CN107367983B - Intelligent service system for glasses - Google Patents

Abstract

The invention discloses an intelligent glasses service system, and belongs to the field of glasses retail in wearable consumer products. The system comprises an IOT, a user management module and a user management module, wherein the IOT is used for the management of IOT users and the management and maintenance of equipment; the ARM board is connected with the MCU control board and is used for sending instructions of running of the sub-equipment, receiving instructions reported by the sub-equipment and providing a man-machine interaction function, a virtual try-on function, a monitoring photographing function and a video voice playing function; UC/Mall is used for managing users in malls, managing points of consumers, managing glasses information of consumers, receiving orders placed by equipment ends or business fields, pushing orders placed by consumers to ERP, receiving order state update and point acquisition mode management. The invention integrates intelligent glasses cleaning, automatic lens parameter reading and virtual try-on, and users log in to perform self-service glasses cleaning, lens degree reading, virtual try-on experience, free charging, glasses cloth feeding and the like, and can place online orders, thereby completing the fusion of online and offline.

Description

Intelligent service system for glasses

Technical Field

The invention belongs to the field of eyeglass retail in wearable consumer products, and particularly relates to an eyeglass intelligent service system.

Background

In recent years, the China macroscopic economy is steadily developed, and the retail market of the Chinese glasses is steadily increased along with the rigid requirement of high myopia rate. With the annual increase of incomes available to residents, the living standard and the consumption capability of people are continuously improved, and consumers can purchase a plurality of pairs of glasses to meet the wearing demands of different occasions, and the rapid growth of the retail market of the glasses is stimulated by selecting a frame made of ultra-light new materials, radiation-resistant and fatigue-resistant multifunctional lenses.

The chinese eyeglass market has a total size of approximately 700 billion in 2016, with optical eyeglass sizes of approximately 560 billion. Traditional optical eyeglass retailers are subject to the pressure of high operation and maintenance costs, high inventory pressure and constant rising rents, and have sought a way to change. In recent years, some electronic commerce have appeared to attract consumers to sell glasses by displaying various styles on-line.

Compared with the traditional offline channel, the online sales glasses have the following advantages: firstly, the glasses are more in style, and the problem that the product style of the physical store cannot be displayed due to the area and the stock pressure is solved; and secondly, the system is in direct contact with wide terminal clients, and can widely, clearly and deeply transfer brand and product information.

However, since the network sales glasses cannot provide optometry service, the network sales contact lenses are strictly controlled, and at present, the on-line glasses retail is mainly sunglasses, and the proportion of the network sales to the Chinese glasses retail market is still not high.

Disclosure of Invention

The invention provides an intelligent service system for glasses, which aims to overcome the defects that in the prior art, the operation and maintenance cost of off-line shops is high, the stock pressure is high, the coverage range is limited, and the consumers are difficult to customize and the actual wearing experience demands of glasses electronic commerce are difficult to meet.

In order to achieve the above purpose, the present invention adopts the following technical scheme:

an eyeglass intelligent service system, comprising:

the IOT is communicated with the ARM board through the Http and Socket interfaces and is used for management of IOT users and management and maintenance of equipment;

the ARM board is connected with the MCU control board and communicated with the sub-equipment through an RS232 serial port and is used for sending an instruction of the operation of the sub-equipment, receiving an instruction reported by the sub-equipment and providing a man-machine interaction function, a virtual try-on function, a monitoring photographing function and a video voice playing function;

UC/Mall is communicated with the IOT and ARM boards through the Http interface and is used for managing users in a Mall, managing points of consumers, managing glasses information of the consumers, receiving orders placed by a device end or a business field, pushing orders placed by consumers to ERP, receiving order state update and point acquisition mode management;

the ARM board is connected with the video module, the camera, the audio module and the WIFI/4G communication module; the MCU control panel is connected with the automatic dioptre module, the ultrasonic cleaner control module, the glasses taking cloth module, the self-service charging module, the bin gate control module and the lamp strip control module; the power supply required by each module is provided by a power supply module;

the video module comprises a display screen and a touch screen;

the camera comprises a virtual try-on camera and a monitoring camera which are operated independently.

