing lamps and the intelligent sensors so as to remotely monitor the intelligent sensing lamps and the intelligent sensors; the main control unit comprises a storage server, a data server and monitoring platform software.
Compared with the prior art, the invention has the beneficial effects that:
the intelligent induction control method can be used for self-defining the automatic starting time, the number of the induction lamps and the type of the illumination scene modes of the intelligent induction control system, and realizing the automatic switching to different illumination scene modes according to different application scenes, different time periods and the outdoor illumination intensity of the environment, thereby achieving the maximum energy saving under the condition of not affecting the normal operation of the induction lamps; meanwhile, an induction linkage mode can be set on the object moving path in a self-defined mode, and a more intelligent and convenient induction control scheme is provided.
According to the invention, two modes of an associated illumination mode and a non-associated illumination mode are selected between any two adjacent groups of intelligent induction lamps, under the associated illumination mode, the intelligent sensor is additionally arranged between the two adjacent groups of intelligent induction lamps with non-coincident induction areas, and the intelligent sensor is used for associating part of the intelligent induction lamps in the two adjacent groups of intelligent induction lamps, so that the induction lamps in the adjacent areas can be started in advance, thereby effectively solving the defects of long interval between the two adjacent groups of intelligent induction lamps or barrier blocking and the like, effectively eliminating induction blind areas and enhancing user experience.
The linkage mode among the intelligent induction lamps in the same group is divided into a unidirectional linkage illumination mode and a non-unidirectional linkage illumination mode, so that all the intelligent induction lamps can be turned on instantly under the condition that a large area illumination is required to be turned on simultaneously in a conference hall, a concert hall, a large classroom and the like, and the user experience is enhanced; the illumination of long and narrow areas such as a gallery and stairs can adopt unidirectional linkage illumination, so that the effect of gradually opening and gradually extinguishing is realized, normal illumination requirements can be met, and the maximum energy conservation can be realized.
According to the invention, a preset trigger strategy is set through the system, different groups of intelligent sensing lamps are controlled, the trigger modes comprise a timing trigger mode, a satellite positioning trigger mode and a light sensing trigger mode, and the modes can be independently set and applied, and can also be combined and set and applied; the intelligent induction control system can be selected by user definition according to different practical application scenes, and can effectively save energy sources while meeting the normal operation requirements of the induction lamp, improve the utilization rate of the induction lamp in the operation environment of the induction control system, reduce the resource waste and improve the modernization management level of the intelligent induction control system.
Drawings
Fig. 1 is a schematic diagram of an intelligent induction control method according to an embodiment of the invention.
FIG. 2 is a schematic diagram of a validity auditing method with unidirectional linkage instructions in an embodiment of the present invention.
Wherein: 1. an intelligent induction lamp A; 2. current intelligent induction lamps; 3. an intelligent induction lamp B; a signal representative of the target object; the status of the intelligent sensing lamp when responding to the unidirectional linkage instruction is indicated by the following;indicating the state of the intelligent induction lamp when the unidirectional linkage instruction is not responded; either ≡or → indicates the direction of the unidirectional linkage instruction, and the arrow points to the unidirectional linkage target.
