CN116149195A - Equipment management method and system - Google Patents

Abstract

A device management method and system relates to the technical field of terminals, wherein the device management system comprises a plurality of terminals, a plurality of first sensors, one or more ring control devices and one or more execution devices, one or more second sensors are arranged in the terminals, and the device management system comprises: the method comprises the steps that first environment data are collected in a first sensor, and the first environment data are sent to environmental control equipment; collecting second environmental data in a second sensor, and sending the second environmental data to the environmental control equipment by a corresponding terminal; the environmental control equipment receives the first environmental data and the second environmental data, and determines target environmental data of each execution equipment according to a preset environmental control strategy according to the first environmental data and the second environmental data; the environmental control equipment sends corresponding target environment data to the execution equipment; the execution device receives the target environment data and adjusts the current environment data to the target environment data. According to the scheme, parameters of equipment in a store can be timely adjusted according to actual environmental changes.

Description

Equipment management method and system

Technical Field

The present application relates to the field of terminal technologies, and in particular, to a device management method and system.

Background

In some off-line retail stores, parameters (e.g., illuminance, temperature and humidity, sound size, fragrance concentration, etc.) corresponding to devices in the store are fixed values, and cannot be automatically adjusted based on changes in internal and external environments, so that an optimal experience environment cannot be provided in combination with actual environmental conditions.

In order to solve this problem, in the conventional art, a designer, a clerk, or other maintenance personnel usually manually adjusts data of each device of the store according to the actual environment of the store. However, after the internal and external environments of the store are adjusted, the staff of the store needs to manually adjust the environment multiple times, so that the adjustment process is complicated, and the real-time optimal environment of the store cannot be ensured.

Disclosure of Invention

The embodiment of the application provides a device management method and a system, which can timely adjust parameters of devices in a store according to actual environment changes and provide optimal experience environments for customers in the store in real time.

In order to achieve the above purpose, the embodiments of the present application adopt the following technical solutions:

in a first aspect, a device management method is provided and applied to a device management system, where the device management system includes a plurality of terminals, a plurality of first sensors, one or more ring control devices, and one or more execution devices; wherein, a plurality of terminals are arranged at the fixed position of one or a plurality of display tables in the exhibition hall, and one or a plurality of second sensors are arranged in the plurality of terminals; the plurality of first sensors include an illumination sensor, a temperature sensor, a humidity sensor, an air quality sensor, a rain sensor, and an odor detection sensor, and the one or more second sensors include a microphone sensor, a temperature sensor, a humidity sensor, an odor detection sensor, and a light sensor; data collected by a first sensor and a second sensor distributed in different areas of an exhibition hall are used for controlling unused execution equipment, and the equipment management method comprises the following steps:

Each first sensor of the plurality of first sensors collects first environmental data and sends the first environmental data to one or more environmental control devices; each of the one or more second sensors collects second environmental data, and the plurality of terminals send the second environmental data to the one or more environmental control devices; one or more pieces of environmental control equipment receive the first environmental data and the second environmental data, and determine target environmental data of each piece of execution equipment in one or more pieces of execution equipment according to a preset environmental control strategy according to the first environmental data and the second environmental data; wherein the target environmental data includes any one of illumination intensity, temperature, humidity, air quality, sound parameters, and odor concentration; one or more environmental control devices send corresponding target environment data to one or more execution devices; one or more execution devices receive the target environmental data and adjust the current environmental data to the target environmental data.

In the embodiment of the application, the acquisition of the environmental data is performed in real time based on the second sensor of the prototype terminal and the first sensor in the store, so that the real-time control of the store environment can be realized, and the manpower is saved. The intelligent environmental control system is in real-time linkage with the terminal, the first sensor and the execution equipment system, and sends an adjusting instruction to the execution equipment system according to the environmental data collected by the second sensor and the first sensor of the terminal and a preset equipment model to instruct the execution equipment system to adjust corresponding environmental data of corresponding execution equipment, so that the environmental data of each execution equipment of a store are always in an optimal environmental experience interval, and the experience environment of a user in the store is optimized.

In a possible implementation manner of the first aspect, the preset environmental control policy configures one or more environmental control devices, where the preset environmental control policy is used to indicate a plurality of environmental data ranges and target environmental data corresponding to each environmental data range. The determining, according to the first environment data and the second environment data and according to a preset environmental control policy, target environment data of each of one or more execution devices includes: the one or more environmental control devices determine actual environmental data of each of a plurality of areas where the plurality of first sensors and the one or more second sensors are located according to the first environmental data and the second environmental data; and the one or more environmental control devices determine target environmental data corresponding to the environmental data range of the actual environmental data of each area according to a preset environmental control strategy.

In the embodiment of the application, the preset environmental control policy in the environmental control device includes a preset corresponding relation between the environmental data range where the collected data is located and the target environmental data, and when determining the target environmental data of the environmental data, the environmental control device can determine the target environmental data corresponding to the current environmental data according to the preset environmental control policy, so that the method can reduce the data calculation amount and improve the calculation efficiency of the target environmental data.

In a possible implementation manner of the first aspect, the one or more environmental control devices are further configured with a correspondence between the first sensor and the second sensor distributed in different areas of the exhibition hall and the one or more execution devices. The one or more environmental control devices send corresponding target environment data to one or more execution devices, including: and the one or more environmental control devices send corresponding target environment data to the one or more execution devices according to the corresponding relation.

In the embodiment of the present application, the environmental control device includes a preset correspondence between the terminal and the execution device, and when determining the target execution device, the environmental control device may determine, according to the correspondence, that the execution device corresponding to the terminal identifier is the target execution device. Because the equipment management system comprises a plurality of terminals, a plurality of first sensors and a plurality of execution equipment, the corresponding relation between the terminals and the first sensors and the execution equipment is constructed in advance, and the control granularity is refined, so that the regulation result of the environmental data around the terminals meets the requirements of users.

In a possible implementation manner of the first aspect, the device management system further includes a passenger flow system, where the passenger flow system is configured to collect passenger flow data. The determining, according to the first environment data and the second environment data and according to a preset environmental control policy, target environment data of each of one or more execution devices includes: one or more environmental control devices receive passenger flow data sent by a passenger flow system; and the one or more environmental control devices refer to the passenger flow data, and determine target environmental data of each of the one or more execution devices according to the first environmental data and the second environmental data and a preset environmental control strategy. In the embodiment of the application, the integrated linkage analysis control of peripheral systems such as passenger flow is combined, so that the adjustment of the environment is more accurate.

In a possible implementation manner of the first aspect, the method further includes: the plurality of first sensors establish communication connection with one or more environmental control devices; the terminal where the one or more second sensors are located establishes a communication connection with one or more ring control devices.

In a possible implementation manner of the first aspect, the adjusting the current environmental data to the target environmental data includes: and the one or more execution devices adjust the current environment data into target environment data according to preset adjustment steps. In the embodiment of the application, the execution device adjusts the environmental data according to the preset adjustment step by step, so that the adjustment effect is achieved in a softer adjustment mode, and the user in the environment is not subjected to environmental abrupt change.

In a second aspect, a device management system is provided, the system comprising a plurality of terminals, a plurality of first sensors, one or more loop control devices, and one or more execution devices; wherein, a plurality of terminals are arranged at the fixed position of one or a plurality of display tables in the exhibition hall, and one or a plurality of second sensors are arranged in the plurality of terminals; the plurality of first sensors include an illumination sensor, a temperature sensor, a humidity sensor, an air quality sensor, a rain sensor, and an odor detection sensor, and the one or more second sensors include a microphone sensor, a temperature sensor, a humidity sensor, an odor detection sensor, and a light sensor; data collected by a first sensor and a second sensor distributed in different areas of an exhibition hall for controlling unused execution equipment, the system comprising:

Wherein, each first sensor in the plurality of first sensors gathers first environmental data, sends first environmental data to one or more environmental control equipment. Each of the one or more second sensors collects second environmental data, and the plurality of terminals send the second environmental data to one or more environmental control devices; the one or more environmental control devices receive the first environmental data and the second environmental data, and determine target environmental data of each of the one or more execution devices according to a preset environmental control strategy according to the first environmental data and the second environmental data; here, the target environmental data includes any one of illumination intensity, temperature, humidity, air quality, sound parameters, and odor concentration. The one or more environmental control devices send corresponding target environmental data to the one or more execution devices, receive the target environmental data, and adjust the current environmental data to the target environmental data.

In the embodiment of the application, the second sensor built in the terminal can be used for replacing a traditional instrument to collect the environmental data in the equipment management system, so that the equipment management cost is reduced. The environmental control equipment determines target environmental data according to the environmental data acquired by the terminal and the first sensor in real time and a preset environmental control strategy, and sends the target environmental data to the execution equipment, and the execution equipment performs control adjustment on the environmental data, so that the environmental data is always in an optimal experience interval.

In a possible implementation manner of the second aspect, the preset environmental control policy configures one or more environmental control devices, where the preset environmental control policy is used to indicate a plurality of environmental data ranges and target environmental data corresponding to each environmental data range.

The one or more environmental control devices can determine actual environmental data of each of a plurality of areas where the plurality of first sensors and the one or more second sensors are located according to the first environmental data and the second environmental data; and determining target environment data corresponding to the environment data range of the actual environment data of each area according to a preset environmental control strategy.

In the embodiment of the application, the preset environmental control policy in the environmental control device includes a preset corresponding relation between the environmental data range where the collected data is located and the target environmental data, and when determining the target environmental data of the environmental data, the environmental control device can determine the target environmental data corresponding to the current environmental data according to the preset environmental control policy, so that the method can reduce the data calculation amount and improve the calculation efficiency of the target environmental data.

In a possible implementation manner of the second aspect, the one or more environmental control devices are further configured with a correspondence between the first sensor and the second sensor distributed in different areas of the exhibition hall and the one or more execution devices. The one or more environmental control devices may send corresponding target environment data to the one or more execution devices according to the correspondence.

In the embodiment of the present application, the environmental control device includes a preset correspondence between the terminal and the execution device, and when determining the target execution device, the environmental control device may determine, according to the correspondence, that the execution device corresponding to the terminal identifier is the target execution device. Because the equipment management system comprises a plurality of terminals, a plurality of first sensors and a plurality of execution equipment, the corresponding relation between the terminals and the first sensors and the execution equipment is constructed in advance, the control granularity is thinned, and the regulation result of the environmental data around the terminals is more in line with the requirements of users.

In a possible implementation manner of the second aspect, the device management system further includes a passenger flow system, where the passenger flow system is used to collect passenger flow data. One or more environmental control devices receive passenger flow data sent by a passenger flow system; and determining target environment data of each execution device in the one or more execution devices according to the first environment data and the second environment data and a preset environmental control strategy. In the embodiment of the application, the integrated linkage analysis control of peripheral systems such as passenger flow is combined, so that the adjustment of the environment is more accurate.

In a possible implementation manner of the second aspect, the system further includes: the plurality of first sensors establish communication connection with one or more environmental control devices; the terminal where the one or more second sensors are located establishes a communication connection with one or more ring control devices.