Further, the automatic lensometer module controls the automatic lensometer to measure each parameter of the glasses, and puts the glasses into the ultrasonic cleaner and feeds back the measurement result and the cleaning completion information;

the ultrasonic cleaner control module controls the starting or stopping of the cleaning of the ultrasonic cleaner, self-checking the equipment and feeding back the result;

the glasses cloth taking module controls resetting of a glasses cloth rotating disc, cloth discharging of an automatic glasses cloth machine and self-checking and feedback of a result of equipment;

the self-service charging module controls the charging port to start or stop charging, and the device self-checks and feeds back the result;

the bin gate control module controls the bin gate to be opened or closed, detects whether the bin gate is opened or closed in place, and whether foreign matter blocking exists in the closing process of the bin gate, and self-checks equipment and feeds back a result;

the lamp strip control module controls the lamp strip brightness adjustment according to the virtual try-on scene.

Further, RS232 serial communication is adopted between the automatic power meter module and the MCU control board.

Further, the audio module and the self-service charging module are powered by AC220V or DC 5V.

Further, the audio module and the self-service charging module adopt independent power boxes to provide 5V power.

Further, the ARM board is powered by two power supplies of 5V or 12V, and the two power supplies correspond to two different ARM boards respectively.

Further, a UART serial port on the ARM board is converted into an RS232 serial port through a UART serial port level conversion board and is connected with the MCU control board.

Further, the IOT includes a server, a communication protocol implementation module, a user management module, a device management module, a system log module, and an interface opened to other modules;

the user management module comprises user information management and user authority management, wherein the user authority management comprises role management, authority management and resource management;

the device management module comprises device information management and device maintenance, wherein the device information management comprises version management, APP version management, basic information management, map distribution, user use statistics and content management; device maintenance includes device content remote update, device APP remote update, timing self-check, device registration, system log, system configuration, and table definition.

Further, the software part on the ARM board comprises an APP interface and an APP background, wherein the APP interface comprises a user operation interface and a maintenance interface; the APP background comprises a timing module, a user interface interaction module, a local running state recording module, a log system module, a downloading module and a periodic timing task module.

The beneficial effects are that:

the invention integrates three core technologies of intelligent glasses cleaning, automatic lens parameter reading and virtual try-on, and after a user logs in, the user can carry out self-service glasses cleaning, lens degree reading, virtual try-on experience, free charging, free glasses cloth feeding and the like, and can place an order on line, thereby completing the fusion of on-line and off-line.

Drawings

FIG. 1 is a block diagram of the software architecture of the intelligent eyeglass service system of the present invention;

FIG. 2 is a block diagram of the basic architecture of an IOT of the present invention;

FIG. 3 is a block diagram of the hardware architecture of the intelligent eyeglass service system of the present invention;

FIG. 4 is a basic structural block diagram of an ARM board of the invention;

FIG. 5 is a communication structure of the intelligent eyeglass service system of the present invention;

fig. 6 is a flow chart for use with the present invention.

Detailed Description

The invention will be further described with reference to the drawings and examples.

The invention relates to an intelligent service system for glasses, as shown in figure 1, the software part mainly comprises: IOT (internet of things server) 1, which is used for the management of IOT users and the management (registration, inquiry, connection, remote control, etc.) and maintenance (mainly, remote update of devices) of devices;

UC/Mall (user center/online Mall) 3 for managing a Mall user (including consumer user and Mall management user, such as user name, password, letter association, receiving address, contact, etc.), managing consumer points, managing consumer glasses information, receiving an order placed on the equipment side or the Mall, pushing an order placed by a consumer to ERP (production link), and receiving an order status update, and point acquisition mode management;

the user can enter Mall through the Device-App, the Mall webpage end and the Mall-App; the user can enter UC to access through the Device-App and the Mall-App; information is pushed between the Device-App and the IOT 1 and between the IOT 1 and the Mall; IOT 1 and Mall can enter UC to access users; IOT 1 is connected to the device database, UC is connected to the user database, mall is connected to the Mall database, and Mall is also connected to the third party interface;

wherein Device-App: android application installed on the equipment, a display interface and user interaction; mall web page end: a mall PC webpage version; mall-App: mall mobile phone application; UC may be included in Mall as a sub-module of Mall; device database: storing information related to equipment, including equipment on-line state, equipment registration state, equipment running state, equipment self-checking state and the like; user database: storing user related information including user name, password, point, receiving address, mail, mobile phone number, etc.; mall database: store orders, glasses information (price, quantity), promotions, etc.; ERP: the production link receives the order and feeds back the order state; the third party interface includes a third party payment interface: mall third party payment interface access, e.g., weChat payment; third party login interface: mall third party login interface access, e.g., weChat login; third party notification interface: mall short message push notification, application message push, mail notification, etc.

