CN211044676U - NBIOT intelligent development experiment platform based on cloud control - Google Patents

Abstract

The utility model discloses a NBIOT intelligent development experiment platform based on cloud control, which comprises a sensor system, a ZIGBEE system, an intelligent voice system, a controller system, a base station, a cloud server and a mobile client, wherein the sensor system, the ZIGBEE system, the intelligent voice system, the controller system, the cloud server and the mobile client are respectively in communication connection with the base station; the sensor system is responsible for collecting environmental data; the ZIGBEE system is responsible for establishing a local area network and networking functions of the sensor system, the intelligent voice system and the controller system; the intelligent voice system is responsible for the man-machine conversation function with the mobile client; the controller system is responsible for device control functions, controlling device switches and device states. The utility model realizes the data interaction with the cloud end on the basis of the function of the experimental platform of the Internet of things; data are interacted with the cloud end by using an NBIOT technology; and the cloud processing data is utilized to realize the development function of the intelligent product.

Description

NBIOT intelligent development experiment platform based on cloud control

Technical Field

The utility model relates to an intelligence development experiment platform technical field, concretely relates to NBIOT intelligence development experiment platform based on high in clouds control.

Background

The internet of things is one of strategic emerging industries for the nation to decide to develop vigorously. From the smart earth to the perception of China, the Internet of things is receiving international attention. With the rapid development of the internet of things, the application requirements of various social industries are more and more obvious and urgent, and the method is used as a key college for developing main forces of national science and technology, builds a laboratory of the internet of things, develops targeted teaching and scientific research, cultivates professional technical talents, and is beneficial to the development of subjects of schools and the promotion of the field of teaching and scientific research.

For students or teachers who are specialized in the internet of things, the internet of things laboratory is a core laboratory which is closely combined with teaching and scientific research of the profession, and requirements of the students or teachers in the aspects of learning and researching the internet of things technology can be met comprehensively.

For schools with the course of the internet of things and students who choose and amend the course, the internet of things laboratory can comprehensively show the application of the internet of things technology, so that students and teachers can master basic theories and technologies of the internet of things and application methods.

For students or teachers in other related professions, such as students or teachers in computer software and hardware, communication, automation, logistics management and other professions, the application of the internet of things technology in the profession can be further mastered through an internet of things laboratory, and a good experiment platform is provided for future employment and scientific research.

The Internet of things experimental platform is a well-designed Internet of things practical training teaching platform integrating teaching, competition, industrial control and environmental monitoring development, integrates technologies such as WIFI communication, ZIGBEE communication, 433M wireless communication, 2.4G wireless communication, RS-485 communication, RS-232 communication, sensing acquisition and control, comprehensively uses technical characteristics of the Internet of things in the aspects of intelligent sensing, network transmission, intelligent processing and the like, and builds a brand-new concept integrating interesting demonstration (science popularization), scientific experiment (teaching) and application development (scientific research).

The existing experimental platform of the internet of things can only complete the following experiments:

1. and (3) carrying out basic experiments on various sensors.

2. 2.4G wireless transmission experiment

3. 433M wireless transmission experiment

4. ZigBee basic knowledge and networking experiment

5. ZigBee basic control and data acquisition experiment

6. And (5) performing RFID basic experiment.

With the development of society, the functionality of the current experimental platform of the internet of things cannot meet the use requirement.

SUMMERY OF THE UTILITY MODEL

The utility model aims to overcome the not enough of prior art, provide a NBIOT intelligence development experiment platform based on high in the clouds control.

The technical scheme of the utility model as follows:

an NBIOT intelligent development experiment platform based on cloud control comprises a sensor system, a ZIGBEE system, an intelligent voice system, a controller system, a base station, a cloud server and a mobile client, wherein the sensor system, the ZIGBEE system, the intelligent voice system, the controller system, the cloud server and the mobile client are respectively in communication connection with the base station;

the sensor system is responsible for collecting environmental data;

the ZIGBEE system is responsible for establishing a local area network and networking functions of the sensor system, the intelligent voice system and the controller system;

the intelligent voice system is responsible for a man-machine conversation function with the mobile client;

the controller system is responsible for equipment control functions, equipment switch control and equipment states.

In the above scheme, the sensor system is composed of a sensor module, a first ZIGBEE router, a first NBIOT module, and a first MCU controller, and the sensor module, the first NBIOT module, and the first MCU controller are respectively connected to the first ZIGBEE router by signals.

In the above scheme, the sensor module comprises a temperature sensor, a humidity sensor, a carbon dioxide sensor and a formaldehyde sensor.

In the above scheme, the ZIGBEE system is composed of a ZIGBEE coordinator, a second MCU controller, and a second NBIOT module, and the ZIGBEE coordinator and the second NBIOT module are respectively connected to the second MCU controller by signals.