Detailed Description
The invention is described in detail below with reference to the attached drawing figures:
example 1
Referring to fig. 1, the intelligent induction control method is based on an intelligent induction control system, which comprises an intelligent induction lamp and an intelligent sensor; the intelligent induction lamp comprises a power supply module, a light emitting module, a controller, a wireless communication module, an induction module and an environment monitoring module, wherein the power supply module, the light emitting module, the wireless communication module, the induction module and the environment monitoring module of the intelligent induction lamp are all electrically connected with the controller of the intelligent induction lamp; the intelligent sensor also comprises a power supply module, a controller, a wireless communication module, an induction module and an environment monitoring module, wherein the power supply module, the wireless communication module, the induction module and the environment monitoring module of the intelligent sensor are all electrically connected with the controller; the number of the intelligent induction lamps is N, N is more than or equal to 1, N intelligent induction lamps are divided into N groups according to the area or the number, N is more than or equal to 1, and each intelligent induction lamp of each group is in interactive wireless communication connection and is in a linkage illumination mode; the linkage illumination mode comprises a unidirectional linkage illumination mode and a non-unidirectional linkage illumination mode; the intelligent sensing lamps are arranged in a wireless communication mode, and the intelligent sensing lamps are connected with the corresponding intelligent sensors in an interactive wireless communication mode; in the non-associated illumination mode, the sensing areas between two adjacent groups of intelligent sensing lamps are partially overlapped;
the specific intelligent induction control method comprises the following steps:
s1, pre-configuring a preset trigger strategy of an intelligent induction lamp and an intelligent sensor;
if the current intelligent induction lamp senses a signal of a target object, a controller of the current intelligent induction lamp invokes a preset trigger strategy of the current intelligent induction lamp, and compares the preset trigger strategy with monitoring data of an environment monitoring module of the current intelligent induction lamp to judge whether the preset trigger strategy is met or not; if the trigger strategy is established and the trigger strategy is not the trigger strategy in the unidirectional linkage illumination mode, executing the step S2; if the trigger strategy is established and triggered by the trigger strategy in the unidirectional linkage illumination mode, executing the step S3; if not, jumping back to the step S1;
if the current intelligent sensor senses a signal of a target object, a controller of the current intelligent sensor invokes a preset trigger strategy of the current intelligent sensor, and compares the preset trigger strategy with monitoring data of an environment monitoring module of the current intelligent sensor to judge whether the preset trigger strategy is established or not; if yes, executing step S4; if not, jumping back to the step S1;
s2, the current intelligent induction lamp sends linkage instructions to other intelligent induction lamps in the same group, and the other intelligent induction lamps in the same group are informed of executing linkage actions of the non-unidirectional linkage illumination mode;
s3, the current intelligent induction lamp sends linkage instructions to other intelligent induction lamps in the same group adjacent to the current intelligent induction lamp, and the other intelligent induction lamps in the same group adjacent to the current intelligent induction lamp are informed to execute linkage actions of the unidirectional linkage illumination mode;
s4, the current intelligent sensor sends an association instruction to the intelligent sensing lamp associated with the current intelligent sensor, and the intelligent sensing lamp associated with the current intelligent sensor is informed to execute the association action of the association lighting mode.
In a preferred but non-limiting embodiment of the present invention, the linkage action of the non-unidirectional linkage illumination mode in the step S2 includes the steps of:
s2.1, comparing the current intelligent induction lamp with monitoring data of an environment monitoring module according to the preset trigger strategy, and controlling the lighting scene mode of the lighting module through a controller according to a comparison result; meanwhile, sending a non-unidirectional linkage instruction to other intelligent induction lamps in the same group as the current intelligent induction lamp;
s2.2, when other intelligent induction lamps in the same group of the current intelligent induction lamps receive the non-unidirectional linkage instruction, judging whether an illumination scene mode is required to be started or not according to monitoring data of an environment monitoring module of the current intelligent induction lamps, if not, responding to a linkage illumination request of the non-unidirectional linkage instruction, and if so, responding to the linkage illumination request of the non-unidirectional linkage instruction and controlling the illumination scene mode of a light emitting module of the current intelligent induction lamps through respective controllers according to respective monitoring data.
In a preferred but non-limiting embodiment of the present invention, the linking action of the unidirectional linked illumination mode in the step S3 specifically includes the following steps:
s3.1, comparing the current intelligent induction lamp with monitoring data of an environment monitoring module according to the preset trigger strategy, and controlling the lighting scene mode of the lighting module through a controller according to a comparison result; simultaneously, sending unidirectional linkage instructions to other intelligent sensing lamps in the same group adjacent to the unidirectional linkage instructions;
s3.2, when other intelligent sensing lamps in the same group adjacent to the current intelligent sensing lamp receive the unidirectional linkage instruction, firstly checking the validity of the unidirectional linkage instruction, if the unidirectional linkage instruction is valid, judging whether an illumination scene mode needs to be started according to monitoring data of an environment monitoring module of the unidirectional linkage instruction, if not, responding to a linkage illumination request of the unidirectional linkage instruction, if so, responding to the linkage illumination request of the unidirectional linkage instruction and controlling the illumination scene mode of a light emitting module of the unidirectional linkage instruction through a controller according to the monitoring data of the unidirectional linkage instruction; and if the unidirectional linkage instruction is invalid, not responding to the linkage illumination request of the unidirectional linkage instruction.