As shown in fig. 2, the software part on IOT 1 includes a server 101, a communication protocol implementation module 102, a user management module 103, a device management module 104, a system log module 105, and an interface 106 opened to other modules (Socket and REST);

the user management module 103 includes user information management and user authority management, wherein the user authority management includes role management, authority management and resource management; the user-defined IOT background maintenance personnel are not the end-use device consumers;

the device management module 104 includes device information management and device maintenance, wherein the device information management includes version management, APP version management, basic information management, map distribution, user usage statistics and content management; device maintenance includes device content remote update, device APP remote update, timing self-check, device registration, system log, system configuration, and table definition.

As shown in fig. 3, the hardware part mainly comprises an ARM board (ARM board in the device) 2, which is connected with an MCU control board 4, and is used for sending instructions (including automatic lensometer, automatic cleaning machine, bin gate, automatic glasses cloth machine, etc.) for running the sub-device, receiving instructions reported by the sub-device, and providing man-machine interaction function, virtual try-on function, monitoring photographing function and video voice playing function; the video module 5, the camera 6, the audio module 7 and the WIFI/4G communication module 8 are connected with the ARM board 2, and the automatic dioptric power meter module 9, the ultrasonic cleaner control module 10, the glasses taking cloth module 11, the self-service charging module 12, the bin gate control module 13 and the lamp strip control module 14 are connected with the MCU control board 4; the power required by each module is supplied with AC220V by the power module 15;

the model of the MCU control board 4 is STM32F407IGT6;

the video module 5 includes a display screen 51 and a touch screen 52;

the camera 6 includes a virtual try-on camera 61 and a monitoring camera 62 which operate independently of each other;

the WIFI/4G communication module 8 communicates through a USB interface and is accessed to a network;

the automatic dioptric power meter module 9 is communicated with the MCU control board 4 by adopting an RS232 serial port;

the sub-equipment modules comprise an automatic dioptre module 9, an ultrasonic cleaner control module 10, a glasses cloth taking module 11, a self-service charging module 12, a bin gate control module 13 and a lamp strip control module 14;

the automatic lensometer module 9 controls the automatic lensometer to measure parameters such as the degree, the pupil distance and the like of the glasses, and puts the glasses into an ultrasonic cleaner and feeds back the measurement result and the cleaning completion information;

the ultrasonic cleaner control module 10 controls the starting or stopping of the cleaning of the ultrasonic cleaner, self-checking the equipment and feeding back the result;

the glasses cloth taking module 11 controls resetting of a glasses cloth rotating disc, cloth discharging of an automatic glasses cloth machine and self-checking and feedback of a result of equipment;

the self-service charging module 12 controls the charging port to start or stop charging, and the equipment self-tests and feeds back the result;

the bin gate control module 13 controls the bin gate to be opened or closed, detects whether the bin gate is opened or closed in place, and whether foreign matter blocking exists in the closing process of the bin gate, and self-checks equipment and feeds back a result;

the lamp band control module 14 controls lamp band brightness adjustment according to the virtual try-on scene;

the audio module 7 and the self-service charging module 12 can be powered by AC220V or DC 5V;

when the audio module 7 and the self-service charging module 12 use 5V power supply, an independent power supply box (an auxiliary switch power supply box) is adopted to supply power to the two modules, namely, the whole system adopts a double power supply box (a main switch power supply box and an auxiliary switch power supply box) to supply power, so that the advantage is that the power supply pressure of the main switch power supply box is lightened, and the main functional stability of the system is enhanced;

the ARM board 2 is powered by two voltages of 5V or 12V, which correspond to two different ARM boards (a Firefly-RK3288 board and a Firefly-RK3288 read board) respectively;

the UART serial port on the ARM board 2 is TTL level, so for stability of data transmission, the TTL level needs to be converted into RS232 level, and therefore a UART serial port level conversion board (232 level conversion chip) needs to be added, and the UART serial port level conversion board should be as close to the ARM board 2 as possible.

As shown in fig. 4, the software part on the ARM board 2 includes an APP interface 201 and an APP background 202, wherein the APP interface 201 includes a user operation interface 2011 and a maintenance interface 2012; APP background 202 includes a timing module 2021, a user interface interaction module 2022, a local running state recording module 2023, a log system module 2024, a download module 2025, and a periodic timing task module 2026.