In the above scheme, the intelligent voice system is composed of an intelligent voice module, a third ZIGBEE router, a third NBIOT module, and a third MCU controller, and the intelligent voice module, the third NBIOT module, and the third MCU controller are respectively connected to the third ZIGBEE router by signals.

In the above scheme, the controller system is composed of a controller module, a fourth ZIGBEE router, a fourth NBIOT module, and a fourth MCU controller, and the controller module, the fourth ZIGBEE router, and the fourth MCU controller are respectively connected to the fourth ZIGBEE router by signals.

In the foregoing scheme, optionally, an HTTP communication manner is adopted between the sensor system, the ZIGBEE system, the intelligent voice system, the controller system, the cloud server, the mobile client, and the base station.

In the foregoing scheme, optionally, an MQTT communication mode is adopted between the sensor system, the ZIGBEE system, the intelligent voice system, the controller system, the cloud server, the mobile client, and the base station.

In the foregoing scheme, optionally, a CoAP communication mode is adopted between the sensor system, the ZIGBEE system, the intelligent voice system, the controller system, the cloud server, the mobile client, and the base station.

In the foregoing scheme, optionally, an SoAP communication mode is adopted between the sensor system, the ZIGBEE system, the intelligent voice system, the controller system, the cloud server, the mobile client, and the base station.

Compared with the prior art, the beneficial effects of the utility model reside in that: the utility model realizes the data interaction with the cloud end on the basis of the function of the experimental platform of the Internet of things; data are interacted with the cloud end by using an NBIOT technology; and the cloud processing data is utilized to realize the development function of the intelligent product.

(1) Basic experiments of the internet of things can be performed, for example: ZIGBEE experiment, sensor experiment, controller experiment, RS-485 communication, RS-232 communication and other experiments;

(2) the intelligent voice human-computer interaction experiment of the Internet of things can be performed;

(3) the method can be used for performing connection experiments of the Internet of things and the cloud and interaction experiments with cloud data;

(4) can be used as an experiment combining computer related specialties and embedded related specialties.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings required for the embodiments or the prior art descriptions will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art to obtain other drawings without creative efforts.

Fig. 1 is a block diagram illustrating an NBIOT intelligent development experimental platform based on cloud control;

fig. 2 is a block diagram of the sensor system according to the present invention;

FIG. 3 is a block diagram of the ZIGBEE system of the present invention;

FIG. 4 is a block diagram of the intelligent audio system of the present invention;

fig. 5 is a schematic circuit diagram of the intelligent voice module according to the present invention;

fig. 6 is a block diagram of the controller system according to the present invention;

fig. 7 is a schematic circuit diagram of the controller module according to the present invention;

fig. 8 is a schematic circuit diagram of the first MCU controller, the second MCU controller, the third MCU controller and the fourth MCU controller of the present invention;

fig. 9 is a circuit schematic diagram of the first NBIOT module, the second NBIOT module, the third NBIOT module, and the fourth NBIOT module according to the present invention.

Detailed Description

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

In order to explain the technical solution of the present invention, the following description is made by using specific examples.

Examples

Referring to fig. 1, the present embodiment provides an NBIOT intelligent development experimental platform based on cloud control, including a sensor system 1, a ZIGBEE system 2, an intelligent voice system 3, a controller system 4, a base station 5, a cloud server 6, and a mobile client 7, where the sensor system 1, the ZIGBEE system 2, the intelligent voice system 3, the controller system 4, the cloud server 6, and the mobile client 7 are respectively in communication connection with the base station 5, and the communication mode may be HTTP/MQTT/CoAP/SoAP.

The sensor system 1 is responsible for collecting environmental data, and as shown in fig. 2, the system is composed of a sensor module 11, a first ZIGBEE router 12, a first NBIOT module 13, and a first MCU controller 14, wherein the sensor module 11, the first NBIOT module 13, and the first MCU controller 14 are respectively in signal connection with the first ZIGBEE router 12; the sensor module 11 comprises a temperature sensor, a humidity sensor, a carbon dioxide sensor and a formaldehyde sensor.

The ZIGBEE system 2 is responsible for establishing a local area network and networking functions of the sensor system 1, the intelligent voice system 3, and the controller system 4, and as shown in fig. 3, the ZIGBEE system is composed of a ZIGBEE coordinator 21, a second MCU controller 22, and a second NBIOT module 23, and the ZIGBEE coordinator 21 and the second NBIOT module 23 are respectively connected to the second MCU controller 22 through signals.