In a preferred, but non-limiting embodiment of the present invention, referring to fig. 2, the method for checking the validity of the unidirectional linkage instruction in step S3.2 is as follows: defining the preset induction duration of the current intelligent induction lamp as T, and defining the real-time induction duration of the current intelligent induction lamp as T; defining an intelligent induction lamp A and an intelligent induction lamp B which are in the same group as the current intelligent induction lamp and are adjacent to each other, wherein the intelligent induction lamp A and the intelligent induction lamp B are not adjacent to each other;
assume that the intelligent sensing lamp A senses a target object signal and effectively and unidirectionally links the current intelligent sensing lamp;
if the real-time sensing duration T of the current intelligent sensing lamp is less than T, when the current intelligent sensing lamp senses a signal of a target object, the unidirectional linkage instruction sent to the intelligent sensing lamp B by the current intelligent sensing lamp is valid at the moment, and the unidirectional linkage instruction sent to the intelligent sensing lamp A is invalid, namely unidirectional linkage, until the real-time sensing duration T of the current intelligent sensing lamp is released; it should be noted that, the unidirectional linkage of the present invention has timeliness, for example, if T is less than T, the current intelligent induction lamp senses the target object signal again if the intelligent induction lamp a is effective to unidirectional linkage the current intelligent induction lamp, and at this time, the unidirectional linkage instruction sent by the current intelligent induction lamp to the intelligent induction lamp a is invalid; the unidirectional linkage instruction is counted down by T, and once the sensing duration time T is finished, the unidirectional linkage instruction sent by the current intelligent sensing lamp to the intelligent sensing lamp A is restored to be effective again.
If the real-time sensing duration T of the current intelligent sensing lamp is less than T, when the intelligent sensing lamp B senses a signal of a target object, the unidirectional linkage instruction sent by the intelligent sensing lamp B to the current intelligent sensing lamp is still valid;
if the real-time sensing duration T of the current intelligent sensing lamp is more than or equal to T, and the current intelligent sensing lamp senses the signal of the target object, the unidirectional linkage instruction sent by the current intelligent sensing lamp to the intelligent sensing lamp A and the intelligent sensing lamp B is effective.
In a preferred but non-limiting embodiment of the present invention, the associating action of the associated illumination pattern in the step S4 includes the steps of
S4.1, when the intelligent sensor compares the preset trigger strategy with the monitoring data of the environment monitoring module, an associated instruction is sent to an intelligent induction lamp associated with the intelligent sensor according to a comparison result;
s4.2, when the intelligent induction lamp associated with the intelligent induction lamp receives the association instruction, judging whether the lighting scene mode needs to be started or not according to the monitoring data of the environment monitoring module of the intelligent induction lamp, if not, not responding to the association lighting request of the association instruction, if so, responding to the association lighting request of the association instruction and controlling the lighting scene mode of the lighting module of the intelligent induction lamp through the controller according to the monitoring data of the intelligent induction lamp.
In a preferred but non-limiting embodiment of the present invention, the triggering mode of the preset triggering strategy is one or more of a timing triggering mode, a satellite positioning triggering mode and a light sensing triggering mode;
if the triggering mode of the preset triggering strategy is a timing triggering mode, presetting a timing time interval, and when the set timing starting node and timing ending node are reached, controlling the controller of the intelligent induction lamp or the intelligent sensor and controlling the lighting scene mode of the corresponding intelligent induction lamp lighting module;
if the triggering mode of the preset triggering strategy is a satellite positioning triggering mode, the controller of the intelligent induction lamp or the intelligent sensor acquires longitude and latitude information of the current region by receiving satellite positioning information, configures a sunrise and sunset time table according to the longitude and latitude information, and controls the illumination scene mode of the corresponding intelligent induction lamp light-emitting module according to the sunrise and sunset time table;
and if the triggering mode of the preset triggering strategy is a light sensing triggering mode, controlling the illumination scene mode of the corresponding intelligent sensing lamp light-emitting module by the controller of the intelligent sensing lamp or the intelligent sensor according to the illumination condition of the current region.
In a preferred but non-limiting embodiment of the present invention, the lighting profile includes four modes of turning on, turning off, custom dimming and color temperature.
In a preferred but non-limiting embodiment of the present invention, the custom dimming includes linear dimming and fixed-grid dimming, and the custom dimming is implemented by the lighting control unit by controlling the output duty cycle of each set of the lamps through PWM signals or 0-10V.
In a preferred but non-limiting embodiment of the present invention, the sensing modules of the intelligent sensing lamp and the intelligent sensor each comprise one or more of a human body sensor, a light sensor and a radar sensor.
In a preferred, but non-limiting embodiment of the present invention, the environmental monitoring module comprises one or more of a GPS satellite positioning element, an illuminance element, a fog sensing element, a haze sensing element, a wind speed sensing element, a human body sensing element, a temperature sensing element, a rainfall sensing element, a speed sensing element, and a radar detection element.
