阅读说明：本技术 智能感应控制方法 (Intelligent induction control method ) 是由 严飞飞 严少斌 牟金龙 于 2021-08-04 设计创作，主要内容包括：智能感应控制方法,基于智能感应控制系统,包括智能感应灯和智能传感器；智能感应灯的数目为n,n≥1,按区域或数量分成N组,N≥1,每组的各个智能感应灯之间呈单向联动照明模式或非单向联动照明模式；任意相邻两组智能感应灯之间呈关联照明模式或非关联照明模式,在关联照明模式下,相邻的两组智能感应灯之间感应区不相重合,且该两组智能感应灯之间至少设有一个所述智能传感器,且该两组智能感应灯中每组至少有一个智能感应灯与相应智能传感器交互无线通讯连接而关联；在非关联照明模式下,相邻的两组智能感应灯之间的感应区部分相重合。本发明可自定义设定自动开启时间、感应灯数量及照明情景模式类型,实现针对不同应用场景、不同时间段和所处环境室外光照强度自动切换至不同照明情景模式,从而在不影响感应灯正常作业状况下达到最大程度的节能。(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 areas or number, N is more than or equal to 1, and each intelligent induction lamp in each group is in a one-way linkage illumination mode or a non-one-way linkage illumination mode; any two adjacent groups of intelligent induction lamps are in an associated illumination mode or a non-associated illumination mode, in the associated illumination mode, the induction areas between the two adjacent groups of intelligent induction lamps are not overlapped, at least one intelligent sensor is arranged between the two groups of intelligent induction lamps, and at least one intelligent induction lamp in each group of the two groups of intelligent induction lamps is in interactive wireless communication connection with the corresponding intelligent sensor for association; in the non-related illumination mode, the sensing areas between the two adjacent groups of intelligent sensing lamps are partially overlapped. The invention can self-define and set the automatic turn-on time, the number of the induction lamps and the type of the lighting contextual model, and realize the automatic switching to different lighting contextual models aiming at 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 influencing the normal operation of the induction lamps.)

1. The intelligent induction control method is characterized by comprising the following steps: 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;

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 electrically connected with the controller;

the number of the intelligent induction lamps is N, N is more than or equal to 1, the N intelligent induction lamps are divided into N groups according to areas or number, N is more than or equal to 1, and the intelligent induction lamps in each group are in interactive wireless communication connection and are in a linkage illumination mode; the linkage lighting mode comprises a unidirectional linkage lighting mode and a non-unidirectional linkage lighting mode;

any two adjacent groups of intelligent induction lamps are in an associated illumination mode or a non-associated illumination mode, in the associated illumination mode, the induction areas between the two adjacent groups of intelligent induction lamps are not overlapped, at least one intelligent sensor is arranged between the two groups of intelligent induction lamps, and at least one intelligent induction lamp in each group of the two groups of intelligent induction lamps is in interactive wireless communication connection with the corresponding intelligent sensor for association; in the non-associated lighting mode, 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 induces a signal of a target object, the controller of the current intelligent induction lamp calls a preset trigger strategy of the current intelligent induction lamp, and compares the preset trigger strategy with monitoring data of an environment monitoring module to judge whether the preset trigger strategy is established or not; if the trigger strategy is established and triggered in the non-unidirectional linkage lighting mode, executing step S2; if the trigger strategy is established and the trigger strategy is the trigger strategy in the unidirectional linkage lighting mode, executing the step S3; if not, jumping to step S1;

if the current intelligent sensor senses a signal of a target object, a controller of the current intelligent sensor calls a preset trigger strategy of the current intelligent sensor, and compares the preset trigger strategy with monitoring data of an environment monitoring module to judge whether the preset trigger strategy is established or not; if yes, go to step S4; if not, jumping to step S1;

s2, the current intelligent induction lamp sends a non-unidirectional linkage instruction to other intelligent induction lamps in the same group, and informs other intelligent induction lamps in the same group of the current intelligent induction lamp to execute linkage action of the non-unidirectional linkage illumination mode;

s3, the current intelligent induction lamp sends a one-way linkage instruction to other adjacent intelligent induction lamps in the same group, and informs other adjacent intelligent induction lamps in the same group to execute linkage action of the one-way linkage lighting mode;

and S4, the current intelligent sensor sends an association instruction to the intelligent induction lamp associated with the current intelligent sensor, and the intelligent induction lamp associated with the current intelligent sensor is informed to execute the association action of the associated lighting mode.