In a possible implementation manner of the second aspect, the one or more execution devices may adjust the current environmental data to the target environmental data according to a preset adjustment step. In the embodiment of the application, the execution device adjusts the environmental data according to the preset adjustment step by step, so that the adjustment effect is achieved in a softer adjustment mode, and the user in the environment is not subjected to environmental abrupt change.

In a third aspect, an electronic device is provided that includes a memory and one or more processors; the memory; the memory has stored therein computer program code comprising computer instructions which, when executed by the processor, cause the electronic device to perform the method as described for the first aspect of the controlling device or terminal or executing device described above.

In a fourth aspect, a computer readable storage medium is provided, having instructions stored therein, which when run on an electronic device, enable the electronic device to perform the device management method of any one of the first aspects above. The electronic device may be any of the devices described above in the device management system.

In a fifth aspect, there is provided a computer program product comprising instructions which, when run on a computer, cause the computer to perform the device management method of any of the first aspects above. The computer may be any of the devices of the device management system described above.

In a sixth aspect, there is provided an apparatus (e.g. the apparatus may be a system-on-a-chip) comprising a processor for supporting a first device to implement the functionality referred to in the first aspect above. In one possible design, the apparatus further includes a memory for holding program instructions and data necessary for the first device. When the device is a chip system, the device can be formed by a chip, and can also comprise the chip and other discrete devices.

The technical effects of any one of the design manners of the second aspect to the sixth aspect may be referred to the technical effects of the different design manners of the first aspect, and will not be repeated here.

Drawings

Fig. 1 is an environmental schematic diagram of a display scenario provided in an embodiment of the present application;

fig. 2 is a schematic structural diagram of an integration scheme of a device management system according to an embodiment of the present application;

fig. 3 is a hardware structural block diagram of an electronic device according to an embodiment of the present application;

Fig. 4 is a flow chart of a device management method according to an embodiment of the present application;

FIG. 5 is a schematic flow chart of a device parameter adjustment according to an embodiment of the present disclosure;

FIG. 6 is a schematic flow chart of an illumination system adjustment according to an embodiment of the present disclosure;

fig. 7 is a schematic flow chart of curtain system adjustment according to an embodiment of the present disclosure;

fig. 8 is a schematic flow chart of sound system adjustment according to an embodiment of the present application;

fig. 9 is a schematic flow chart of an air conditioning system adjustment provided in an embodiment of the present application;

fig. 10 is a schematic flow chart of a fragrance system adjustment provided in an embodiment of the present application;

FIG. 11 is a schematic diagram of an influence factor of a device management system according to an embodiment of the present application;

fig. 12 is a schematic structural diagram of an electronic device according to an embodiment of the present application.

Detailed Description

The following description of the embodiments of the present application will be made clearly and fully with reference to the accompanying drawings, in which it is evident that the embodiments described are some, but not all, of the embodiments of the present application. All other embodiments, which can be made by one of ordinary skill in the art based on the embodiments herein without making any inventive effort, are intended to be within the scope of the present application.

The terms "first" and "second" are used below for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defining "a first" or "a second" may explicitly or implicitly include one or more such feature. In the description of the present application, unless otherwise indicated, the meaning of "a plurality" is two or more.

In some off-line retail stores or showrooms, lighting, curtains, air conditioning, sound, fragrance machines, etc. are typically provided to provide a better experience environment for customers in the store. The parameters corresponding to the equipment are fixed and are set by staff of a store when the store is opened. Such as the illuminance corresponding to the lighting equipment, the descending degree of the curtain, the temperature and wind speed of the air conditioner, the sound size, the fragrance concentration of the fragrance machine, and the like. If the environment outside the store changes, none of the devices can automatically adjust to the environment changes, but rather require the store's staff to manually adjust the parameters of the device. Because the environment inside and outside the store is changed in real time, the staff of the store may need to manually adjust the parameters of the device multiple times, resulting in a cumbersome adjustment process. Moreover, the staff of the store cannot guarantee that parameters of the equipment in the store can be adjusted in time, so that the best experience environment cannot be provided for customers in the store.

Taking a lighting device set in a store as an example, reference is made to the scene diagram shown in fig. 1. Fig. 1 shows a store with three terminals placed on a display stand, above which lighting devices are arranged. The terminal comprises a terminal A and a terminal A base, a terminal B and a terminal B bracket and a terminal C. The placement distances between the terminals a, B and C are not limited. Illustratively, the terminal a may be a mobile phone, the terminal B may be a tablet computer, and the terminal C may be a notebook computer. Optionally, the terminal may also be an intelligent bracelet, an intelligent watch, an intelligent sound box, an intelligent humidifier or other intelligent home devices, and other intelligent terminals. Wherein the lighting device can be arranged on the roof, the periphery of the wall and the like of the store. The number of the lighting devices can be one or more, and the lighting devices are used for emitting light rays to the display table so as to improve the illumination intensity around the display table and better highlight the display effect of the terminal on the display table. The lighting device can be different types of devices such as a spotlight, a lamp strip and the like.

In a store, a lighting device may illuminate a display stand, for example, a light strip illuminates a display stand. Alternatively, a lighting device may illuminate a terminal on a display stand, for example, a spotlight illuminates a terminal on a display stand. Alternatively, a plurality of illumination devices may illuminate a display stand, for example, a plurality of spot lights illuminate a display stand. Alternatively, a plurality of illumination devices may illuminate a terminal on a display stand, for example, a plurality of spot lights illuminate a terminal on a display stand. The correspondence of the lighting device to the object (display stand or terminal) it irradiates may be determined according to the actual situation.

Wherein the lighting device in the store is of fixed illumination intensity. For example, the lumen of the lighting device is 1500, and the lumen is kept 1500 until manually adjusted, without changing due to the illumination intensity of the ambient light. Where lumen is the unit of luminous flux. An object uniformly illuminated by light has an illumination intensity of 1 lux (i.e., lux or lx) when the resulting luminous flux over an area of 1 square meter is 1 lumen.

Since the lighting in the store is a fixed illumination intensity. When the internal ambient light of the store changes in different time periods and different seasons, the displayed terminal is affected by the ambient light, and the condition that the illumination intensity of the illumination equipment in the store is insufficient or the illumination intensity is too strong possibly exists, so that the display effect of the terminal is affected. Especially, for terminals with display screens, such as mobile phones, tablet computers, notebook computers, projectors, etc., the display screens are more affected by the internal ambient light of the store, and poor display effects can lead to reduced experience interests of users.

In the prior art, the existing problems can be improved by manually adjusting the illumination intensity of the illumination equipment in the store by staff in the store, but the manual adjustment method is complex in flow and cannot timely combine with an actual environment light scene to present the optimal illumination effect for the displayed terminal. Therefore, how to reduce the steps of equipment adjustment and adjust the parameters of the equipment in time according to the actual environmental changes, so as to provide the optimal experience environment for the customers in the store in real time is a problem to be solved.

In order to solve the above-mentioned problems, an embodiment of the present application provides an apparatus management method, which is applicable to an apparatus management system. The device management system comprises a plurality of terminals, a plurality of proprietary collection devices, one or more execution devices and one or more environmental control devices. The terminal is a prototype terminal for store display, such as a mobile phone, a tablet computer, a notebook computer, an air conditioner and the like. The terminals are placed at fixed positions of one or more display tables in a store (exhibition hall), and one or more second sensors are arranged in the terminals. The second sensor includes a microphone sensor, a temperature sensor, a humidity sensor, an odor detection sensor, and a light sensor. Different terminals are displayed in different stores, for example, if the terminals are mobile phones, tablet computers and notebook computers, the built-in second sensor can comprise a microphone sensor and a light sensor; if the terminal is an air conditioner, the built-in second sensor may include a temperature sensor and a humidity sensor; if the terminal is a fragrance machine, the built-in second sensor can be an odor detection sensor; if the terminal is acoustic, the built-in second sensor may be a microphone sensor.

The proprietary collection device may be a proprietary sensor (first sensor) mainly comprising a rain sensor, a temperature sensor, a humidity sensor, an illumination sensor, an air quality sensor, an odor detection sensor, etc.

In different equipment management scenes, different terminals are different from the execution equipment corresponding to the first sensor, namely, the data collected by the first sensor and the second sensor distributed in different areas of the exhibition hall are used for controlling the unused execution equipment.

For example, in a scenario where the environmental light of a store is managed based on the device management system, the terminal may be an electronic device with an illumination collection device (e.g., a light sensor) built in the store, such as a mobile phone, a tablet, a computer, etc.; the executing device may be a lighting device in a store, such as a spotlight, a lamp strip, a lamp curtain, etc.

For example, in a scene where the degree of curtain descent of a store is managed based on the device management system, the first sensor is an illumination sensor at a glass, a temperature sensor, a rain sensor, or the like; the actuating device may be a curtain in a store.

For example, in a scenario of managing sound of a store based on a device management system, the terminal may be an electronic device with a microphone sensor built in the store, such as a mobile phone, a tablet, a computer, a smart sound, etc.; the executing device may be an electronic device with a speaker in a store, such as a smart sound, a television, etc.

For example, in a scenario of managing the temperature and humidity of a store based on the device management system, the terminal may be an electronic device such as an air conditioner, a heater, etc. having a temperature sensor and a humidity sensor built in the store; the executing device may be an air conditioner, a humidifier, etc. in a store.

For example, in a scenario where the fragrance concentration of a store is managed based on the device management system, the terminal may be an electronic device in the store, such as a fragrance machine, etc., having an odor detection sensor built therein; the execution device may be a fragrance machine in a store or the like. If the prototype terminal of the store does not include a fragrance machine, a first sensor may be provided, the first sensor may be an odor detection sensor, and the execution device may be a fragrance machine provided in the store. The fragrance machine is not a prototype of in-store display, but is used only to control the fragrance concentration in the store.

In the embodiment of the application, a first sensor collects first environmental data and sends the first environmental data to a ring control device; and the second sensor collects second environmental data, and the corresponding terminal sends the second environmental data to the environmental control equipment. For example, the first sensor is a temperature sensor, and the temperature sensor collects temperature and sends the temperature to the environmental control device.

Wherein the ring control device can be one or more. For example, the device management system manages an illumination system, a sound system, an air conditioning system, a fragrance system, and a curtain system in a store. If the number of the environmental systems is one, the environmental systems are corresponding to the preset environmental systems, and the environmental systems are corresponding to the preset environmental systems. If the number of the ring control devices is multiple, each ring control device in the multiple ring control devices corresponds to different preset ring control strategies respectively; for example, the environmental control device 1 includes a preset environmental control policy corresponding to the lighting system, the environmental control device 2 includes a preset environmental control policy corresponding to the sound system, the environmental control device 3 includes a preset environmental control policy corresponding to the air conditioning system, the environmental control device 4 includes a preset environmental control policy corresponding to the fragrance system, and the environmental control device 5 includes a preset environmental control policy corresponding to the curtain system. Or, the preset environmental control strategy corresponding to a part of environmental systems in the environmental systems can also be obtained by the plurality of environmental control devices; for example, the environmental control device 1 includes preset environmental control strategies corresponding to the lighting system and the curtain system respectively, and the environmental control device 2 includes preset environmental control strategies corresponding to the sound system, the air conditioning system and the fragrance respectively.