In a preferred but non-limiting embodiment of the present invention, the system further comprises a main control unit, wherein the main control unit is in interactive communication connection with each intelligent induction lamp and each intelligent sensor, and the main control unit is used for storing, comparing, analyzing and processing according to the acquired operation state parameters of the intelligent induction lamps and the intelligent sensors so as to remotely monitor the intelligent induction lamps and the intelligent sensors; the main control unit comprises a storage server, a data server and monitoring platform software.
Example 2
Application scenarios of different trigger modes of the preset trigger policy will be described below.
In a timing mode, for example, in an airport, in a period of 18:30 to 1:00 in the early morning, flights get in and out busy, the timing starting node of the intelligent induction lamp in an operation area can be appointed to be 18:30 in advance, the brightness is adjusted to 100%, and at the moment, once the appointed time is reached, all the appointed intelligent induction lamps can be automatically started, so that the normal and safe operation of the operation is ensured; in the time period of 1:30 in the early morning to 6:30 in the early morning, flights are fewer, and the brightness of the intelligent induction lamp in the designated operation area of the airport can be preset to be 50%, so that energy conservation and consumption reduction are realized. In the time period of 6:30 in the morning to 18:30 in the evening, the illumination meets the requirement without lighting, and the intelligent induction lamp turning-off time in the operation area can be preset to be 6:30.
Under the GPS mode, the system automatically calculates sunrise and sunset time according to the GPS positioning system, automatically turns off the lamp according to the sunrise and sunset time and automatically turns on the lamp according to the sunset time.
Under the photoinduction mode, the intelligent induction lamp controller can be according to current illumination condition, and whether the lamp is needed to be turned on or off is judged automatically, for example face overcast and rainy weather, haze weather in daytime, and the illumination is insufficient, and the intelligent induction lamp perceives that the current condition is automatically turned on, and the illumination is automatically turned off after the current illumination is recovered.
In a hybrid mode, namely timing+GPS, timing+light sense, timing+light sense+GPS and the like, the combination in any mode realizes intelligent induction illumination.
Example 3
An application scenario of the unidirectional linkage illumination mode will be described below.
For example, a large hotel corridor is long and narrow and is free from illumination throughout the year, intelligent induction lamps can be distributed according to the structural interval of the corridor, and adjacent intelligent induction lamps are linked in a unidirectional mode, so that the visual effect of the corridor can be guaranteed, when no person walks, the corridor is in a low-brightness illumination state, such as 10% of brightness is started, a unidirectional mode is started when the person walks is perceived, the corridor is gradually started along the pedestrian direction in the unidirectional linkage mode, the pedestrian direction is far away from the pedestrian direction, the corridor is gradually extinguished to the low-brightness mode, and the maximized energy conservation is realized under the condition of ensuring consumer experience.
The examples of the present invention are intended to be illustrative only and not to limit the scope of the claims, and other substantially equivalent substitutions will occur to those skilled in the art and are intended to be within the scope of the present invention.

Claims (11)

1. The intelligent induction control method is characterized in that: based on an intelligent induction control system, the system comprises an intelligent induction lamp and an intelligent sensor;
the intelligent induction lamp comprises a power supply module, a light emitting module, a controller, a wireless communication module, an induction module and an environment monitoring module, wherein the power supply module, the light emitting module, the wireless communication module, the induction module and the environment monitoring module of the intelligent induction lamp are all electrically connected with the controller of the intelligent induction lamp;
the intelligent sensor also comprises a power supply module, a controller, a wireless communication module, an induction module and an environment monitoring module, wherein the power supply module, the wireless communication module, the induction module and the environment monitoring module of the intelligent sensor are all electrically connected with the controller;
the number of the intelligent induction lamps is N, N is more than or equal to 1, N intelligent induction lamps are divided into N groups according to the area or the number, N is more than or equal to 1, and each intelligent induction lamp of each group is in interactive wireless communication connection and is in a linkage illumination mode;
the linkage illumination mode comprises a unidirectional linkage illumination mode and a non-unidirectional linkage illumination mode;
