阅读说明：本技术 一种人工智能教学远程无线烧写主板 (Artificial intelligence teaching remote wireless programming mainboard ) 是由 吴坷镁 徐杰 徐军军 吴直场 于 2021-09-17 设计创作，主要内容包括：本发明公开了一种人工智能教学远程无线烧写主板,包括无线烧录器、芯片模拟输入基准电容和烧写主板主体,所述无线烧录器的右上角表面固定连接有芯片引脚接口,所述芯片引脚接口的下方固定连接有无线烧录器使能上拉电阻。该人工智能教学远程无线烧写主板主要有硬件、服务器、编译器、编程平台、插件组成,硬件包括远程烧写器、集成远程烧写功能的avr功能教学板、快速烧写器配置器,远程烧写器主要利用无线网络接受学生编写的程序数据,再通过串口烧写到芯片端,并对芯片内的数据进行验证,-集成远程烧写功能的avr功能教学板可支持远程烧写与可以支持有线烧写,在这块板中还解决了市场上售卖的arduino编程板的问题。(The invention discloses an artificial intelligence teaching remote wireless programming mainboard which comprises a wireless programmer, a chip analog input reference capacitor and a programming mainboard main body, wherein a chip pin interface is fixedly connected to the surface of the upper right corner of the wireless programmer, and a wireless programmer enabling pull-up resistor is fixedly connected below the chip pin interface. The artificial intelligence teaching remote wireless programming mainboard mainly comprises hardware, a server, a compiler, a programming platform and plug-in components, wherein the hardware comprises a remote programming device, an avr function teaching board integrating the remote programming function and a rapid programming device configurator, the remote programming device mainly utilizes a wireless network to receive program data written by students, then programs the chip end through a serial port and verifies the data in the chip, the avr function teaching board integrating the remote programming function can support remote programming and wired programming, and the problem of the arduino programming board sold in the market is solved in the board.)