2. The intelligent induction control method of claim 1, wherein: the linkage action of the non-unidirectional linkage lighting 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 thereof according to the preset trigger strategy, and controlling an illumination contextual model of a light emitting module thereof through a controller thereof according to a comparison result; meanwhile, a non-unidirectional linkage instruction is sent to other intelligent induction lamps in the same group of the current intelligent induction lamp;

and 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 contextual model needs to be started according to the monitoring data of the environment monitoring module of the current intelligent induction lamps respectively, if not, not responding to the linkage illumination request of the non-unidirectional linkage instruction, if so, responding to the linkage illumination request of the non-unidirectional linkage instruction and controlling the illumination contextual model of the light emitting module of the current intelligent induction lamps through respective controllers according to the monitoring data.

3. The intelligent induction control method of claim 1, wherein: the linkage action of the unidirectional linkage lighting 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 thereof according to the preset trigger strategy, and controlling the lighting scene mode of a light emitting module thereof through a controller thereof according to a comparison result; meanwhile, sending a one-way linkage instruction to other adjacent intelligent induction lamps in the same group;

s3.2 when other adjacent intelligent induction lamps in the same group adjacent to the current intelligent induction lamp receive the one-way linkage instruction, firstly checking the validity of the one-way linkage instruction, if the one-way linkage instruction is valid, judging whether an illumination scene mode needs to be started according to the monitoring data of the self environment monitoring module, if not, not responding to the linkage illumination request of the one-way linkage instruction, if so, responding to the linkage illumination request of the one-way linkage instruction and controlling the illumination scene mode of the light emitting module of the one-way linkage instruction through respective controllers according to the respective monitoring data; and if the one-way linkage instruction is invalid, not responding to the linkage illumination request of the one-way linkage instruction.

4. The intelligent induction control method of claim 3, wherein: the validity checking method of the linkage instruction in the step S3.2 comprises the following steps:

defining the preset sensing duration time of the current intelligent sensing lamp as T, and defining the real-time sensing duration time of the current intelligent sensing lamp as T;

defining that an intelligent induction lamp A and an intelligent induction lamp B are arranged in the intelligent induction lamps which are in the same group and adjacent to the current intelligent induction lamp, wherein the intelligent induction lamp A is not adjacent to the intelligent induction lamp B;

assuming that the intelligent induction lamp A induces a target object signal and effectively links with the current intelligent induction lamp;

if the real-time sensing duration time T of the current intelligent sensing lamp is less than T and 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, and the linkage instruction sent to the intelligent sensing lamp A is invalid, namely unidirectional linkage, until the real-time sensing duration time of the current intelligent sensing lamp is released when T is reached;

if the real-time sensing duration time T of the current intelligent sensing lamp is less than T and the intelligent sensing lamp B senses a signal of a target object, the linkage instruction sent to the current intelligent sensing lamp by the intelligent sensing lamp B is still effective;

if the real-time sensing duration time T of the current intelligent sensing lamp is longer than or equal to T, and the current intelligent sensing lamp senses the signal of the target object, the linkage instruction sent by the current intelligent sensing lamp to the intelligent sensing lamp A and the intelligent sensing lamp B is effective.

5. The intelligent induction control method of claim 1, wherein: the associating act of associating the 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 thereof according to the preset trigger strategy, sending an association instruction to the intelligent induction lamp associated with the intelligent sensor according to the comparison result;

and S4.2, when the intelligent induction lamp associated with the intelligent induction lamp receives the association instruction, judging whether the lighting contextual model needs to be started 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 contextual model of the light emitting module of the intelligent induction lamp through the controller according to the monitoring data of the intelligent induction lamp.