the intelligent sensing lamps are arranged in a wireless communication mode, and the intelligent sensing lamps are connected with the corresponding intelligent sensors in an interactive wireless communication mode; in the non-associated illumination mode, the sensing areas between two adjacent groups of intelligent sensing lamps are partially overlapped;
the specific intelligent induction control method comprises the following steps:
s1, pre-configuring a preset trigger strategy of an intelligent induction lamp and an intelligent sensor;
if the current intelligent induction lamp senses a signal of a target object, a controller of the current intelligent induction lamp invokes a preset trigger strategy of the current intelligent induction lamp, and compares the preset trigger strategy with monitoring data of an environment monitoring module of the current intelligent induction lamp to judge whether the preset trigger strategy is met or not; if the trigger strategy is established and the trigger strategy is not the trigger strategy in the unidirectional linkage illumination mode, executing the step S2; if the trigger strategy is established and triggered by the trigger strategy in the unidirectional linkage illumination mode, executing the step S3; if not, jumping back to the step S1;
if the current intelligent sensor senses a signal of a target object, a controller of the current intelligent sensor invokes a preset trigger strategy of the current intelligent sensor, and compares the preset trigger strategy with monitoring data of an environment monitoring module of the current intelligent sensor to judge whether the preset trigger strategy is established or not; if yes, executing step S4; if not, jumping back to the step S1;
s2, the current intelligent induction lamp sends a non-unidirectional linkage instruction to other intelligent induction lamps in the same group, and the other intelligent induction lamps in the same group are informed to execute linkage actions of the non-unidirectional linkage illumination mode;
s3, the current intelligent induction lamp sends a unidirectional linkage instruction to other intelligent induction lamps in the same group adjacent to the current intelligent induction lamp, and the other intelligent induction lamps in the same group adjacent to the current intelligent induction lamp are informed to execute linkage action of the unidirectional linkage illumination mode;
s4, the current intelligent sensor sends an association instruction to the intelligent sensing lamp associated with the current intelligent sensor, and the intelligent sensing lamp associated with the current intelligent sensor is informed to execute the association action of the association lighting mode.
2. The intelligent induction control method according to claim 1, characterized in that: the linkage action of the non-unidirectional linkage illumination mode in the step S2 includes the following steps:
s2.1, comparing the current intelligent induction lamp with monitoring data of an environment monitoring module according to the preset trigger strategy, and controlling the lighting scene mode of the lighting module through a controller according to a comparison result; meanwhile, sending a non-unidirectional linkage instruction to other intelligent induction lamps in the same group as the current intelligent induction lamp;
s2.2, when other intelligent induction lamps in the same group of the current intelligent induction lamps receive the non-unidirectional linkage instruction, judging whether an illumination scene mode is required to be started or not according to monitoring data of an environment monitoring module of the current intelligent induction lamps, if not, responding to a linkage illumination request of the non-unidirectional linkage instruction, and if so, responding to the linkage illumination request of the non-unidirectional linkage instruction and controlling the illumination scene mode of a light emitting module of the current intelligent induction lamps through respective controllers according to respective monitoring data.
3. The intelligent induction control method according to claim 1, characterized in that: the linkage action of the unidirectional linkage illumination mode in the step S3 specifically includes the following steps:
s3.1, comparing the current intelligent induction lamp with monitoring data of an environment monitoring module according to the preset trigger strategy, and controlling the lighting scene mode of the lighting module through a controller according to a comparison result; simultaneously, sending unidirectional linkage instructions to other intelligent sensing lamps in the same group adjacent to the unidirectional linkage instructions;
s3.2, when other intelligent sensing lamps in the same group adjacent to the current intelligent sensing lamp receive the unidirectional linkage instruction, firstly checking the validity of the unidirectional linkage instruction, if the unidirectional linkage instruction is valid, judging whether an illumination scene mode needs to be started according to monitoring data of an environment monitoring module of the unidirectional linkage instruction, if not, responding to a linkage illumination request of the unidirectional linkage instruction, if so, responding to the linkage illumination request of the unidirectional linkage instruction and controlling the illumination scene mode of a light emitting module of the unidirectional linkage instruction through a controller according to the monitoring data of the unidirectional linkage instruction; and if the unidirectional linkage instruction is invalid, not responding to the linkage illumination request of the unidirectional linkage instruction.