1. The utility model provides a long-range wireless mainboard of writing with a programme of artificial intelligence teaching, includes wireless burnt ware (1), chip analog input benchmark electric capacity (23) and writes with a programme mainboard main part (43), its characterized in that: a chip pin interface (2) is fixedly connected to the surface of the upper right corner of the wireless recorder (1), a wireless recorder enabling pull-up resistor (3) is fixedly connected to the lower portion of the chip pin interface (2), a wireless recorder filter capacitor (4) is fixedly connected to the left side of the wireless recorder enabling pull-up resistor (3), a burn-in indicator lamp I (5) is fixedly connected to the left side position of the wireless recorder filter capacitor (4), a chip external crystal oscillator (6) is fixedly connected to the lower left corner position of the burn-in indicator lamp I (5), a crystal oscillator peripheral capacitor (7) is fixedly connected to the outer side portion above the chip external crystal oscillator (6), a main control chip (8) is fixedly connected to the lower left side of the chip external crystal oscillator (6), and a power indicator lamp (9) is fixedly connected to the upper right corner portion of the chip external crystal oscillator (6), the power supply indicator lamp comprises a power indicator lamp (9), a 5-volt voltage stabilizer (10) is fixedly connected to the lower portion of the power indicator lamp (9), a 5-volt voltage output (11) is fixedly connected to the left side of the 5-volt voltage output (11), a 3.3-volt voltage stabilizer (12) is fixedly connected to the left side of the 5-volt voltage stabilizer (10), a USB signal resistor (13) is fixedly connected to the position vertically below the 3.3-volt voltage stabilizer (12), a chip reset key (14) is fixedly connected to the right side of the USB signal resistor (13), a programming and expansion pin (16) is fixedly connected to the left side end face of the wireless burner (1), a chip reset pin pull-up resistor (15) is connected to the right side horizontal position of the chip reset key (14), an integrated interface (17) is fixedly connected to the right side end face of the chip reset pin pull-up resistor (15), and a second indicator lamp (18) is burnt in by fixedly connected to the upper right corner position of the integrated interface (17), a wireless burner pull-down resistor (19) is fixedly connected to the right side of the second burning indicator lamp (18), a wireless burner reset chip switch (20) is fixedly connected to the bottom end of the wireless burner pull-down resistor (19), a chip pin interface A0-A7 (21) is fixedly connected to the right side of the integrated interface (17), a 5V and 3.3V power interface (22) is fixedly connected to the position right above the chip pin interface A0-A7 (21), a first power supply filter (24) is fixedly connected to the position right above the chip analog input reference capacitor (23), a power indicator lamp current-limiting resistor (25) is fixedly connected to the upper position of the first power supply filter (24), a second power supply filter (26) is fixedly connected to the left side of the first power supply filter (24), and a serial port chip reset capacitor (27) is fixedly connected to the left side of the second power supply filter (26), serial port chip resets left side below position fixedly connected with serial ports signal resistance (28) of electric capacity (27), the left side fixedly connected with serial ports signal resistance two (29) of serial ports signal resistance (28), the upper left side fixedly connected with of serial ports signal resistance two (29) burns in pilot lamp current-limiting resistance one (30), the left side position of burning in pilot lamp current-limiting resistance one (30) is from the right side to left side fixedly connected with wireless programming line programming conversion circuit one (31), burns in pilot lamp current-limiting resistance two (32) and burns in pilot lamp current-limiting resistance three (33), burn in pilot lamp current-limiting resistance four (34) under fixedly connected with programming line programming conversion circuit under pilot lamp current-limiting resistance two (32), burn in pilot lamp current-limiting resistance five (35) of fixedly connected with programming under pilot lamp current-limiting resistance four (34), burn in the left side below fixedly connected with of pilot lamp current-limiting resistance five (35) and burn in line programming conversion Circuit two (36), the right side below position fixedly connected with crystal oscillator peripheral capacitance one (37) of serial ports signal resistance one (28), the outside crystal oscillator of right side fixedly connected with serial ports chip (38) of crystal oscillator peripheral capacitance one (37), the outside crystal oscillator of right side fixedly connected with crystal oscillator peripheral capacitance two (39) of serial ports chip (38), fixedly connected with serial ports chip (40) directly over serial ports chip outside crystal oscillator (38), the outside filter capacitance of right side fixedly connected with serial ports chip (41) of serial ports chip (40), pilot lamp current-limiting resistance six (42) are burnt in to the left side fixedly connected with of serial ports signal resistance two (29).

2. The artificial intelligence teaching remote wireless programming mainboard of claim 1, characterized in that: the chip pin interface (2) is designed equidistantly and is vertically symmetrical to the chip pin interface A0-A7 (21), the programming main board body (43) is designed in a fan-blade shape, and the periphery of the programming main board body (43) is designed to be provided with openings.

3. The artificial intelligence teaching remote wireless programming mainboard of claim 1, characterized in that: the first burning indicator lamp (5) and the second burning indicator lamp (18) are designed to be symmetrical up and down, and the first burning indicator lamp current-limiting resistor (30) and the sixth burning indicator lamp current-limiting resistor (42) are respectively in one-to-one correspondence with the first burning indicator lamp (5) and the second burning indicator lamp (18) in position.

4. The artificial intelligence teaching remote wireless programming mainboard of claim 1, characterized in that: the upper side and the lower side of the main control chip (8) are respectively connected with external channels such as the wireless burner (1), and the external channels are designed to be concave with different lengths and at equal intervals.

5. The artificial intelligence teaching remote wireless programming mainboard of claim 1, characterized in that: the 5 volt voltage stabilizer (10) is electrically connected with the power indicator lamp (9), the integrated interface (17) is designed equidistantly, and the inside of the integrated interface (17) is electrically connected with the programming and extension pins (16).

6. The artificial intelligence teaching remote wireless programming mainboard of claim 1, characterized in that: the first power filter (24) and the second power filter (26) are connected to the respective accessories at positions via external channels.