The intelligent voice system 3 is responsible for a man-machine conversation function with the mobile client 7, and as shown in fig. 4, the system is composed of an intelligent voice module 31, a third ZIGBEE router 32, a third NBIOT module 33 and a third MCU controller 34, wherein the intelligent voice module 31, the third ZIGBEE router 33 and the third MCU controller 34 are respectively in signal connection with the third ZIGBEE router 32; as shown in fig. 5, it is a schematic circuit diagram of a main control board adopted by the intelligent voice module 31.

The controller system 4 is responsible for controlling the device control function, controlling the device switch and the device state, and as shown in fig. 6, the system is composed of a controller module 41, a fourth ZIGBEE router 42, a fourth NBIOT module 43 and a fourth MCU controller 44, wherein the controller module 41, the fourth ZIGBEE module 43 and the fourth MCU controller 44 are respectively in signal connection with the fourth ZIGBEE router 42; as shown in fig. 7, it is a schematic circuit diagram of a main control board adopted by the controller module 41.

The first MCU controller 14, the second MCU controller 22, the third MCU controller 34 and the fourth MCU controller 44 all adopt the same MCU main control board, and the circuits thereof are as shown in fig. 8.

The first NBIOT module 13, the second NBIOT module 23, the third NBIOT module 33, and the fourth NBIOT module 43 all use the same NBIOT master control board, and the circuit thereof is shown in fig. 9.

The utility model mainly aims to complete the data interaction with the cloud end on the basis of completing the function of the experimental platform of the internet of things; data are interacted with the cloud end by using an NBIOT technology; and the cloud processing data is utilized to realize the development function of the intelligent product.

The above description is only exemplary of the present invention and should not be construed as limiting the present invention, and any modifications, equivalents and improvements made within the spirit and principles of the present invention are intended to be included within the scope of the present invention.

Claims (10)

1. The utility model provides a NBIOT intelligence development experiment platform based on high in clouds control which characterized in that: the system comprises a sensor system, a ZIGBEE system, an intelligent voice system, a controller system, a base station, a cloud server and a mobile client, wherein the sensor system, the ZIGBEE system, the intelligent voice system, the controller system, the cloud server and the mobile client are respectively in communication connection with the base station;

the sensor system is responsible for collecting environmental data;

the ZIGBEE system is responsible for establishing a local area network and networking functions of the sensor system, the intelligent voice system and the controller system;

the intelligent voice system is responsible for a man-machine conversation function with the mobile client;

the controller system is responsible for equipment control functions, equipment switch control and equipment states.

2. The cloud control-based NBIOT intelligent development experimental platform of claim 1, wherein: the sensor system is composed of a sensor module, a first ZIGBEE router, a first NBIOT module and a first MCU controller, wherein the sensor module, the first NBIOT module and the first MCU controller are respectively connected with the first ZIGBEE router through signals.

3. The cloud control-based NBIOT intelligent development experimental platform of claim 2, wherein: the sensor module comprises a temperature sensor, a humidity sensor, a carbon dioxide sensor and a formaldehyde sensor.

4. The cloud control-based NBIOT intelligent development experimental platform of claim 1, wherein: the ZIGBEE system is composed of a ZIGBEE coordinator, a second MCU controller and a second NBIOT module, wherein the ZIGBEE coordinator and the second NBIOT module are respectively connected with the second MCU controller through signals.

5. The cloud control-based NBIOT intelligent development experimental platform of claim 1, wherein: the intelligent voice system is composed of an intelligent voice module, a third ZIGBEE router, a third NBIOT module and a third MCU controller, wherein the intelligent voice module, the third NBIOT module and the third MCU controller are respectively connected with the third ZIGBEE router through signals.

6. The cloud control-based NBIOT intelligent development experimental platform of claim 1, wherein: the controller system is composed of a controller module, a fourth ZIGBEE router, a fourth NBIOT module and a fourth MCU controller, wherein the controller module, the fourth NBIOT module and the fourth MCU controller are respectively connected with the fourth ZIGBEE router through signals.

7. The cloud control-based NBIOT intelligent development experimental platform of claim 1, wherein: and the sensor system, the ZIGBEE system, the intelligent voice system, the controller system, the cloud server, the mobile client and the base station adopt an HTTP communication mode.

8. The cloud control-based NBIOT intelligent development experimental platform of claim 1, wherein: and an MQTT communication mode is adopted among the sensor system, the ZIGBEE system, the intelligent voice system, the controller system, the cloud server, the mobile client and the base station.

9. The cloud control-based NBIOT intelligent development experimental platform of claim 1, wherein: the sensor system, the ZIGBEE system, the intelligent voice system, the controller system, the cloud server, the mobile client and the base station adopt a CoAP communication mode.

10. The cloud control-based NBIOT intelligent development experimental platform of claim 1, wherein: and the sensor system, the ZIGBEE system, the intelligent voice system, the controller system, the cloud server, the mobile client and the base station adopt an SoAP communication mode.

Images