6. The intelligent induction control method of claim 1, wherein: the trigger mode of the preset trigger strategy is one or more of a timing trigger mode, a satellite positioning trigger mode and a light induction trigger mode;

if the trigger mode of the preset trigger strategy is a timing trigger mode, presetting a timing time interval, and when a set timing start node and a set timing end node are reached, controlling the lighting scene mode of the corresponding intelligent induction lamp light-emitting module by the controller of the intelligent induction lamp or the intelligent sensor;

if the trigger mode of the preset trigger strategy is a satellite positioning trigger 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, and configures a sunrise and sunset time table according to the longitude and latitude information, and controls the lighting scene mode corresponding to the light emitting module of the intelligent induction lamp according to the sunrise and sunset time table;

and if the trigger mode of the preset trigger strategy is a light-induced trigger mode, the controller of the intelligent induction lamp or the intelligent sensor controls the lighting scene mode of the light-emitting module of the corresponding intelligent induction lamp according to the lighting condition of the current region.

7. The intelligent induction control method according to any one of claims 1-6, characterized in that: the lighting scene modes comprise four modes of turning on a lamp, turning off the lamp, customizing dimming and adjusting the color temperature.

8. The intelligent induction control method of claim 7, wherein: the custom dimming comprises linear dimming and freeze dimming, and the custom dimming is realized by controlling the output duty ratio of each set of the lamp by the lighting control unit through a PWM signal or 0-10V.

9. The intelligent induction control method of claim 1, wherein: the intelligent induction lamp and the induction 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 of claim 1, wherein: the environment monitoring module comprises one or more of a GPS satellite positioning element, a light illumination 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 of claim 1, wherein: the intelligent induction lamp and the intelligent sensor are in interactive communication connection, and the main control unit is used for storing, comparing, analyzing and processing the acquired running state parameters of the intelligent induction lamp and the intelligent sensor so as to remotely monitor the intelligent induction lamp and the intelligent sensor; the main control unit comprises a storage server, a data server and monitoring platform software.

Technical Field

The invention relates to an intelligent induction control method.

Background

The novel intelligent illuminating product can automatically control the light source to be lightened through the induction module during induction of the lamp, can automatically turn on illumination and automatically delay to turn off after people leave; the induction lamp is often installed in larger buildings in daily use, such as residential buildings, markets, hospitals, airports, urban roads and other public areas, so as to bring convenience to users in dark areas or when the light is dim; however, the existing induction lamp has the following disadvantages: firstly, the distance between induction lamps arranged in a plurality of public areas is far away at present, so that troubles of wire arrangement and wiring and unnecessary waste of resources are reduced as far as possible under the condition of meeting use requirements, and a person walks in a building; secondly, in two adjacent areas, due to the obstruction of a wall body or a door and the like, when a user leaves the current area and enters another area, the induction lamp in the other area cannot be started in advance, the user often experiences a previous blackened state, the condition of the other area cannot be predicted, the user is inconvenient to use, and the user experience is influenced; thirdly, the existing induction lamp can only be opened when sensing a person, and the brightness of the light can not be adjusted. However, the brightness of the lamp is required to be different under different ambient light levels, for example, the brightness of the lamp can be lower in cloudy days, and the brightness of the lamp needs to be higher at night, while the brightness of the existing induction 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 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; 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 electrically connected with the controller; the number of the intelligent induction lamps is N, N is more than or equal to 1, the N intelligent induction lamps are divided into N groups according to areas or number, N is more than or equal to 1, and the intelligent induction lamps in each group are in interactive wireless communication connection and are in a linkage illumination mode; the linkage lighting mode comprises a unidirectional linkage lighting mode and a non-unidirectional linkage lighting mode; any two adjacent groups of intelligent induction lamps are in an associated illumination mode or a non-associated illumination mode, in the associated illumination mode, the induction areas between the two adjacent groups of intelligent induction lamps are not overlapped, at least one intelligent sensor is arranged between the two groups of intelligent induction lamps, and at least one intelligent induction lamp in each group of the two groups of intelligent induction lamps is in interactive wireless communication connection with the corresponding intelligent sensor for association; in the non-related illumination mode, the sensing areas between the 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 induces a signal of a target object, the controller of the current intelligent induction lamp calls a preset trigger strategy of the current intelligent induction lamp, and compares the preset trigger strategy with monitoring data of an environment monitoring module to judge whether the preset trigger strategy is established or not; if the trigger strategy is established and triggered in the non-unidirectional linkage lighting mode, executing step S2; if the trigger strategy is established and the trigger strategy is the trigger strategy in the unidirectional linkage lighting mode, executing the step S3; if not, jumping to step S1;