As shown in fig. 5, the communication structure between the software part and the hardware part is: the IOT 1 and the ARM board 2 communicate through the Http and Socket interface, wherein the Socket: the IOT 1 is connected with the ARM board 2 in a long way and is used for pushing and receiving information at any time, sending instructions and receiving instructions according to a protocol, and managing equipment and reporting equipment information; http: ARM board 2 downloads content such as new version Device-App (Android application installed on Device) from IOT 1, updated advertisement content and other dynamic content;

the ARM board 2 and the MCU control board 4 communicate with the sub-equipment through an RS232 serial port, send and receive instructions according to a protocol, and manage the sub-equipment and report faults of the sub-equipment;

UC/Mall3 communicates with IOT 1 through Http interface, IOT 1 is used as intermediate agent of UC/Mall3 pushing message to Device-ARM, and authentication of Device on IOT 1;

UC/Mall3 communicates with ARM board 2 through Http interface, ARM board 2 obtains and updates user information, obtains and updates virtual try-on information from UC/Mall3, and can make bill, point purchase, etc.

The invention relates to an intelligent service system for glasses, which comprises the following steps: as shown in fig. 6, the home page is clicked arbitrarily, the user logs in the interface: the user scans through WeChat, and the system enters a login/registration interface. If the member is the existing member, the user directly enters into use; if the member is a new member, the mobile phone verification is needed to finish registration; the system distributes user numbers for users and establishes personal information files (members can complete user information improvement and modification through mobile phone APP/equipment); control interface: after the user finishes logging in, the user enters the control interface. Here, the user may make a selection service: basic services such as self-cleaning glasses, virtual try-on/automatic focusing/self-printing photos, online ordering and the like; user cleaning interface: in the cleaning process of a user, the system automatically performs focal power for the user and collects glasses information of the user; advertisement interface: in the cleaning waiting process, the system automatically plays advertisements and prompts the user to perform virtual try-on experience; virtual try-on interface: the user selects virtual try-on, enters a virtual try-on interface, and selects different glasses models for experience, and in the user experience process, the system automatically recommends new glasses for the user on site according to user behaviors; if the user looks at a certain glasses, the user can select to place an online bill, and the system directly jumps to an online mall to complete online purchase; on-line printing interface: in the virtual try-on process of the user, a certain modeling can be selected, and the photos can be saved and printed on line. In principle, each user only prints one sheet every day, and if more sheets are needed, the user can select point exchange or online purchase; after the glasses are washed, the user can select whether to receive the glasses cloth for free. In principle, each user can only pick up one piece of glasses per day. If a plurality of sheets are needed, the points are needed to be exchanged; the whole operation is completed, and the system is restored to the original interface; the point exchange mode is as follows: check in daily, shopping each time; every time a new member is recommended, the points can be exchanged.

It should be apparent to those skilled in the art that various modifications or variations can be made in the present invention without requiring any inventive effort by those skilled in the art based on the technical solutions of the present invention.

Claims (8)

1. An intelligent eyeglass service system, comprising:

the IOT (1) is communicated with the ARM board (2) through an Http and Socket interface and is used for management of IOT users and management and maintenance of equipment;

the ARM board (2) is connected with the MCU control board (4) and is communicated with the sub-equipment through an RS232 serial port, and is used for sending an instruction of the operation of the sub-equipment, receiving an instruction reported by the sub-equipment, and providing a man-machine interaction function, a virtual try-on function, a monitoring photographing function and a video voice playing function;

UC/Mal (3) is communicated with the IOT (1) and the ARM board (2) through the Http interface and is used for managing users in a Mall, managing points of consumers, managing glasses information of the consumers, receiving orders placed by a device side or a business, pushing orders placed by consumers to ERP, receiving order state update and point acquisition mode management;

the ARM board (2) is connected with the video module (5), the camera (6), the audio module (7) and the WIFI/4G communication module (8); the MCU control panel (4) is connected with the automatic dioptric power meter module (9), the ultrasonic cleaner control module (10), the glasses taking cloth module (11), the self-service charging module (12), the bin gate control module (13) and the lamp strip control module (14); the power supply required by each module is provided by a power supply module (15);