The method comprises the steps that the environmental control equipment receives first environmental data and second environmental data, and determines target environmental data of each execution equipment in one or more execution equipment according to a preset environmental control strategy according to the first environmental data and the second environmental data; wherein the target environmental data includes any one of illumination intensity, temperature, humidity, air quality, sound parameters, and odor concentration.

The environmental control equipment sends corresponding target environmental data to the execution equipment, and the execution equipment receives the target environmental data and adjusts the current environmental data into the target environmental data. For example, the second environmental data received by the environmental control device and sent by the terminal 1 is the illumination intensity. If the corresponding execution device is determined to be the lighting device 1, the environmental control device determines the target illumination intensity of the lighting device 1 according to a preset lighting control strategy (preset environmental control strategy). The ring control device sends the target illumination intensity to the lighting device 1. The lighting device 1 receives the target illumination intensity and adjusts the current illumination intensity to the target illumination intensity.

In the following embodiments, a ring control device is specifically described.

Referring to fig. 2, fig. 2 is a schematic structural diagram of an integration scheme of an equipment management system according to an embodiment of the present application. As shown in fig. 2, the device management system includes a terminal (i.e., the front-end acquisition terminal of fig. 2), a first sensor, an intelligent environmental control system (i.e., the environmental control device described above), and a drive terminal system (which may also be referred to as an execution device system). The terminal is internally provided with a second sensor for collecting environmental data in a store, and mainly comprises data collection of a lighting system, data collection of a sound system, data collection of an air conditioning system, data collection of a fragrance system, data collection of a curtain system and the like. Wherein, the first sensor may include a temperature sensor, a humidity sensor, an illumination sensor, a rain sensor, an air quality sensor, an odor detection sensor, an infrared sensor, and the like.

The data acquisition of the lighting system requires a light sensor, and the light sensor is used for acquiring the illumination intensity of a plurality of lighting devices in the lighting system. The data acquisition of the sound system needs to comprise a microphone sensor and a passenger flow system, wherein the microphone sensor is used for acquiring decibel values in a store, and the passenger flow system is used for acquiring passenger flow in the store. The data acquisition of the air conditioning system needs to include an air quality sensor, a temperature and humidity sensor (a temperature sensor and a humidity sensor) for acquiring the air quality value and the temperature and humidity of each area in the store. The data acquisition of the fragrance system comprises an odor detection sensor and a passenger flow system, wherein the odor detection sensor is used for detecting the fragrance concentration in a store, and the passenger flow system is used for acquiring the passenger flow in the store. The data acquisition of the curtain system comprises an illumination sensor, a rainwater sensor and a temperature sensor, wherein the temperature sensor is used for acquiring the temperature of the glass corresponding to each curtain, the illumination sensor is used for acquiring the illumination intensity of the glass corresponding to each curtain, and the rainwater sensor is used for detecting rainwater. The passenger flow system is a system for counting the number of people, groups and other data in a single area by utilizing machine vision, and is used for counting the passenger flow in a store and calculating the space density. The scent concentration detection module includes a scent concentration detection sensor. The data acquisition of the security system requires the use of an infrared sensor.

The intelligent environmental control system can be a computer, an independent server, a server cluster, a cloud server or the like.

The terminal collects environmental data of the environment where the terminal is located through the collecting device of the terminal. After the environmental data is collected, the terminal uploads the environmental data to the intelligent environmental control system. Taking the mobile phone 1 as an example, the terminal collects the ambient light data of the environment where the mobile phone 1 is located (for example, the display stand where the mobile phone 1 is located) through the self illumination collection device (namely, the light sensor). After the ambient light data is collected, the mobile phone uploads the ambient light data to the intelligent environmental control system. The ambient light data is illumination intensity data of the environment where the mobile phone 1 is located.

The intelligent environmental control system is used for calculating target environmental data of the execution equipment corresponding to the terminal according to the environmental data uploaded by the terminal, and transmitting the target environmental data to the driving terminal system. For example, the intelligent environmental control system determines the target illumination intensity of the target illumination device (for example, the spotlight above the mobile phone 1) corresponding to the mobile phone 1 according to the environmental light data uploaded by the mobile phone 1, and sends the target illumination intensity to the illumination system, and then the illumination system sends the target illumination intensity to the target illumination device.

The intelligent environmental control system comprises a data model module, a scenerization adjustment module, a data processing module, a strategy engine module, a device management module, a third-party system control adjustment service module and an adjustment mode operation and maintenance operation module.

The data model module comprises a lamplight adjusting model, a sound adjusting model, an air conditioner adjusting model, a fragrance adjusting model, a curtain adjusting model and a security adjusting model. Wherein the effects presented are different due to the different types of executing devices and the different locations of the executing devices in the store. Thus, each adjustment model may include multiple models, with different execution devices corresponding to different adjustment models. For example, the light adjustment model includes a light adjustment model 1, a light adjustment model 2, a light device 1 corresponds to the light adjustment model 1, and a light device 2 corresponds to the light adjustment model 2. The light adjustment model is input into the light intensity of the light sensor, current time data and current season data, and output into the target light intensity. The input of the sound adjusting model is the decibel value of the microphone sensor and the passenger flow of the passenger flow system, and the output is the target decibel value. The input of the air conditioner adjusting model is the temperature and humidity of a temperature and humidity sensor and the passenger flow of a passenger flow system, and the output is the target temperature and humidity. The input of the fragrance adjustment model is the fragrance smell concentration of the smell detection sensor and the passenger flow volume of the passenger flow system, and the output is the target smell concentration. The input of the curtain adjusting model is the temperature of the temperature sensor and the illumination intensity of the illumination sensor, and the output is the descending proportion of the curtain.

The scene change adjusting mode module refers to a scene change adjusting mode which can be customized by a user. In the embodiment of the application, the scene modes of the store include a store opening mode, a store closing mode, a scholarly mode and the like. Different scene modes correspond to different data models.

The data processing module can analyze according to the environmental data sent by the terminal. In particular, the data processing module may determine from the environmental data whether an environmental conditioning operation needs to be performed. For example, the data processing module may analyze the ambient light data sent by the handset 1. In particular, the data processing module may determine from the ambient light data whether an ambient light adjustment operation needs to be performed. For example, if the ambient light data is within the preset illumination intensity range, it is determined that the ambient light adjustment operation is not required for the environment where the mobile phone 1 is located; if the ambient light data is outside the preset illumination intensity range, it is determined that the ambient light adjustment operation needs to be performed on the environment where the mobile phone 1 is located.

If the data processing module needs to perform environment adjustment operation on the environment where the terminal is located, the policy engine module of the intelligent environmental control system calculates target environment data which needs to be adjusted by the target execution equipment according to the environment data and the determined target execution equipment. For example, if the data processing module determines that the environment where the mobile phone 1 is located needs to be subjected to an environmental light adjustment operation, the policy engine module of the intelligent environmental control system calculates, according to the environmental light data and the determined target lighting device, a target illumination intensity that needs to be adjusted by the target lighting device.

The device management module may configure a correspondence relationship between each execution device and the terminal in the store, where the correspondence relationship represents a correspondence relationship between position data of the execution device and position data of the terminal. Taking an illumination system as an example, a space corresponding to a store may be divided into a plurality of subspaces, the position data of the illumination device a is (X, Y, Z), the position data of the mobile phone a is (Q, W, E), and according to the coordinate range of the subspaces, the coordinates (X, Y, Z) and the coordinates (Q, W, E) belong to the same subspace, and then the terminal illuminated by the illumination device a is determined to be the mobile phone a. Similarly, the device management module may also configure the correspondence between other lighting devices and the terminal according to the location data of the lighting devices, the location data of the terminal, and the divided subspace ranges. For example, the terminal irradiated by the lighting device B includes a mobile phone B and a mobile phone C; the terminals illuminated by the lighting device C and the lighting device D are mobile phones D.

After the policy engine module calculates the target environment data, the control adjustment service module of the intelligent environmental control system generates a control instruction based on the target environment data, wherein the control instruction carries the target environment data and the target execution equipment identifier. The intelligent environmental control system sends the control instruction to the execution equipment system. The control adjustment service module may be a third party system control adjustment service module. For example, after the rule engine module calculates the target illumination intensity, the third party system controls the adjustment service module to generate a control instruction based on the target illumination intensity, where the control instruction carries the target illumination intensity and the target lighting device identifier. The intelligent environmental control system sends the control instruction to the lighting system.

The adjustment mode operation module can query the equipment condition of the equipment in real time through an operation interface, for example, whether the equipment is offline, whether the equipment is damaged or not, and the like. And timely reporting the equipment condition to inform the staff for processing. And monitoring the scene adjustment mode module, and monitoring whether a user uses the scene adjustment mode module, the use frequency of the scene adjustment mode module and the like.

The driving terminal system mainly comprises a lighting system, a sound system, a curtain system, an air conditioning system and a fragrance system. The execution device system is used for managing a plurality of execution devices, and the execution device system can be an independent server, a server cluster, a cloud server or the like. For example, a lighting system is used to manage a plurality of lighting devices, a sound system is used to manage a plurality of sound devices, a curtain system is used to manage a plurality of curtains in a store, an air conditioning system is used to manage a plurality of air conditioners, and a fragrance system is used to manage a plurality of fragrance machines.

After receiving the control instruction sent by the intelligent environmental control system, the driving terminal system inquires the target execution equipment corresponding to the target execution equipment identifier according to the target execution equipment identifier in the control instruction. For example, after receiving a control instruction sent by the intelligent environmental control system, the lighting system queries, according to a target lighting device identifier in the control instruction, a target lighting device corresponding to the target lighting device identifier. For example, after receiving a control instruction sent by the intelligent environmental control system, the curtain system queries a target curtain corresponding to the target curtain identifier according to the target curtain identifier in the control instruction.

In this embodiment of the application, based on the collection system (second sensor) of sample machine terminal self in the store and the collection system (first sensor) of proprietary that sets up carry out environmental data's collection in real time, can realize the real-time control to store environment, saved the manpower. The intelligent environmental control system is in real-time linkage with the terminal, the special acquisition device and the execution equipment system, and sends an adjusting instruction to the execution equipment system according to the environmental data acquired by the terminal and the special acquisition device and a preset equipment model to instruct the execution equipment system to adjust corresponding environmental data of corresponding execution equipment, so that the environmental data of each execution equipment of a store is always in an optimal environmental experience interval, and the experience environment of a user in the store is optimized. The scheme combines the integrated linkage analysis control of peripheral systems such as passenger flow and the like, so that the environment is adjusted more accurately.