if the current intelligent sensor senses a signal of a target object, a controller of the current intelligent sensor calls a preset trigger strategy of the current intelligent sensor, and compares the preset trigger strategy with monitoring data of an environment monitoring module to judge whether the preset trigger strategy is established or not; if yes, go to step S4; if not, jumping to step S1;

s2, the current intelligent induction lamp sends a non-unidirectional linkage instruction to other intelligent induction lamps in the same group, and informs other intelligent induction lamps in the same group of the current intelligent induction lamp to execute linkage action of the non-unidirectional linkage illumination mode;

s3, the current intelligent induction lamp sends a one-way linkage instruction to other adjacent intelligent induction lamps in the same group, and informs other adjacent intelligent induction lamps in the same group to execute linkage action of the one-way linkage lighting mode;

and S4, the current intelligent sensor sends an association instruction to the intelligent induction lamp associated with the current intelligent sensor, and the intelligent induction lamp associated with the current intelligent sensor is informed to execute the association action of the associated lighting mode.

In the above technical solution, the linkage action of the non-unidirectional linkage lighting 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 thereof according to the preset trigger strategy, and controlling an illumination contextual model of a light emitting module thereof through a controller thereof according to a comparison result; meanwhile, a non-unidirectional linkage instruction is sent to other intelligent induction lamps in the same group of the current intelligent induction lamp;

and 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 contextual model needs to be started according to the monitoring data of the environment monitoring module of the current intelligent induction lamps respectively, if not, not responding to the linkage illumination request of the non-unidirectional linkage instruction, if so, responding to the linkage illumination request of the non-unidirectional linkage instruction and controlling the illumination contextual model of the light emitting module of the current intelligent induction lamps through respective controllers according to the monitoring data.

In the above technical solution, the linkage action of the unidirectional linkage lighting 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 thereof according to the preset trigger strategy, and controlling the lighting scene mode of a light emitting module thereof through a controller thereof according to a comparison result; meanwhile, sending a one-way linkage instruction to other adjacent intelligent induction lamps in the same group;

s3.2 when other adjacent intelligent induction lamps in the same group adjacent to the current intelligent induction lamp receive the one-way linkage instruction, firstly checking the validity of the one-way linkage instruction, if the one-way linkage instruction is valid, judging whether an illumination scene mode needs to be started according to the monitoring data of the self environment monitoring module, if not, not responding to the linkage illumination request of the one-way linkage instruction, if so, responding to the linkage illumination request of the one-way linkage instruction and controlling the illumination scene mode of the light emitting module of the one-way linkage instruction through respective controllers according to the respective monitoring data; and if the one-way linkage instruction is invalid, not responding to the linkage illumination request of the one-way linkage instruction.

In the above technical solution, the method for checking the validity of the unidirectional linkage instruction in step S3.2 is as follows:

defining the preset sensing duration time of the current intelligent sensing lamp as T, and defining the real-time sensing duration time of the current intelligent sensing lamp as T; defining that an intelligent induction lamp A and an intelligent induction lamp B are arranged in the intelligent induction lamps which are in the same group and adjacent to the current intelligent induction lamp, wherein the intelligent induction lamp A is not adjacent to the intelligent induction lamp B;

assuming that the intelligent induction lamp A induces a target object signal and effectively and unidirectionally links the current intelligent induction lamp;