4. The intelligent induction control method according to claim 3, characterized in that: the validity auditing method of the linkage instruction in the step S3.2 is as follows:
defining the preset induction duration of the current intelligent induction lamp as T, and defining the real-time induction duration of the current intelligent induction lamp as T;
defining an intelligent induction lamp A and an intelligent induction lamp B which are in the same group as the current intelligent induction lamp and are adjacent to each other, wherein the intelligent induction lamp A and the intelligent induction lamp B are not adjacent to each other;
the intelligent induction lamp A is assumed to sense a target object signal and effectively link the current intelligent induction lamp;
if the real-time sensing duration T of the current intelligent sensing lamp is less than T, when the current intelligent sensing lamp senses a signal of a target object, the linkage instruction sent to the intelligent sensing lamp B by the current intelligent sensing lamp is effective at the moment, and the linkage instruction sent to the intelligent sensing lamp A is ineffective, namely one-way linkage, until the real-time sensing duration T of the current intelligent sensing lamp is relieved;
if the real-time induction duration T of the current intelligent induction lamp is less than T, when the intelligent induction lamp B induces a signal of a target object, the linkage instruction sent by the intelligent induction lamp B to the current intelligent induction lamp is still valid at the moment;
if the real-time sensing duration T of the current intelligent sensing lamp is more than or equal to T, when the current intelligent sensing lamp senses a signal of a target object, the linkage instruction sent to the intelligent sensing lamp A and the intelligent sensing lamp B by the current intelligent sensing lamp is effective.
5. The intelligent induction control method according to claim 1, characterized in that: the associating action of the associated lighting pattern in the step S4 comprises the following steps
S4.1, when the intelligent sensor compares the preset trigger strategy with the monitoring data of the environment monitoring module, an associated instruction is sent to an intelligent induction lamp associated with the intelligent sensor according to a comparison result;
s4.2, when the intelligent induction lamp associated with the intelligent induction lamp receives the association instruction, judging whether the illumination scene mode needs to be started or not according to monitoring data of an environment monitoring module of the intelligent induction lamp, if not, not responding to an association illumination request of the association instruction, if so, responding to the association illumination request of the association instruction and controlling the illumination scene mode of a light emitting module of the intelligent induction lamp through a controller according to the respective monitoring data.
6. The intelligent induction control method according to claim 1, characterized in that: the triggering mode of the preset triggering strategy is one or more of a timing triggering mode, a satellite positioning triggering mode and a light sensing triggering mode;
if the triggering mode of the preset triggering strategy is a timing triggering mode, presetting a timing time interval, and when the set timing starting node and timing ending node are reached, controlling the controller of the intelligent induction lamp or the intelligent sensor and controlling the lighting scene mode of the corresponding intelligent induction lamp lighting module;
if the triggering mode of the preset triggering strategy is a satellite positioning triggering mode, the controller of the intelligent induction lamp or the intelligent sensor acquires longitude and latitude information of the current region by receiving satellite positioning information, configures a sunrise and sunset time table according to the longitude and latitude information, and controls the illumination scene mode of the corresponding intelligent induction lamp light-emitting module according to the sunrise and sunset time table;
and if the triggering mode of the preset triggering strategy is a light sensing triggering mode, controlling the illumination scene mode of the corresponding intelligent sensing lamp light-emitting module by the controller of the intelligent sensing lamp or the intelligent sensor according to the illumination condition of the current region.
7. The intelligent induction control method according to any one of claims 2, 3, 5 or 6, characterized in that: the lighting scene modes comprise four modes of turning on a lamp, turning off the lamp, and self-defining dimming and color temperature adjustment.
8. The intelligent induction control method according to claim 7, characterized in that: the self-defined dimming comprises linear dimming and fixed-grid dimming, and the self-defined dimming is realized by controlling the output duty ratio of each set of lamp by the lighting control unit through PWM signals or 0-10V.
9. The intelligent induction control method according to claim 1, characterized in that: the intelligent sensing lamp and the sensing module of the intelligent sensor comprise one or more of a human body sensor, a light sensor and a radar sensor.
10. The intelligent induction control method according to claim 1, characterized in that: the environment monitoring module comprises one or more of a GPS satellite positioning element, an illuminance element, a fog sensing element, a haze sensing element, a wind speed sensing element, a human body sensing element, a temperature sensing element, a rainfall sensing element, a speed sensing element and a radar detection element.
11. The intelligent induction control method according to claim 1, characterized in that: the intelligent sensing lamp and the intelligent sensor are connected with each other in an interactive communication mode, and the intelligent sensing lamp and the intelligent sensor are used for acquiring running state parameters of the intelligent sensing lamp and the intelligent sensor, and storing, comparing, analyzing and processing the running state parameters to remotely monitor the intelligent sensing lamp and the intelligent sensor; the main control unit comprises a storage server, a data server and monitoring platform software.
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