7. The artificial intelligence teaching remote wireless programming mainboard of claim 1, characterized in that: the serial port signal resistor I (28) and the serial port signal resistor II (29) are connected in parallel, and the burn-in indicator light current-limiting resistor I (30), the burn-in indicator light current-limiting resistor II (32), the burn-in indicator light current-limiting resistor III (33), the burn-in indicator light current-limiting resistor IV (34) and the burn-in indicator light current-limiting resistor V (35) are connected in series.

8. The artificial intelligence teaching remote wireless programming mainboard of claim 1, characterized in that: the first crystal oscillator peripheral capacitor (37) and the second crystal oscillator peripheral capacitor (39) are designed to be symmetrical left and right, and the serial port chip external crystal oscillator (38) is electrically connected with the first crystal oscillator peripheral capacitor (37) and the second crystal oscillator peripheral capacitor (39).

Technical Field

The invention relates to the technical field of internet and single-chip microcomputer, in particular to an artificial intelligence teaching remote wireless programming mainboard.

Background

The single chip computer is an integrated circuit chip, which is a small and perfect microcomputer system formed by integrating the functions of a central processing unit CPU with data processing capacity, a random access memory RAM, a read only memory ROM, various I/O ports, an interrupt system, a timer/counter and the like (possibly comprising a display driving circuit, a pulse width modulation circuit, an analog multiplexer, an A/D converter and other circuits) on a silicon chip by adopting a super-large scale integrated circuit technology, and is widely applied to the field of industrial control. From the 80 s of the last century, the current high-speed single chip microcomputer of 300M is developed by 4-bit and 8-bit single chip microcomputers.

However, in the teaching of hardware programming, an AVR chip, and arduino, mixly, and linkboy at a software end are generally used, and these software are all code editors adopted in current artificial intelligence teaching products, but these editors only support wired programming and 2.4g and other programming methods with distance limitation, and if a student designs a cart, the student encounters a problem during testing, and needs the help of a teacher at this time, but the teacher is out of school, and the student sends a code to the teacher for viewing, and the teacher also needs to program the cart and view information output by a hardware serial port during debugging. Because these reasons can't solve the problem for the student in time, cause in the teaching process, the teacher and student's teaching can't break through the restriction in space, has reduced the teaching quality.

Disclosure of Invention

The invention aims to provide an artificial intelligence teaching remote wireless programming mainboard, which aims to solve the problems that distance and line are bound, field debugging is not facilitated, and particularly project debugging at a moving position is required, so that teachers and students cannot break through the limitation of space in the teaching process, and the teaching quality is reduced.