if the real-time sensing duration time T of the current intelligent sensing lamp is less than T and the current intelligent sensing lamp senses a signal of a target object, the one-way linkage instruction sent to the intelligent sensing lamp B by the current intelligent sensing lamp is effective, and the one-way linkage instruction sent to the intelligent sensing lamp A is invalid, namely one-way linkage, and the current intelligent sensing lamp is released until the real-time sensing duration time T of the current intelligent sensing lamp reaches T;

if the real-time sensing duration time T of the current intelligent sensing lamp is less than T and the intelligent sensing lamp B senses a signal of a target object, the one-way linkage instruction sent to the current intelligent sensing lamp by the intelligent sensing lamp B is still effective;

if the real-time sensing duration time T of the current intelligent sensing lamp is longer than or equal to T, and the current intelligent sensing lamp senses the signal of the target object, the one-way 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 operation of associating the lighting pattern in 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 thereof according to the preset trigger strategy, sending an association instruction to the intelligent induction lamp associated with the intelligent sensor according to the comparison result;

and S4.2, when the intelligent induction lamp associated with the intelligent induction lamp receives the association instruction, judging whether the lighting contextual model needs to be started 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 contextual model of the light emitting 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 trigger mode of the preset trigger policy is one or more of a timing trigger mode, a satellite positioning trigger mode and a light sensing trigger mode; if the trigger mode of the preset trigger strategy is a timing trigger mode, presetting a timing time interval, and when a set timing start node and a set timing end node are reached, controlling the lighting scene mode of the corresponding intelligent induction lamp light-emitting module by the controller of the intelligent induction lamp or the intelligent sensor; if the trigger mode of the preset trigger strategy is a satellite positioning trigger 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, and configures a sunrise and sunset time table according to the longitude and latitude information, and controls the lighting scene mode corresponding to the light emitting module of the intelligent induction lamp according to the sunrise and sunset time table; and if the trigger mode of the preset trigger strategy is a light-induced trigger mode, the controller of the intelligent induction lamp or the intelligent sensor controls the lighting scene mode of the light-emitting module of the corresponding intelligent induction lamp according to the lighting condition of the current region.

In the above technical solution, the lighting scene mode includes four modes of turning on a light, turning off the light, self-defining dimming and color temperature adjustment.

In the above technical scheme, the custom dimming includes linear dimming and freeze dimming, and the custom dimming is realized by the lighting control unit controlling the output duty cycle of each set of the lamp through a PWM signal or 0-10V.

In the above technical scheme, the sensing modules of the intelligent sensing lamp and the intelligent sensor all include one or more of a human body sensor, a light sensor and a radar sensor.

In the above technical solution, the environment monitoring module includes one or more of a GPS satellite positioning element, a light illumination 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 the technical scheme, the intelligent induction lamp remote monitoring 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 is used for storing, comparing, analyzing and processing the acquired running 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.

Compared with the prior art, the invention has the beneficial effects that:

according to the intelligent induction control method, the automatic starting time, the number of the induction lamps and the type of the lighting contextual model of the intelligent induction control system can be set in a self-defined manner, and the outdoor illumination intensity can be automatically switched to different lighting contextual models according to different application scenes, different time periods and environments, so that the maximum energy conservation is achieved under the condition that the normal operation of the induction lamps is not influenced; meanwhile, the induction linkage mode can be set on an object moving path in a user-defined mode, and an intelligent and convenient induction control scheme is provided.

According to the invention, two modes, namely an associated illumination mode and a non-associated illumination mode, are selected between any two adjacent groups of intelligent induction lamps, and under the associated illumination mode, the induction lamps in the adjacent regions can be turned on in advance by adding the intelligent sensor between the two adjacent groups of intelligent induction lamps with the induction regions not overlapped and associating part of the induction lamps in the two adjacent groups of intelligent induction lamps with the intelligent sensor, so that the defects of long interval between the two adjacent groups of intelligent induction lamps or barrier blockage and the like can be effectively overcome, the induction blind area can be effectively eliminated, and the user experience can be enhanced.