It should be appreciated that the setting of the first sensor may be adjusted according to the model machine type of store. For example, in a scenario where the device management system manages the fragrance concentration of a store, if the in-store prototype includes a prototype fragrance machine, the fragrance concentration may be collected by an odor concentration sensor in the prototype fragrance machine, and the corresponding execution device may be the prototype fragrance machine. If the in-store prototype does not comprise the prototype fragrance machine, the fragrance concentration can be acquired through a special odor detection sensor, and the corresponding execution equipment can be the fragrance machine arranged in the store. In a scene of managing the temperature and the humidity of a store based on the equipment management system, the acquisition of the temperature data and the humidity data are the same, if the store model comprises an air conditioner model and a humidifier model, the temperature and humidity data can be acquired through a temperature and humidity sensor in the air conditioner model, the humidity data can be acquired through a humidity sensor of the humidifier model, and corresponding execution equipment is the air conditioner model and the humidifier model. If the store prototype does not comprise the air conditioner prototype and the humidifier prototype, the temperature and humidity data can be acquired through a special temperature and humidity sensor, and the corresponding execution equipment can be an air conditioner and a humidifier arranged in the store.

In the above device management system, it may be understood that the terminal where the second sensor is located and the executing device may be different devices. The intelligent environmental control system is communicated with the terminal where the first sensor and the second sensor are located and the execution equipment system corresponding to the execution equipment, so that equipment management of the execution equipment is realized. The environmental data collected by each terminal in the store comprises illumination intensity, environmental temperature data, environmental humidity data, environmental decibels, fragrance concentration, passenger flow and the like.

Referring to fig. 3, a block diagram of a hardware structure of an electronic device (e.g., electronic device 100) according to an embodiment of the present application is shown. The device structure of the intelligent environmental control system, the device structure of the terminal and the device structure of the execution device system can refer to the electronic device structure diagram shown in fig. 3. The electronic device 100 may include, among other things, a processor 310, an external memory interface 320, an internal memory 321, a universal serial bus (un iversa l ser ia l bus, USB) interface 330, a charge management module 340, a power management module 341, a battery 342, an antenna 1, an antenna 2, a radio frequency module 350, a communication module 360, an audio module 370, a speaker 370A, an experience listener 370B, a microphone 370C, an ear-piece interface 370D, a sensor module 380, keys 390, a motor 391, an indicator 392, a camera 393, a display screen 394, and a user identification module (subscr iber ident ificat ion modu le, SIM) card interface 395. Wherein the sensor module 380 may include a proximity light sensor 380A, an ambient light sensor 380B, and the like.

The illustrated structure of the embodiment of the present invention does not constitute a limitation of the electronic apparatus 100. More or fewer components than shown may be included, or certain components may be combined, or certain components may be split, or different arrangements of components. The illustrated components may be implemented in hardware, software, or a combination of software and hardware.

Processor 310 may include one or more processing units. For example, the processor 310 may include an application processor (app l icat ion processor, AP), a modem processor, a graphics processor (graph ics process ing un it, GPU), an image signal processor (image s igna l processor, ISP), a controller, a memory, a video codec, a digital signal processor (d igita l s igna l processor, DSP), a baseband processor, and/or a neural network processor (neuro l-network process ing un it, NPU), etc. Wherein the different processing units may be separate devices or may be integrated in one or more processors.

The controller may be a decision maker that directs the various components of the electronic device 100 to coordinate their operations in accordance with instructions. Is the neural and command center of the electronic device 100. The controller generates an operation control signal according to the instruction operation code and the time sequence signal to finish the control of instruction fetching and instruction execution.

A memory may also be provided in the processor 310 for storing instructions and data. In some embodiments, memory in the processor 310 is a cache memory that holds instructions or data that the processor 310 has just used or recycled. If the processor 310 needs to reuse the instruction or data, it may be called directly from the memory. Repeated accesses are avoided and the latency of the processor 310 is reduced, thereby improving the efficiency of the system.

In some embodiments, the processor 310 may include an interface. The interfaces may include an integrated circuit (inter-integrated ci rcu it, I2C) interface, an integrated circuit built-in audio (inter-integrated ci rcu it sound, I2S) interface, a pulse code modulation (pu l se code modu l at ion, PCM) interface, a universal asynchronous receiver transmitter (un iversa lasynchronous receiver/transmitter, UART) interface, a mobile industry processor interface (mobi le industry processor interface, MI PI), a general purpose input/output (GPIO) interface, a SIM interface, and/or a USB interface, among others.

The interface connection relationship between the modules illustrated in the embodiment of the present invention is only schematically illustrated, and does not limit the structure of the electronic device 100. The electronic device 100 may employ different interfacing means, or a combination of interfacing means, in embodiments of the present invention.

The charge management module 340 is configured to receive a charge input from a charger. The charger can be a wireless charger or a wired charger. In some wired charging embodiments, the charge management module 340 may receive a charging input of a wired charger through the USB interface 330. In some wireless charging embodiments, the charge management module 340 may receive wireless charging input through a wireless charging coil of the electronic device 100. The battery 342 is charged by the charge management module 340, and the electronic device 100 can be powered by the power management module 341.

The power management module 341 is configured to connect the battery 342, the charge management module 340 and the processor 310. The power management module 341 receives input from the battery 342 and/or the charge management module 340 to power the processor 310, the internal memory 321, the external memory interface 320, the display screen 394, the camera 393, the communication module 360, and the like. The power management module 341 may also be configured to monitor battery capacity, battery cycle number, battery health (leakage, impedance), and other parameters. In some embodiments, the power management module 341 may also be disposed in the processor 310. In some embodiments, the power management module 341 and the charge management module 340 may also be provided in the same device.

The wireless communication function of the electronic device 100 may be implemented by the antenna 1, the antenna 2, the radio frequency module 350, the communication module 360, the modem, the baseband processor, and the like.

The electronic device 100 implements display functions through a GPU, a display screen 394, an application processor, and the like. The GPU is a microprocessor for image processing, connected to the display screen 394 and the application processor. The GPU is used to perform mathematical and geometric calculations for graphics rendering. Processor 310 may include one or more GPUs that execute program instructions to generate or change display information.

The electronic device 100 may implement audio functionality through an audio module 370, a speaker 370A, a receiver 370B, a microphone 370C, an ear-headphone interface 370D, and an application processor, among others. Such as music playing, recording, etc.

The audio module 370 is used to convert digital audio information into an analog audio signal output and also to convert an analog audio input into a digital audio signal. The audio module 370 may also be used to encode and decode audio signals. In some embodiments, the audio module 370 may be disposed in the processor 310, or some of the functional modules of the audio module 370 may be disposed in the processor 310.

Speaker 370A, also known as a "horn," is used to convert audio electrical signals into sound signals. The electronic device 100 may listen to music, or to hands-free conversations, through the speaker 370A.

A receiver 370B, also referred to as a "earpiece", is used to convert the audio electrical signal into a sound signal. When electronic device 100 is answering a telephone call or voice message, voice may be received by placing receiver 370B close to the human ear.

Microphone 370C, also referred to as a "microphone," is used to convert sound signals into electrical audio signals. When making a call or transmitting voice information, the user can sound near the microphone 370C through the mouth, inputting a sound signal to the microphone 370C. The electronic device 100 may be provided with at least one microphone 370C. In some embodiments, the electronic device 100 may be provided with two microphones 370C, and may implement a noise reduction function in addition to collecting sound signals. In some embodiments, the electronic device 100 may also be provided with three, four, or more microphones 370C to enable collection of sound signals, noise reduction, identification of sound sources, directional recording functions, etc.

The earphone interface 370D is for connecting a wired earphone. The earphone interface 370D may be a USB interface 330 or a 3.5mm open mobile terminal platform (open mobi le termina l p l atform, OMTP) standard interface, a american cellular telecommunications industry association (ce l l u l ar te lecommun icat ions industry associat ion of the USA, CTIA) standard interface.

The proximity light sensor 380A may include, for example, a Light Emitting Diode (LED) and a light detector, such as a photodiode. The light emitting diode may be an infrared light emitting diode. Infrared light is emitted outwards by the light emitting diode. A photodiode is used to detect infrared reflected light from nearby objects. When sufficient reflected light is detected, it may be determined that there is an object in the vicinity of the electronic device 100. When insufficient reflected light is detected, it may be determined that there is no object in the vicinity of the electronic device 100. The electronic device 100 can detect that the user holds the electronic device 100 close to the ear by using the proximity light sensor 380A, so as to automatically extinguish the screen to achieve the purpose of saving power. The proximity light sensor 380A may also be used in holster mode, pocket mode to automatically unlock and lock the screen.

The ambient light sensor 380B is used to sense ambient light level. The electronic device 100 may adaptively adjust the display screen brightness based on the perceived ambient light level. The ambient light sensor 380B may also be used to automatically adjust white balance during photographing. Ambient light sensor 380B may also cooperate with proximity light sensor 380A to detect if electronic device 100 is in a pocket to prevent false touches.

In this embodiment, the ambient light sensor 380B of the terminal is configured to collect ambient light data of an environment in which the terminal is located, and the terminal uploads the collected ambient light data to the intelligent environmental control system.

The temperature sensor 380C is used to detect temperature. In some embodiments, the electronic device 100 performs a temperature processing strategy using the temperature detected by the temperature sensor 380C. For example, when the temperature reported by temperature sensor 380C exceeds a threshold, electronic device 100 performs a reduction in performance of a processor located in the vicinity of temperature sensor 380C in order to reduce power consumption to implement thermal protection.

In this embodiment, the temperature sensor 380C of the terminal is configured to collect environmental temperature data of an environment in which the terminal is located, and the terminal uploads the collected environmental light data to the intelligent environmental control system.

Referring to fig. 4, fig. 4 is a flowchart of a device management method according to an embodiment of the present application. As shown in fig. 4, the flow among each terminal, the intelligent environmental control system and the execution device system in the store is as follows:

s401, configuring information of the connection intelligent environmental control system by the terminal.

The information comprises the connection address of the intelligent environmental control system, the position data of the terminal and the like. This information is taken as first configuration information. The user can perform a configuration operation based on the setting interface of the terminal. The setting interface comprises configuration options for carrying out connection addresses of the intelligent environmental control system and configuration options for carrying out position data of the terminal. Illustratively, the connection address of the intelligent ring control system may be a network address. The location data of the terminal may be latitude and longitude data determined by the terminal through a global positioning system (globa l pos it ion ing system, GPS). Alternatively, the location data of the terminal may also be an arrangement location of the terminal in the store, for example, the location data is used to indicate the a-th row and B-th row of the first terminal on the display stand Y in the region X of the store.

In the embodiment of the application, the connection address of the intelligent environmental control system is configured in each terminal in the store.

S402, the intelligent environmental control system adds a sensor and binds equipment.

The intelligent environmental control system acquires information such as a connection address of the execution equipment system, position data of a special acquisition device (a first sensor) and the like. The information is taken as second configuration information. The execution equipment system comprises an air conditioning system, a lighting system, a fragrance system, a sound system and the like.