the automatic lensometer module (9) controls the automatic lensometer to measure each parameter of the glasses, and puts the glasses into the ultrasonic cleaner and feeds back the measurement result and the cleaning completion information;

the ultrasonic cleaner control module (10) controls the starting or stopping of cleaning of the ultrasonic cleaner, self-tests equipment and feeds back a result;

the glasses cloth taking module (11) controls resetting of a glasses cloth rotating disc, cloth discharging of an automatic glasses cloth machine and self-checking and feedback of a result;

the self-service charging module (12) controls the charging port to start or stop charging, and the equipment self-checks and feeds back the result;

the bin gate control module (13) controls the bin gate to be opened or closed, detects whether the bin gate is opened or closed in place, and whether foreign matter blocking exists in the closing process of the bin gate, and self-checks equipment and feeds back a result;

the lamp strip control module (14) controls lamp strip brightness adjustment according to the virtual try-on scene;

the video module (5) comprises a display screen (51) and a touch screen (52);

the camera (6) comprises a virtual try-on camera (61) and a monitoring camera (62) which are operated independently;

the use flow is as follows: clicking the first page at will, and logging in the interface by the user: the user scans through WeChat, the system enters the login/registration interface; if the member is the existing member, the user directly enters into use; if the member is a new member, the mobile phone verification is needed to finish registration; the system allocates a user number for the user and establishes a personal information file; control interface: after the user finishes logging in, entering a control interface; here, the user may make a selection service: self-cleaning glasses/virtual try-on/automatic power/self-printing photos/online ordering; user cleaning interface: in the cleaning process of a user, the system automatically performs focal power measurement for the user and collects glasses information of the user; advertisement interface: in the cleaning waiting process, the system automatically plays advertisements and prompts the user to perform virtual try-on experience; virtual try-on interface: the user selects virtual try-on, enters a virtual try-on interface, and selects different glasses models for experience, and in the user experience process, the system automatically recommends new glasses for the user on site according to user behaviors; if the user looks at a certain glasses, the user can select to place an online bill, and the system directly jumps to an online mall to complete online purchase; on-line printing interface: in the virtual try-on process of the user, a certain modeling can be selected, and the photo can be saved and printed on line; in principle, each user only prints one sheet every day, and if more sheets are needed, the user can select point exchange or online purchase; after the glasses are cleaned, the user can select whether to receive the glasses cloth for free; in principle, each user can only pick up one piece of glasses cloth every day; if a plurality of sheets are needed, the points are needed to be exchanged; the whole operation is completed, and the system is restored to the original interface; the point exchange mode is as follows: check in daily, shopping each time; every time a new member is recommended, the points can be exchanged.

2. The glasses intelligent service system according to claim 1, wherein the automatic power meter module (9) and the MCU control board (4) adopt RS232 serial port communication.

3. The glasses intelligent service system according to claim 1, wherein the audio module (7) and the self-service charging module (12) are powered by AC220V or DC 5V.

4. The glasses intelligent service system according to claim 3, wherein the audio module (7) and the self-service charging module (12) adopt independent power boxes to provide 5V power.

5. The intelligent eyeglass service system according to claim 1, wherein the ARM board (2) is powered by two power supplies of 5V or 12V, corresponding to two different ARM boards respectively.

6. The glasses intelligent service system according to claim 1, wherein a UART serial port on the ARM board (2) is converted into an RS232 serial port by a UART serial port level conversion board (21) and is connected with the MCU control board (3).

7. The glasses intelligent service system according to claim 1, wherein the IOT (1) comprises a server (101), a communication protocol implementation module (102), a user management module (103), a device management module (104), a system log module (105) and an interface (106) opened to other modules;

the user management module (103) comprises user information management and user authority management, wherein the user authority management comprises role management, authority management and resource management;

the device management module (104) comprises device information management and device maintenance, wherein the device information management comprises version management, APP version management, basic information management, map distribution, user usage statistics and content management; device maintenance includes device content remote update, device APP remote update, timing self-check, device registration, system log, system configuration, and table definition.

8. The eyeglass smart service system of claim 1, wherein the software portion on the ARM board (2) comprises an APP interface (201) and an APP background (202), wherein the APP interface (201) comprises a user operations interface (2011) and a maintenance interface (2012); the APP background (202) includes a timing module (2021), a user interface interaction module (2022), a local running state recording module (2023), a log system module (2024), a download module (2025), and a periodic timing task module (2026).