The linkage mode among the intelligent induction lamps in the same group is divided into a one-way linkage lighting mode and a non-one-way linkage lighting mode, and all the linkage intelligent induction lamps can be instantly turned on under the condition that large-area lighting needs to be turned on simultaneously in meeting halls, broadcasting halls, large classrooms and the like, so that the user experience is enhanced; and the illumination of long and narrow regions such as galleries, stairs and the like can be realized by adopting one-way linkage illumination, the effect of gradually turning on and gradually turning off is realized, the normal illumination requirement can be met, and the maximum energy conservation can be realized.

The system is provided with a preset trigger strategy to control different groups of intelligent induction lamps, the trigger modes comprise a timing trigger mode, a satellite positioning trigger mode and a light induction trigger mode, and the modes can be independently set and applied or can be combined; the intelligent induction control system can be selected by self-definition according to different practical application scenes, the normal operation requirements of the induction lamp are met, meanwhile, the energy is effectively saved, the utilization rate of the induction lamp in the operation environment of the induction control system is improved, the resource waste is reduced, and meanwhile, the modernization management level of the intelligent induction control system is improved.

Drawings

Fig. 1 is a schematic diagram of an intelligent sensing control method according to an embodiment of the present invention.

Fig. 2 is a schematic diagram of a validity checking method of a unidirectional linkage instruction in an embodiment of the present invention.

Wherein: 1. an intelligent induction lamp A; 2. current intelligent induction lights; 3. an intelligent induction lamp B; a signal representing a target object; the status of the intelligent induction lamp when the unidirectional linkage instruction is responded is indicated;the state of the intelligent induction lamp is shown when the unidirectional linkage instruction is not responded; either ← or → denotes a one-way gang instruction direction, the arrow of which points to a one-way gang direction.

Detailed Description

The invention is described in detail below with reference to the attached drawing figures:

example 1

Referring to fig. 1, the intelligent sensing control method is based on an intelligent sensing control system, which includes an intelligent sensing 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; 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 electrically connected with the controller; the number of the intelligent induction lamps is N, N is more than or equal to 1, the N intelligent induction lamps are divided into N groups according to areas or number, N is more than or equal to 1, and the intelligent induction lamps in each group are in interactive wireless communication connection and are in a linkage illumination mode; the linkage lighting mode comprises a unidirectional linkage lighting mode and a non-unidirectional linkage lighting mode; any two adjacent groups of intelligent induction lamps are in an associated illumination mode or a non-associated illumination mode, in the associated illumination mode, the induction areas between the two adjacent groups of intelligent induction lamps are not overlapped, at least one intelligent sensor is arranged between the two groups of intelligent induction lamps, and at least one intelligent induction lamp in each group of the two groups of intelligent induction lamps is in interactive wireless communication connection with the corresponding intelligent sensor for association; in the non-associated lighting mode, 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 induces a signal of a target object, the controller of the current intelligent induction lamp calls a preset trigger strategy of the current intelligent induction lamp, and compares the preset trigger strategy with monitoring data of an environment monitoring module to judge whether the preset trigger strategy is established or not; if the trigger strategy is established and triggered in the non-unidirectional linkage lighting mode, executing step S2; if the trigger strategy is established and the trigger strategy is the trigger strategy in the unidirectional linkage lighting mode, executing the step S3; if not, jumping to step S1;

if the current intelligent sensor senses a signal of a target object, a controller of the current intelligent sensor calls a preset trigger strategy of the current intelligent sensor, and compares the preset trigger strategy with monitoring data of an environment monitoring module to judge whether the preset trigger strategy is established or not; if yes, go to step S4; if not, jumping to step S1;

s2, the current intelligent induction lamp sends a linkage instruction to other intelligent induction lamps in the same group, and informs other intelligent induction lamps in the same group of the current intelligent induction lamp to execute linkage action of the non-unidirectional linkage illumination mode;

s3, the current intelligent induction lamp sends a linkage instruction to other adjacent intelligent induction lamps in the same group, and informs other adjacent intelligent induction lamps in the same group of the intelligent induction lamps to execute linkage action of the unidirectional linkage lighting mode;

and S4, the current intelligent sensor sends an association instruction to the intelligent induction lamp associated with the current intelligent sensor, and the intelligent induction lamp associated with the current intelligent sensor is informed to execute the association action of the associated lighting mode.