The intelligent environmental control system adds a collecting device (a second sensor) in each terminal and binds each execution device based on the connection address of the execution device system. Specifically, the intelligent environmental control system configures the corresponding relation between each terminal and the execution device.

Optionally, the intelligent environmental control system establishes the corresponding relation between the terminal and the execution device according to the position data of the terminal and the position data of the corresponding execution device and by taking the distance between the terminal and the execution device as a reference that is smaller than or equal to a preset distance threshold value.

And each first sensor is added in the intelligent environmental control system and is bound with each execution device based on the connection address of the execution device system. Specifically, the intelligent environmental control system configures the corresponding relation between each first sensor and the execution device. For example, the illumination sensor a is disposed at the a-side glass, and the execution device corresponding to the illumination sensor a is a curtain a on the a-side glass. For another example, the temperature and humidity sensor a is disposed in the area a, and the executing device corresponding to the temperature and humidity sensor a may be an air outlet corresponding to the area a.

S403, the terminal performs parameter setting configuration.

The terminal binds with the store information and binds with the position information. For example, if the terminal 1 is disposed in the store 1, the terminal 1 is bound to the store 1. For example, if the terminal 1 is placed on the sample table 1, the terminal 1 is bound to the sample table 1.

The terminal configures a corresponding relation with the acquisition area. For example, if the terminal 1 is in the area a, the terminal 1 collects the environmental data of the area a. One terminal can collect environmental data of a plurality of areas. Environmental data for an area may also be collected by multiple terminals.

S404, connecting the terminal with the environmental control system.

The terminal is connected with the network, and the acquisition terminal is started. And then, the terminal sends a connection establishment request to the intelligent ring control system according to the connection address of the intelligent ring control system.

In this embodiment, optionally, the connection establishment request carries an identifier of the terminal.

S405, the intelligent environmental control system judges whether the terminal is added.

And the intelligent ring control system inquires whether a terminal corresponding to the terminal identifier exists in the second configuration information according to the terminal identifier carried in the connection establishment request.

If the intelligent environmental control system inquires that the identifier corresponding to the terminal exists from the second configuration information, the terminal is judged to be added. If the intelligent environmental control system does not inquire that the identifier corresponding to the terminal exists in the second configuration information, judging that the terminal is not added.

S406, the intelligent environmental control system judges that the terminal is added, and establishes connection with the terminal.

S407, the terminal collects environment data and uploads the environment data to the intelligent environmental control system.

For example, taking sound control as an example, a decibel collector of each area in a store collects the environmental decibel of the corresponding area, and then the environmental decibel is uploaded to an intelligent environmental control system. And the passenger flow system of the store counts the passenger flow volume of the store at the moment, calculates the space density according to the passenger flow volume, and then uploads the space density to the intelligent environmental control system.

The environment data comprises second environment data acquired by a second sensor built in the terminal and first environment data acquired by the first sensor.

S408, the intelligent environmental control system judges whether to trigger a preset environmental control strategy.

And the intelligent environmental control system determines a corresponding preset environmental control strategy according to the received environmental data. And acquiring a set data range in a preset environmental control strategy, and comparing the received environmental data with the set data range. Specifically, according to the received first environmental data and second environmental data, determining actual environmental data of each of a plurality of areas where the plurality of first sensors and one or more second sensors are located, and comparing the actual environmental data with a set data range.

And indicating a plurality of environment data ranges and target environment data corresponding to each environment data range in a preset environmental control strategy. If the target environmental data corresponding to a certain environmental data range is actual environmental data, that is, environmental adjustment is not needed in the environmental data range, the environmental data range is the set data range. The setting data range can be set according to the real-time environment condition of each area. The set data range may be not a range but a numerical value (trigger value).

The intelligent environmental control system judges whether the actual environmental data is in a set data range. And if the actual environment data is not in the set data range, triggering a preset environmental control strategy. If the actual environment data is within the set data range, the preset environmental control strategy is not triggered. For example, the illumination intensity of the desktop 1 is adjusted to be 8:00-8:30 on a sunny day, and the illumination intensity range (set data range) is set to be 800-900l ux. If the actual illumination intensity of the desktop 1 is 800l ux, the illumination intensity of the desktop 1 does not need to be adjusted; if the actual illumination intensity of the desktop 1 is smaller than 800l ux or larger than 900l ux, the illumination intensity of the desktop 1 needs to be adjusted, that is, a preset environmental control strategy is triggered.

S409, if the intelligent environmental control system judges that the preset environmental control strategy is triggered, the intelligent environmental control system matches the preset environmental control strategy corresponding to each terminal.

And the intelligent environmental control system calculates target environmental data which needs to be regulated by the target execution equipment according to the received environmental data and the determined target execution equipment. For example, the intelligent environmental control system obtains the actual illumination intensity of the area A according to the received illumination intensity of the area A. And determining the target illumination intensity corresponding to the illumination intensity range where the actual illumination intensity is located.

S410, the intelligent environmental control system calls an execution device system verification interface.

Optionally, after the intelligent environmental control system obtains the target environmental data, the intelligent environmental control system may further send a connection request to a system corresponding to the target execution device.

In this embodiment, after the intelligent environmental control system obtains the target environmental data of the target execution device, the address information of the execution device system corresponding to the target execution device is queried according to the second configuration information. The intelligent ring control system calls an execution device system verification interface, and sends a connection request to the execution device system based on the address information of the execution device system, wherein the connection request can carry the address information of the intelligent ring control system.

S411, the execution device system returns an interface check value.

In this embodiment, the executing device system verifies the validity of the intelligent environmental control system when receiving the connection request. For example, the address information of the intelligent ring control system is obtained, and if the address information of the intelligent ring control system is the stored address in the execution equipment system, the intelligent ring control system is determined to be legal. And the execution equipment system responds to the connection request and returns an interface check value to the intelligent environmental control system. And determining whether the intelligent environmental control system is legal or not according to the interface check value.

Or, the execution device system returns a connection response carrying a key to the intelligent ring control system in response to the connection request, and the intelligent ring control system can establish a communication connection with the execution device system based on the key. If the address information of the intelligent ring control system is not the stored address in the execution equipment system, the execution equipment system does not respond to the connection request.

The validity of the intelligent environmental control system can be verified by the execution device system, so that the information security and the effectiveness of device management in the device management process can be ensured.

S412, the intelligent environmental control system calls an executing device system adjusting interface.

And if the intelligent ring control system determines that the intelligent ring control system is legal according to the received interface check value, calling the execution equipment system to adjust the interface. The intelligent environmental control system sends a control instruction of environment adjustment to the execution equipment system through the execution equipment system adjustment interface. Wherein the control instruction for the environmental adjustment is generated based on the identification of the target execution device and the target environmental data.

S413, the executive device system judges whether the target executive device is online.

After receiving the control instruction of environment adjustment, the execution device system judges whether the target execution device is online or not. And if the target execution equipment is online, adjusting the target execution equipment according to the target environment data. If the target execution device is not online, the control instruction of the environment adjustment is not executed. Here, the target execution device being online means that the target execution device is in a power-on state. The target execution device being offline means that the target execution device is in a power-off state.

Optionally, the execution device system may further query whether the target execution device exists according to the identifier of the target execution device carried in the control instruction. If the execution device managed by the execution device system does not have the device corresponding to the identification of the target execution device, the control instruction is not executed. And if the device corresponding to the identification of the target execution device exists in the execution devices managed by the execution device system, adjusting the target execution device according to the target environment data.

S414, the execution device system adjusts device parameters.

The execution device system adjusts the target execution device according to the target environment data. Taking the example that the illumination system adjusts the target illumination device according to the target illumination intensity, the target illumination intensity is 1200, the current illumination intensity of the target illumination device is 1100, and the illumination intensity of the target illumination device is adjusted to 1200.

The illumination intensity of the target execution device can be adjusted step by step. For example, the target illumination intensity is 1200, the illumination intensity of the current target lighting device is 1000, and the lighting system can gradually adjust the illumination intensity of the target lighting device to 1200 according to the adjustment step of 100, so that the adjustment effect is achieved in a softer adjustment manner, and the illumination abrupt change feeling is not generated for users in the environment.

In the embodiment of the application, after the execution device system adjusts the target execution device according to the target environment data, a response of the adjustment completion is returned to the intelligent environmental control system.

S415, the intelligent environmental control system determines that the device parameter adjustment is successful.

In the embodiment of the application, the intelligent environmental control system determines that the target execution device is successfully adjusted after receiving the response of the completion of adjustment returned by the execution device system.

Referring to fig. 5, fig. 5 is a schematic flow chart of an apparatus parameter adjustment according to an embodiment of the present application. As shown in fig. 5, the terminal in the store is connected to the network, and the acquisition program is started. The acquisition device in the terminal and the special acquisition device in the store are both sensors. Each sensor starts to collect the environmental data of the corresponding area and uploads the environmental data to the host. The host analyzes the environmental data collected by the sensor and matches the sensor with the execution equipment. And acquiring the trigger value of the execution device matched with each sensor, and determining whether to trigger the parameter adjustment of the execution device, namely determining whether to perform the parameter adjustment on the execution device matched with the sensor. Wherein the trigger value may be a set data range for one of the environmental data. If the parameters of the execution equipment corresponding to the sensor do not need to be adjusted, namely the environmental data collected by the sensor are within the set data range, the process is ended. If the parameters of the execution equipment corresponding to the sensor need to be adjusted, namely the environmental data collected by the sensor is not in the set data range, the host matches the adjustment strategy corresponding to the execution equipment according to the collected environmental data. That is, the parameter value to which the corresponding execution device needs to be adjusted is determined according to the collected environmental data. For example, if the environmental data is the illumination intensity of the D area, the illumination intensity of the lighting device of the D area needs to be adjusted if the illumination intensity of the D area is not within the preset illumination intensity range of the D area.

Wherein the environmental data of an area may be determined jointly from the data acquired by the plurality of sensors. For example, the light sensors in the terminal 1 and the terminal 2 can collect the illumination intensity of the sample table B, and the terminal 1 and the terminal 2 upload the illumination intensities of the sample table B collected by the respective light sensors to the intelligent environmental control system. The intelligent environmental control system can take the average value of the two illumination intensities as the actual illumination intensity of the sample table B, or take the larger illumination intensity of the two illumination intensities as the actual illumination intensity of the sample table B.

Specifically, a policy value and a ladder value are obtained, wherein the policy value is a numerical value of target environmental data to be adjusted by the execution device, and the ladder value is an adjustment step of the execution device. The host computer judges whether the difference value between the strategy value and the acquisition value is larger than a step value. If the difference value between the strategy value and the acquisition value is smaller than the step value, the strategy value is taken as setting data, and the setting data is issued to the corresponding execution equipment. If the difference value between the strategy value and the acquisition value is larger than the step value, under the condition that the strategy value is larger than the acquisition value, the step value is subtracted by the acquisition value to serve as setting data, and the setting data is issued to corresponding execution equipment. If the difference value between the strategy value and the acquisition value is larger than the step value, the acquisition value plus the step value is taken as setting data, and the setting data is issued to the corresponding execution equipment under the condition that the strategy value is smaller than the acquisition value. The execution device adjusts the environment data of the corresponding terminal according to the preset adjustment steps, and achieves the adjustment effect in a softer adjustment mode without generating environment mutation feeling for users in the environment.