In a preferred but non-limiting embodiment of the present invention, the linkage action of the non-unidirectional linkage lighting 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 thereof according to the preset trigger strategy, and controlling an illumination contextual model of a light emitting module thereof through a controller thereof according to a comparison result; meanwhile, a non-unidirectional linkage instruction is sent to other intelligent induction lamps in the same group of the current intelligent induction lamp;

and 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 contextual model needs to be started according to the monitoring data of the environment monitoring module of the current intelligent induction lamps respectively, if not, not responding to the linkage illumination request of the non-unidirectional linkage instruction, if so, responding to the linkage illumination request of the non-unidirectional linkage instruction and controlling the illumination contextual model of the light emitting module of the current intelligent induction lamps through respective controllers according to the monitoring data.

In a preferred but non-limiting embodiment of the present invention, the linkage action of the unidirectional linkage lighting 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 thereof according to the preset trigger strategy, and controlling the lighting scene mode of a light emitting module thereof through a controller thereof according to a comparison result; meanwhile, sending a one-way linkage instruction to other adjacent intelligent induction lamps in the same group;

s3.2 when other adjacent intelligent induction lamps in the same group adjacent to the current intelligent induction lamp receive the one-way linkage instruction, firstly checking the validity of the one-way linkage instruction, if the one-way linkage instruction is valid, judging whether an illumination scene mode needs to be started according to the monitoring data of the self environment monitoring module, if not, not responding to the linkage illumination request of the one-way linkage instruction, if so, responding to the linkage illumination request of the one-way linkage instruction and controlling the illumination scene mode of the light emitting module of the one-way linkage instruction through respective controllers according to the respective monitoring data; and if the one-way linkage instruction is invalid, not responding to the linkage illumination request of the one-way 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 one-way linkage command in step S3.2 is as follows: defining the preset sensing duration time of the current intelligent sensing lamp as T, and defining the real-time sensing duration time of the current intelligent sensing lamp as T; defining that an intelligent induction lamp A and an intelligent induction lamp B are arranged in the intelligent induction lamps which are in the same group and adjacent to the current intelligent induction lamp, wherein the intelligent induction lamp A is not adjacent to the intelligent induction lamp B;

assuming that the intelligent induction lamp A induces a target object signal and effectively and unidirectionally links the current intelligent induction lamp;

if the real-time sensing duration time T of the current intelligent sensing lamp is less than T and the current intelligent sensing lamp senses a signal of a target object, the one-way linkage instruction sent to the intelligent sensing lamp B by the current intelligent sensing lamp is effective, and the one-way linkage instruction sent to the intelligent sensing lamp A is invalid, namely one-way linkage, and the current intelligent sensing lamp is released until the real-time sensing duration time T of the current intelligent sensing lamp reaches T; it should be noted that the unidirectional linkage of the present invention has timeliness, for example, if the intelligent induction lamp a is effective to unidirectionally link the current intelligent induction lamp, if T is less than T, when the current intelligent induction lamp senses the target object signal again, the unidirectional linkage instruction sent by the current intelligent induction lamp to the intelligent induction lamp a is invalid at this time; 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 recovered to be effective again.

If the real-time sensing duration time T of the current intelligent sensing lamp is less than T and the intelligent sensing lamp B senses a signal of a target object, the one-way linkage instruction sent to the current intelligent sensing lamp by the intelligent sensing lamp B is still effective;

if the real-time sensing duration time T of the current intelligent sensing lamp is longer than or equal to T, and the current intelligent sensing lamp senses the signal of the target object, the one-way 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 act of associating the associated lighting pattern in 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 thereof according to the preset trigger strategy, sending an association instruction to the intelligent induction lamp associated with the intelligent sensor according to the comparison result;

and S4.2, when the intelligent induction lamp associated with the intelligent induction lamp receives the association instruction, judging whether the lighting contextual model needs to be started 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 contextual model of the light emitting 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 trigger mode of the preset trigger strategy is one or more of a timing trigger mode, a satellite positioning trigger mode and a light sensing trigger mode;