The execution equipment system receives the adjustment instruction information issued by the host, wherein the adjustment instruction information comprises setting data corresponding to each execution equipment. The execution device system judges that the corresponding execution device is in an offline state. And if the execution equipment is online, adjusting parameters of the execution equipment to be the setting data. If the execution device is offline, the flow ends. After the parameter setting of the execution device is successful, the current setting data (device parameter value) of the execution device is returned to the host. And the host judges whether the setting data is equal to the strategy value, if so, the adjusting flow is ended. If the set data is not equal to the policy value, the host determines whether the difference between the policy value and the set data (return value) is greater than the step value, and the subsequent step is the same as the subsequent step of "whether the difference between the policy value and the collection value is greater than the step value" described above. And until the host receives the setting data returned by the execution equipment system and is the same as the strategy value, ending the adjusting flow.

For example, in the adjustment of the air conditioning system, if the temperature difference between the current temperature (28 degrees) of the target air conditioner and the policy value (22 degrees) is too large (the temperature difference is 6 degrees), the temperature adjustment may be performed step by step according to a preset adjustment step (for example, 3 degrees). That is, the temperature of the target air conditioner is adjusted to 25 degrees for the first time, and 22 degrees for the second time, thereby completing the temperature adjustment of the target air conditioner.

In the embodiment of the application, environmental data can be collected through a store prototype instead of traditional instrument collection. Such as by a prototype built-in sensor instead of the traditional light sensor and microphone sensor. And the intelligent environmental control system is linked, and the illumination brightness, the air-conditioning temperature, the music sound size and the like in the store are intelligently adjusted according to the collected environmental data and the set environmental adjustment strategy, so that customers in the store are always in the optimal environmental experience interval.

In the embodiment of the application, the adjustment flow of each system in the store is described in detail. Fig. 6 to 10 are as follows.

Referring to fig. 6, fig. 6 is a schematic flow chart of an illumination system adjustment according to an embodiment of the present application. As shown in fig. 6, when the store is in store-on mode, the store activates the intelligent environmental control system. At this time, the illumination collection system collects the illumination intensity in the store. The illumination collection system may include a plurality of illumination sensors (i.e., light sensors), each of which may correspondingly collect illumination intensity of one or more regions. For example, the sample machine terminal A of the desktop A in a store is provided with the illumination sensor A, so that the illumination intensity of the desktop A can be correspondingly acquired. In a prototype terminal B of a desktop B in a store, an illumination sensor B is arranged and can correspondingly collect illumination intensity of the desktop B. And in the preset acquisition time, the illumination sensor A and the illumination sensor B acquire illumination intensities of the desktop A and the desktop B respectively and then upload the illumination intensities to the host. The preset collection time may be set in a user-defined manner, for example, the preset collection time is 5 minutes.

The host computer matches the illumination regulation strategies corresponding to the desktop A and the desktop B. For example, the illumination intensity range value is set to 2000lx-2300lx, and whether to trigger the illumination adjustment strategy is determined according to the received illumination intensities of the desktop A and the desktop B. Specifically, if the illumination intensities of the desktop a and the desktop B are within the set illumination range value, the intelligent environmental control system will not trigger the corresponding illumination adjustment strategy. If the illumination intensities of the desktop A and the desktop B are not within the set illumination range value, the intelligent environmental control system does not trigger the corresponding illumination adjustment strategy. The set illumination intensity range value is determined according to the current weather, time and other factors.

Based on the illumination adjustment strategies corresponding to the desktop A and the desktop B, it can be known that if the actual illumination intensity of the desktop A is greater than 2300lx or less than 2000lx, the device parameters of the illumination device of the desktop A are adjusted. And determining target illumination intensities of the illumination devices corresponding to the desktop A and the desktop B, and setting the illumination intensities of the illumination devices corresponding to the desktop A and the desktop B as the target illumination intensities. Specifically, if the lighting device corresponding to the desktop a is the spotlight a, and if the actual illumination intensity of the desktop a is greater than 2300lx, the light of the spotlight a needs to be dimmed, and the illumination intensity of the spotlight a is adjusted to a target value of 2000lx. If the actual illumination intensity of the desktop A is smaller than 2000lx, the lamp light of the spotlight A needs to be turned on, and the illumination intensity of the spotlight A is adjusted to a target value of 2000lx. Desktop B is the same.

According to the illumination data and the illumination adjustment strategy, the illumination brightness in the store is intelligently adjusted, so that customers in the store are always in the optimal illumination environment.

Referring to fig. 7, fig. 7 is a schematic flow chart of curtain system adjustment according to an embodiment of the present application. As shown in fig. 7, when in the store-on mode, the store activates the intelligent climate control system. At this time, the illumination collection system and the temperature collection system in the store collect the actual illumination intensity and the actual temperature at the glass position corresponding to the window curtain respectively. The illumination collection system may include a plurality of illumination sensors (i.e., illumination sensors), each of which may correspondingly collect illumination intensity of one or more regions. The temperature acquisition system may include a plurality of temperature sensors (i.e., temperature sensors), each of which may correspondingly acquire the temperature of one or more areas. For example, the illumination collection system may include an illumination sensor a that collects the actual illumination intensity of the a-side glass and an illumination sensor B that collects the actual illumination intensity of the B-side glass. The temperature acquisition system can comprise a temperature sensor A and a temperature sensor B, wherein the temperature sensor A acquires the actual temperature of the glass on the surface A, and the temperature sensor B acquires the actual temperature of the glass on the surface B. Wherein, illumination inductor A and temperature-sensing ware A set up in A face glass, illumination inductor B and temperature-sensing ware B set up in B face glass.

Then, the host determines an adjustment strategy corresponding to the curtain system, and determines the target illumination intensity and the target temperature according to the adjustment strategy. And then, according to the received illumination intensity and temperature, respectively comparing the received illumination intensity and the received temperature with the corresponding target illumination intensity and target temperature, and judging whether to trigger a curtain adjustment strategy. For example, if the target temperature corresponding to the temperature is 35 degrees and the actual temperature corresponding to the surface glass a is greater than 35 degrees, the window curtain corresponding to the surface glass a is lowered by 100%, that is, the window curtain is completely closed. And if the actual temperature corresponding to the A-side glass is less than 35 degrees, automatically adjusting the window curtain based on a preset system algorithm.

The elements to be considered in the system algorithm comprise the geographic position of a store, the season, the current weather condition, the sunlight direction and the like. It should be appreciated that the angle at which solar light strikes a store varies with geographic location and season, and the intensity of the light varies with geographic location, season, weather; and the sunlight directions from the morning to the evening are different, and the angle and the illumination intensity of the sunlight store are different. In the embodiment of the application, the default illumination intensity and the illumination angle of the similar geographic position and the same season are the same; default illumination intensity and illumination angle are the same in every half hour from morning to evening; the target illumination intensity and the descending/ascending proportion of curtain adjustment are the same in the same weather within half an hour. Thus, in the adjustment strategy corresponding to the curtain system, the corresponding relation between the geographic position of the store, the season, the weather, the angle of the solar irradiation store and the target illumination intensity, and the corresponding relation between the target illumination intensity and the descending/ascending proportion of the curtain are preset.

The illumination sensor in the glass collects the illumination intensity of natural light at the glass, and the host determines the corresponding descending/ascending target proportion of the curtain according to the corresponding adjustment strategy of the curtain system. Then, the ratio of the curtain descent/ascent is adjusted to the target ratio. For example, store 1 at geographic location 1, in the morning of sunny days in summer, the target illumination intensity for glass at a is illumination intensity 1; in store 1 at geographic location 1, the target illumination intensity corresponding to glass at a is illumination intensity 2 in the afternoon of sunny days in summer. It will be appreciated that the angle of the solar light irradiation store is different in the morning and afternoon, so that the corresponding target light intensity for the glass at a is also different in the same geographic location, the same season and the same weather. According to the curtain adjusting strategy corresponding to the glass at the position A, the curtain descending proportion corresponding to the illumination intensity 1 is the proportion 1, and the curtain descending proportion corresponding to the illumination intensity 2 is the proportion 2. Therefore, the window curtain of the glass at A is adjusted to be reduced in proportion to 1 in the afternoon, and the window curtain of the glass at A is adjusted to be reduced in proportion to 2 in the afternoon.

Wherein the descending/ascending proportion of the B-side glass and the C-side glass is controlled in the same way.

According to the temperature data and the illumination data which are collected and the curtain adjusting strategy which is set, the curtain descending degree in the store is intelligently adjusted, so that customers in the store are always in the optimal illumination environment. In the adjustment strategy of the curtain system, besides the most main temperature sensor and the illumination sensor, a rainwater sensor can be arranged to detect rainwater, and the adjustment strategy of the curtain can be influenced. Or, the wind-solar-rain sensor can be directly arranged for detecting the wind speed, the intensity of outdoor light and the rain.

In the embodiment of the application, the systems are interrelated. Such as lighting systems and window covering systems. Taking control of the window curtain 1 of the glass 1 as an example, the light sensor 1 arranged at the glass 1 is used for collecting the illumination intensity of the position of the glass 1. The light sensor 1 uploads the collected illumination intensity 1 of the position of the glass 1 to corresponding environmental control equipment. The environmental control equipment determines the target illumination intensity (set as illumination intensity 2) corresponding to the illumination intensity 1 according to the curtain adjustment strategy, and then determines the corresponding dropping proportion 1 of the curtain according to the target illumination intensity. The environmental control equipment sends the descending proportion 1 to the curtain system, the curtain system sends the descending proportion 1 to the curtain 1, and the curtain 1 adjusts the descending proportion of the curtain to be the descending proportion 1. Then, the illumination intensity of the table top 1 is adjusted.

After the descending proportion of the curtain 1 is adjusted, the illumination intensity of the position of the glass 1 is 2. The environmental control equipment acquires the target illumination intensity (set as illumination intensity 3) of the desktop 1 at this time. The terminal 1 placed on the desktop 1 collects the actual illumination intensity of the desktop 1 at the moment, wherein the actual illumination intensity of the desktop 1 at the moment is determined according to the illumination intensity of the illumination device 1 corresponding to the desktop 1 at the moment and the illumination intensity of the glass 1 position. If the actual illumination intensity of the desktop 1 at this time is not the illumination intensity 3, the environmental control device sends the illumination intensity 3 to the lighting system, the lighting system sends the illumination intensity 3 to the lighting device 1 corresponding to the desktop 1, and the lighting device 1 adjusts the current illumination intensity to the illumination intensity 3, so that the actual illumination intensity of the desktop 1 reaches the illumination intensity 3.

For example, in a preset environmental control strategy of the lighting system, the target illumination intensity corresponding to the desktop 1 is 800l ux in a sunny day of 8:00-8:30; the target illumination intensity corresponding to the desktop 1 is 1000l ux in sunny days ranging from 8:30 to 9:00.

When the ratio of the light to the window curtain 1 is 8:00, the light sensor at the glass 1 collects that the illumination intensity of natural light at the position of the glass 1 is 900l ux, and the descending proportion of the window curtain 1 at the glass 1 is adjusted by the environmental control equipment. After the lowering ratio of the window curtain 1 is adjusted, the illumination intensity of the natural light at the position of the glass 1 is 600l ux. The terminal 1 placed on the desktop 1 collects the actual illumination intensity of the desktop 1 at the moment, if the illumination intensity is not 800l ux, the spotlight 1 corresponding to the desktop 1 adjusts the brightness of the lamp light, so that the actual illumination intensity of the desktop reaches 800l ux.

When the ratio of the natural light to the window curtain 1 at the glass 1 is 8:30, the light sensor at the glass 1 collects that the illumination intensity of the natural light at the position of the glass 1 is 1200l ux, and the descending proportion of the window curtain 1 at the glass 1 is adjusted by the environmental control equipment. After the lowering ratio of the window curtain 1 is adjusted, the illumination intensity of the natural light at the position of the glass 1 is 800l ux. The terminal 1 placed on the desktop 1 collects the actual illumination intensity of the desktop 1 at the moment, if the actual illumination intensity is not 1000l ux, the spotlight 1 corresponding to the desktop 1 adjusts the brightness of the lamp light, so that the actual illumination intensity of the desktop reaches 1000l ux.

In this embodiment of the present application, the adjustment of the window shade system and the lighting system are linked, and the adjustment of the lowering degree of each window shade in the window shade system may affect the adjustment of the illumination intensity of each lighting device of the lighting system.

Referring to fig. 8, fig. 8 is a schematic flow chart of sound system adjustment according to an embodiment of the present application. As shown in fig. 8, when in the store-on mode, the store activates the intelligent climate control system. At this time, the store starts playing the background music. The decibel collection system collects decibel values of a store. The decibel acquisition system may include a plurality of decibel collectors, each of which may correspond to acquiring decibel values for one or more regions. For example, the decibel collection system in the store comprises a decibel collector A and a decibel collector B, wherein the decibel collector A and the decibel collector B respectively collect decibel values of corresponding areas and then upload the decibel values to the programmable gateway. The programmable gateway is uploaded to the local area network. For example, the decibel collector may be a microphone sensor in the terminal.

Meanwhile, the passenger flow system also collects the passenger flow in the store and calculates the space density of the store. Wherein the measure of density is related to the sound decibel value generated during the consumer experience and the sound decibel value of the background music. If the persistence of the sound decibel value generated in the experience process of the consumer is larger than that of the music sound decibel value, the density is considered to be large; if the persistence of sound decibel value generated in the experience process of the consumer is smaller than that of music sound decibel value, the density is considered to be small. Or a density threshold value is preset, and if the space density of the current store is greater than the preset density threshold value, the space density is considered to be high; and if the space density of the current store is smaller than the preset density threshold value, the space density is considered to be small. Wherein the preset density threshold may be 4 flat/person.

And the intelligent environmental control system determines a corresponding sound adjusting strategy according to the space density. Different spatial densities correspond to different sound conditioning strategies, i.e. different spatial densities correspond to different decibel target values. For example, when the spatial density is high, the decibel target value may be 60dB, and when the spatial density is low, the decibel target value may be 45dB. If the space density is high, the decibel value in the current store is not 60dB, and the intelligent environmental control system sends a control instruction to the background music host in the store. And after receiving the control instruction, the background music host in the store adjusts the sound source power amplification to 60dB. The decibel value in the current store is calculated according to the decibel values acquired by the decibel collector A and the decibel collector B. For example, the decibel value in the current store may be an average of the decibel values respectively acquired by decibel collector a and decibel collector B.

According to the method and the system, music decibel values in a store are intelligently adjusted according to collected decibel data and a set sound adjusting strategy, so that customers in the store cannot feel too loud or too loud.

Referring to fig. 9, fig. 9 is a schematic flow chart of an air conditioning system adjustment according to an embodiment of the present application. As shown in fig. 9, when in the store-on mode, the store activates the intelligent climate control system. At this time, the passenger flow system in the store starts to count the passenger flow, and the temperature and humidity acquisition system starts to acquire the temperature and humidity. The temperature and humidity acquisition system comprises a plurality of temperature and humidity sensors, and each temperature and humidity sensor can correspondingly acquire the temperature and humidity of one or more areas. For example, a temperature and humidity sensor A is arranged in a prototype terminal C of an area A of a store, so that the temperature and humidity of the area A can be collected in real time. A temperature and humidity sensor B is arranged in a sample machine terminal D of a region B of a store, and the temperature and humidity of the region B can be collected in real time. Then the data is uploaded to the host, and the host is uploaded to the local area network. The preset collection time may be set in a user-defined manner, for example, the preset collection time is 5 minutes. And continuously collecting the passenger flow volume by the passenger flow system within a preset collection time, calculating the space density according to the passenger flow volume, and uploading the space density to the programmable gateway.

And the host computer matches the corresponding air conditioner adjustment strategy according to the space density. Different space densities correspond to different air conditioning strategies, i.e., different space densities correspond to different target humiture. Wherein, the target temperature and humidity are also related to seasons. For example, when the space density is high, in summer, the air conditioning mode corresponding to the target temperature and humidity is 22 degrees cooling, and the wind speed is high. If the temperature is winter, the air conditioning mode corresponding to the target temperature and humidity can be heating at 18 degrees, and the wind speed is automatic. If the space density is small, the air conditioning mode corresponding to the target temperature and humidity can be refrigeration at 25 degrees and the wind speed is automatic. If winter is adopted at this time, the air conditioning mode corresponding to the target temperature and humidity can be 20 degrees of heating, and the wind speed is high wind. The intelligent environmental control system judges whether the temperature and humidity of the store at the moment are target temperature and humidity, and if yes, the air conditioning mode is not adjusted. If not, matching the corresponding air conditioning mode according to the space density, and sending a control instruction to the air conditioner of the corresponding area. After receiving the control instruction, the air conditioner in the corresponding area is adjusted to be in a corresponding air conditioning mode. The control instruction includes an air conditioning mode to be adjusted by the air conditioner.

According to the temperature and humidity data collected and the air conditioner adjustment strategy, the air conditioner mode in the store is intelligently adjusted, so that customers in the store are always in the optimal temperature and humidity environment.

Wherein, in the adjusting strategy of the air conditioning system, an air quality sensor can be arranged and is generally arranged at the bottom of the table and mainly used for collecting PM2.5 and CO in the air ₂ 、O ₂ And CO. For example, the value acquired by the air quality sensor is compared with a target value of a preset air quality to determine whether to trigger the adjustment of the air quality. The air quality of the store is adjusted and improved through the air conditioner so as to reach the target value of the air quality.

Referring to fig. 10, fig. 10 is a schematic flow chart of a fragrance system adjustment according to an embodiment of the present application. As shown in fig. 10, when in the store-on mode, the store activates the intelligent climate control system. At this time, the in-store odor collection system starts collecting the odor concentration of the store. Wherein, the smell collection system may include a plurality of smell detection sensors, each smell detection sensor collecting a smell concentration of a corresponding region. For example, the odor collection system of a store includes an odor detection sensor a and an odor detection sensor B. The odor detection sensor a is in the store's prototype terminal E and the odor detection sensor B is in the store's prototype terminal F. The odor detection sensor A and the odor detection sensor B upload the collected odor concentration to a protocol gateway, the protocol gateway uploads the collected odor concentration to a host, and the host uploads the collected odor concentration to a local area network. Meanwhile, the passenger flow system in the store counts the passenger flow of the store through the passenger flow counting and monitoring device. And the passenger flow system continuously collects passenger flow, calculates space density according to the passenger flow, and uploads the space density to the programmable gateway. The programmable gateway is uploaded to the local area network.

The host computer matches the corresponding regulation strategy according to the size of the space density, namely, the starting interval and the starting duration of the fragrance machine in the store are controlled. For example, if the space density is greater than the set value, the fragrance machine is adjusted to be started for X1 seconds at an interval of Y1 seconds and then stopped; if the space density is smaller than the set value, the fragrance machine is adjusted to be started for X2 seconds at intervals of Y2 seconds and stopped. In general, the greater the spatial density, the shorter the actuation interval of the fragrance machine and the longer the actuation period. For example, Y1 may be smaller than Y2, and X1 may be larger than X2.

According to the method and the device, according to the collected odor concentration and the set fragrance machine adjustment strategy, the starting of the fragrance machine in the store is intelligently adjusted, so that customers in the store cannot be in an environment with too-thick or too-thin fragrance.

In this embodiment of the present application, the real-time adjustment of the lighting system, the curtain system, the sound system, the air conditioning system, and the fragrance system is performed, so that the overall store environment is optimally performed in real time. The system can form integration with people, shops and environments in coordination, provides efficient, comfortable, convenient, warm and more atmosphere shopping experience for consumers, realizes comprehensive and reasonable monitoring of safe, energy-saving, environment-friendly, electric, acoustic, cold and heat energy sources for the shops, and more effectively plans, organizes, controls and coordinates the use of the energy sources.

In this embodiment of the present application, the adjustment of the store environment may include not only the adjustment of the lighting system, the curtain system, the sound system, the air conditioning system, and the fragrance system, but also the adjustment of other execution devices in the store, and the corresponding device management method may refer to the adjustment of the above system.

In some embodiments, the security system may also be device-managed and an infrared sensor may be used. Then a security adjustment module may be included in the data model module described above. In the control strategy of the security system, an infrared sensor detects infrared radiation from the human body or animal in the environment to judge whether suspicious personnel invade the defense area.

In the embodiment of the present application, as shown in fig. 11, in the control strategy of the lighting system, the light sensor of the prototype terminal is used. Factors affecting the control strategy of the lighting system include season, time, natural light, weather, window shade elevation/shutter tilt ratio, experiencing a target brightness of 2000 lumens (target light intensity) at the table top, etc. In the control strategy of the window covering system, a temperature sensor and a wind, light and rain sensor are used. Factors affecting the control strategy of the shade system include season, time, natural light, overcast and rainy days, etc. In the control strategy of the sound system, microphone sensors and passenger flow systems are used. The influence factors of the control strategy of the sound system comprise in-store/out-of-store environmental sounds, high and low sounds of a single song, passenger flow density and target decibels of music fluctuating within the range of 60-65 db according to different numbers of people. In the control strategy of air conditioning systems, air quality sensors, temperature and humidity sensors and passenger flow systems are used. The control strategy of the air conditioning system has influence factors including the interaction between a store and the outside air, the passenger flow density, the proper environment temperature of a human body between 22 and 24 degrees (target temperature), the humidity between 40 and 50 percent (target humidity) and the like. In the control strategy of the fragrance system, odour detection sensors and passenger flow systems are used. The control strategy of the fragrance system has influence factors including time, season, passenger flow density, target atomization amount of 3ml plus or minus 5%, odor concentration and the like.