if the trigger mode of the preset trigger strategy is a timing trigger mode, presetting a timing time interval, and when a set timing start node and a set timing end node are reached, controlling the lighting scene mode of the corresponding intelligent induction lamp light-emitting module by the controller of the intelligent induction lamp or the intelligent sensor;

if the trigger mode of the preset trigger strategy is a satellite positioning trigger 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, and configures a sunrise and sunset time table according to the longitude and latitude information, and controls the lighting scene mode corresponding to the light emitting module of the intelligent induction lamp according to the sunrise and sunset time table;

and if the trigger mode of the preset trigger strategy is a light-induced trigger mode, the controller of the intelligent induction lamp or the intelligent sensor controls the lighting scene mode of the light-emitting module of the corresponding intelligent induction lamp according to the lighting condition of the current region.

In a preferred but nonlimiting embodiment of the present invention, the lighting profiles include four modes, i.e., light on, light off, custom dimming, and color temperature.

In a preferred but non-limiting embodiment of the present invention, the custom dimming includes linear dimming and freeze dimming, and the custom dimming is implemented by the lighting control unit controlling the output duty cycle of each set of the lamps through a PWM signal 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 include 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 environment monitoring module comprises one or more of a GPS satellite positioning element, a light illumination 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 present invention 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 is configured to perform storage, comparison, analysis and processing according to the obtained operating state parameters of the intelligent sensing lamps and the intelligent sensors, so as to perform remote monitoring on the intelligent sensing lamps and the intelligent sensors; the main control unit comprises a storage server, a data server and monitoring platform software.

Example 2

The following describes application scenarios of different trigger modes of the preset trigger policy.

In a timing mode, for example, in an airport, within a time period of 18:30 at night to 1:00 at early morning, when a flight is busy, a timing starting node of the intelligent induction lamps in the operation area can be pre-designated to be 18:30, the brightness is adjusted to 100%, at the moment, once the designated time is reached, all designated intelligent induction lamps are automatically started, and the normal and safe operation of the operation is guaranteed; in the time period of 1:30 to 6:30 in the morning, the number of flights is small, and the brightness of the intelligent induction lamp in the designated operation area of the airport can be preset to be adjusted to 50 percent so as to realize energy conservation and consumption reduction. In the time period of 6:30 in the morning to 18:30 in the evening, the illumination meets the requirement, the lamp does not need to be turned on, and the lamp turning-off time of the intelligent induction lamp in the operation area can be specified in advance to be 6: 30.

In the GPS mode, the system automatically calculates sunrise and sunset time according to the GPS, automatically turns off the lamp according to the sunrise time and automatically turns on the lamp according to the sunset time.

Under the photoinduction mode, whether intelligent induction lamp controller can be according to current illumination condition, whether automatic judgement need turn on the light or turn off the light, for example face overcast and rainy weather, haze weather in daytime, lead to illumination not enough, and the illumination is opened automatically to the current condition of intelligence response lamp perception, and after current illumination resumes, the self-closing illumination.

In a mixed mode, namely timing + GPS, timing + light sensation + GPS and the like, intelligent induction illumination is realized by combination in any mode.

Example 3

The application scenario of the unidirectional linked illumination mode will be described below.

For example, large hotel corridor, long and narrow and not have illumination throughout the year, can press the structure interval distribution intelligence response lamp of gallery, one-way linkage between the adjacent intelligence response lamp, be in the low luminance lighting status when can setting up unmanned walking in order to guarantee the visual effect of gallery and open 10% like luminance, one-way mode is started when the perception people walks, open gradually along the pedestrian direction under one-way linkage mode, keep away from the pedestrian direction and put out gradually to low luminance mode, under the condition that guarantees consumer experience, realize the maximize and save energy.

The embodiments of the present invention are merely illustrative, and not restrictive, of the scope of the claims, and other substantially equivalent alternatives may occur to those skilled in the art and are within the scope of the present invention.