According to the embodiment of the application, the terminal equipment is utilized to carry out self-contained sensors and independent sensors, collected data are transmitted to the intelligent environmental control system, and the systems such as illumination, air conditioning, sound equipment, curtains and fragrance are adjusted according to the pre-established intelligent adjustment model, so that a store is in an optimal environment, and consumer experience is guaranteed. And, peripheral systems such as passenger flow are combined to integrate linkage analysis control. Intelligent control impact factors and control strategy analysis adapted to the 3C retail store are output.

In some embodiments, as shown in fig. 12, a structural schematic of an electronic device is provided. The electronic device comprises a processor 1001 and a communication module 1002.

The processor 1001 is configured to execute the device management method executed by the server or the terminal or the controlled device in the device management system in the above embodiment. The processor 1001 may be a central processing unit (centra l process ing un it, CPU), a digital signal processor (d igital s igna l processor, DSP), an Application Specific Integrated Circuit (ASIC), a field programmable gate array (fie ld programmab le gate array, FPGA) or other programmable logic device, a transistor logic device, a hardware component, or any combination thereof. The processor may include an application processor and a baseband processor. Which may implement or perform the various exemplary logic blocks, modules, and circuits described in connection with this disclosure. The processor may also be a combination that performs the function of a computation, e.g., a combination comprising one or more microprocessors, a combination of a DSP and a microprocessor, and the like. The communication module 1002 may be a transceiver, transceiver circuitry, or the like. The memory module may be a memory.

For example, the processor 1001 may be the processor 310 shown in fig. 3, and the communication module 1002 includes a radio frequency module (e.g., the radio frequency module 350 shown in fig. 3). The communication modules may also include Wi-Fi modules and bluetooth modules, radio frequency modules 350, and the like. The memory module may be a memory (such as internal memory 321 shown in fig. 3). The terminal provided in the embodiment of the present application may be the electronic device 100 shown in fig. 3.

Embodiments of the present application also provide a computer-readable storage medium including computer instructions that, when executed on an electronic device described above, cause the electronic device to perform the functions or steps performed by the electronic device 100 in the method embodiments described above. The electronic device may be any of the devices described above in the device management system.

Embodiments of the present application also provide a computer program product which, when run on a computer, causes the computer to perform the functions or steps performed by the electronic device 100 in the method embodiments described above. For example, the computer may be the electronic device 100 described above. The computer may be any of the devices of the device management system described above.

It will be apparent to those skilled in the art from this description that, for convenience and brevity of description, only the above-described division of the functional modules is illustrated, and in practical application, the above-described functional allocation may be performed by different functional modules according to needs, i.e. the internal structure of the apparatus is divided into different functional modules to perform all or part of the functions described above.

In the several embodiments provided in this application, it should be understood that the disclosed apparatus and method may be implemented in other ways. For example, the apparatus embodiments described above are merely illustrative, e.g., the division of the modules or units is merely a logical functional division, and there may be additional divisions when actually implemented, e.g., multiple units or components may be combined or integrated into another apparatus, or some features may be omitted, or not performed. Alternatively, the coupling or direct coupling or communication connection shown or discussed with each other may be an indirect coupling or communication connection via some interfaces, devices or units, which may be in electrical, mechanical or other form.

The units described as separate parts may or may not be physically separate, and the parts displayed as units may be one physical unit or a plurality of physical units, may be located in one place, or may be distributed in a plurality of different places. Some or all of the units may be selected according to actual needs to achieve the purpose of the solution of this embodiment.

In addition, each functional unit in each embodiment of the present application may be integrated in one processing unit, or each unit may exist alone physically, or two or more units may be integrated in one unit. The integrated units may be implemented in hardware or in software functional units.

The integrated units, if implemented in the form of software functional units and sold or used as stand-alone products, may be stored in a readable storage medium. Based on such understanding, the technical solution of the embodiments of the present application may be essentially or a part contributing to the prior art or all or part of the technical solution may be embodied in the form of a software product stored in a storage medium, including several instructions for causing a device (may be a single-chip microcomputer, a chip or the like) or a processor (processor) to perform all or part of the steps of the methods described in the embodiments of the present application. And the aforementioned storage medium includes: a usb disk, a removable hard disk, a read-only memory (read on ly memory, ROM), a random access memory (random access memory, RAM), a magnetic disk, or an optical disk, or the like, which can store program codes.

The foregoing is merely a specific embodiment of the present application, but the scope of the present application is not limited thereto, and any changes or substitutions within the technical scope of the present disclosure should be covered in the scope of the present application. Therefore, the protection scope of the present application shall be subject to the protection scope of the claims.

Claims (12)

1. A device management method, characterized by being applied to a device management system, the device management system comprising a plurality of terminals, a plurality of first sensors, one or more ring control devices and one or more execution devices; the terminals are placed at fixed positions of one or more showing tables in the exhibition hall, and one or more second sensors are arranged in the terminals; the plurality of first sensors include an illumination sensor, a temperature sensor, a humidity sensor, an air quality sensor, a rain sensor, and an odor detection sensor, and the one or more second sensors include a microphone sensor, a temperature sensor, a humidity sensor, an odor detection sensor, and a light sensor; data collected by the first sensor and the second sensor distributed in different areas of the exhibition hall for controlling unused execution devices, the method comprising:

Each first sensor of the plurality of first sensors collects first environmental data and sends the first environmental data to the one or more environmental control devices;

each second sensor of the one or more second sensors collects second environmental data, and the plurality of terminals send the second environmental data to the one or more environmental control devices;

the one or more environmental control devices receive the first environmental data and the second environmental data, and determine target environmental data of each of the one or more execution devices according to a preset environmental control strategy according to the first environmental data and the second environmental data; wherein the target environmental data includes any one of illumination intensity, temperature, humidity, air quality, sound parameters, and odor concentration;

the one or more environmental control devices send corresponding target environment data to the one or more execution devices;

the one or more execution devices receive the target environmental data and adjust current environmental data to the target environmental data.

2. The device management method according to claim 1, wherein the preset environmental control policy configures one or more environmental control devices, the preset environmental control policy is used to indicate a plurality of environmental data ranges, and target environmental data corresponding to each environmental data range;

The determining, according to the first environmental data and the second environmental data and according to a preset loop control policy, target environmental data of each of the one or more execution devices includes:

the one or more environmental control devices determine actual environmental data of each of a plurality of areas where the plurality of first sensors and the one or more second sensors are located according to the first environmental data and the second environmental data;

and the one or more environmental control devices determine target environmental data corresponding to the environmental data range where the actual environmental data of each region is located according to the preset environmental control strategy.

3. The device management method according to claim 1, wherein the one or more ring control devices are further configured with correspondence between the first sensor and the second sensor distributed in different areas of the exhibition hall and the one or more execution devices;

the one or more environmental control devices sending corresponding target environment data to the one or more execution devices, including:

and the one or more environmental control devices send corresponding target environment data to the one or more execution devices according to the corresponding relation.

4. A device management method according to any one of claims 1-3, wherein the device management system further comprises a passenger flow system, and the passenger flow system is used for collecting passenger flow data;

the determining, according to the first environmental data and the second environmental data and according to a preset loop control policy, target environmental data of each of the one or more execution devices includes:

the one or more environmental control devices receive passenger flow data sent by the passenger flow system;

and the one or more environmental control devices refer to the passenger flow data, and determine target environmental data of each of the one or more execution devices according to the first environmental data and the second environmental data and a preset environmental control strategy.

5. The device management method according to claim 1, characterized in that the method further comprises:

the plurality of first sensors establish communication connection with the one or more environmental control devices;

and the terminal where the one or more second sensors are located is in communication connection with the one or more environmental control devices.

6. The device management method according to any one of claims 1 to 5, wherein the adjusting the current environment data to the target environment data includes:

And the one or more execution devices adjust the current environment data into the target environment data according to preset adjustment steps.

7. A device management system, the system comprising a plurality of terminals, a plurality of first sensors, one or more environmental control devices, and one or more execution devices; the terminals are placed at fixed positions of one or more showing tables in the exhibition hall, and one or more second sensors are arranged in the terminals; the plurality of first sensors include an illumination sensor, a temperature sensor, a humidity sensor, an air quality sensor, a rain sensor, and an odor detection sensor, and the one or more second sensors include a microphone sensor, a temperature sensor, a humidity sensor, an odor detection sensor, and a light sensor; data collected by the first sensor and the second sensor distributed in different areas of the exhibition hall for controlling unused execution devices, the system comprising:

each first sensor of the plurality of first sensors is configured to collect first environmental data, and send the first environmental data to the one or more environmental control devices;

Each of the one or more second sensors is configured to collect second environmental data, and the plurality of terminals send the second environmental data to the one or more environmental control devices;

the one or more environmental control devices are configured to receive the first environmental data and the second environmental data, and determine target environmental data of each of the one or more execution devices according to a preset environmental control policy according to the first environmental data and the second environmental data; wherein the target environmental data includes any one of illumination intensity, temperature, humidity, air quality, sound parameters, and odor concentration;

the one or more environmental control devices are further configured to send corresponding target environment data to the one or more execution devices;

the one or more execution devices are configured to receive the target environmental data and adjust current environmental data to the target environmental data.

8. The system of claim 7, wherein the preset gating strategy configures one or more gating devices, the preset gating strategy being configured to indicate a plurality of environmental data ranges and target environmental data corresponding to each environmental data range;

The one or more environmental control devices are further configured to determine actual environmental data of each of a plurality of areas where the plurality of first sensors and the one or more second sensors are located according to the first environmental data and the second environmental data; and determining target environment data corresponding to the environment data range of the actual environment data of each region according to the preset environmental control strategy.

9. The system of claim 7, wherein the one or more environmental control devices are further configured with correspondence of the first sensor and the second sensor distributed in different areas of the exhibition hall to the one or more execution devices;

the one or more environmental control devices are further configured to send corresponding target environment data to the one or more execution devices according to the correspondence.

10. The system according to any one of claims 7-9, further comprising a passenger flow system, wherein the passenger flow system is configured to collect passenger flow data;

the one or more environmental control devices are further configured to receive passenger flow data sent by the passenger flow system; and determining target environment data of each execution device of the one or more execution devices according to the first environment data and the second environment data and a preset environmental control strategy by referring to the passenger flow data.

11. The system of claim 7, wherein the system further comprises:

the plurality of first sensors are used for establishing communication connection with the one or more ring control devices;

and the terminal where the one or more second sensors are located is used for establishing communication connection with the one or more ring control devices.

12. The system according to any of claims 7-11, wherein the one or more executing devices are configured to adjust the current environmental data to the target environmental data in a preset adjustment step.

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