In order to achieve the purpose, the invention provides the following technical scheme: a remote wireless programming mainboard for artificial intelligence teaching comprises a wireless programmer, a chip analog input reference capacitor and a programming mainboard main body, wherein a chip pin interface is fixedly connected to the surface of the upper right corner of the wireless programmer, a wireless programmer is fixedly connected to the lower side of the chip pin interface to enable a pull-up resistor, a wireless programmer filter capacitor is fixedly connected to the left side of the pull-up resistor, a first programming indicator lamp is fixedly connected to the left side of the wireless programmer filter capacitor, a chip external crystal oscillator is fixedly connected to the lower left corner of the first programming indicator lamp, a crystal oscillator peripheral capacitor is fixedly connected to the upper outer side of the chip external crystal oscillator, a master control chip is fixedly connected to the lower left side of the chip external crystal oscillator, a power indicator lamp is fixedly connected to the upper right corner of the chip external crystal oscillator, and a 5V voltage stabilizer is fixedly connected to the lower side of the power indicator lamp, the left side of the 5V voltage stabilizer is fixedly connected with a 5V voltage output, the lower part of the left side of the 5V voltage output is fixedly connected with a 3.3V voltage stabilizer, the position of the vertical lower part of the 3.3V voltage stabilizer is fixedly connected with a USB signal resistor, the lower part of the right side of the USB signal resistor is fixedly connected with a chip reset key, the left end surface of the wireless burner is fixedly connected with a programming and expanding pin, the horizontal position of the right side of the chip reset key is connected with a chip reset pin pull-up resistor, the right end surface of the chip reset pin pull-up resistor is fixedly connected with an integrated interface, the upper right corner position of the integrated interface is fixedly connected with a second burner indicator lamp, the right side direction of the second burner indicator lamp is fixedly connected with a wireless burner pull-down resistor, and the bottom end of the wireless burner pull-down resistor is fixedly connected with a wireless burner reset chip switch, the right side fixedly connected with chip pin interface A0-A7 of integrative interface, locate fixedly connected with 5V, 3.3v power source directly over chip pin interface A0-A7, the first power filter of fixedly connected with directly over chip analog input benchmark electric capacity, the top position fixedly connected with power indicator current-limiting resistor of first power filter, the left side fixedly connected with second power filter of first power filter, the left side fixedly connected with serial chips reset electric capacity of second power filter, the left side position fixedly connected with serial signals resistance one under serial chips reset electric capacity, the left side fixedly connected with serial signals resistance two of serial signals resistance one, the upper left side fixedly connected with of serial signals resistance two burns into indicator current-limiting resistor one, the left side position of burning indicator current-limiting resistor one is from right side to left side fixedly connected with in proper order that the line burns and writes that line burns and writes conversion circuit one, A second burned-in indicator light current-limiting resistor and a third burned-in indicator light current-limiting resistor, wherein a fourth burned-in indicator light current-limiting resistor is fixedly connected under the second burned-in indicator light current-limiting resistor, a fifth current-limiting resistor of the burn-in indicator lamp is fixedly connected under the fourth current-limiting resistor of the burn-in indicator lamp, a second wireless programming wired programming conversion circuit is fixedly connected to the lower portion of the left side of the fifth programming indicator light current-limiting resistor, a first crystal oscillator peripheral capacitor is fixedly connected at the right lower position of the first serial port signal resistor, a serial port chip external crystal oscillator is fixedly connected at the right side of the first crystal oscillator peripheral capacitor, the right side of the crystal oscillator outside the serial port chip is fixedly connected with a second crystal oscillator peripheral capacitor, a serial port chip is fixedly connected right above the crystal oscillator outside the serial port chip, the right side of the serial port chip is fixedly connected with a peripheral filter capacitor of the serial port chip, and the left side of the serial port signal resistor II is fixedly connected with a burning-in indicator lamp current-limiting resistor six.

Preferably, the chip pin interfaces are designed equidistantly and are symmetrical to the chip pin interfaces A0-A7 in position, the programming main board body is in a fan-blade-shaped design, and the periphery of the programming main board body is in an open design.

Preferably, the first burning indicator lamp and the second burning indicator lamp are designed to be symmetrical up and down, and the first burning indicator lamp current-limiting resistor and the sixth burning indicator lamp current-limiting resistor correspond to the first burning indicator lamp and the second burning indicator lamp one to one in position respectively.

Preferably, the upper side and the lower side of the main control chip are respectively connected with external channels such as a wireless burner, and the external channels are designed to be concave with different lengths and at equal intervals.

Preferably, the 5 volt voltage stabilizer is electrically connected with the power indicator lamp, the integrated interface is designed at equal distance, and the inside of the integrated interface is electrically connected with the programming and extension pins.

Preferably, the first power filter and the second power filter are connected to each accessory through an external channel.

Preferably, the serial port signal resistor I and the serial port signal resistor II are connected in parallel, and the burn-in indicator light current-limiting resistor I, the burn-in indicator light current-limiting resistor II, the burn-in indicator light current-limiting resistor III, the burn-in indicator light current-limiting resistor IV and the burn-in indicator light current-limiting resistor V are connected in series.

Preferably, the first crystal oscillator peripheral capacitor and the second crystal oscillator peripheral capacitor are designed to be symmetrical left and right, and the external crystal oscillator of the serial port chip is electrically connected with the first crystal oscillator peripheral capacitor and the second crystal oscillator peripheral capacitor.

Compared with the prior art, the invention has the beneficial effects that: the artificial intelligence teaching remote wireless programming mainboard mainly comprises hardware, a server, a compiler, a programming platform and a plug-in, wherein the hardware comprises a remote programming device, an avr function teaching board integrating the remote programming function and a rapid programming device configurator. The remote programming device mainly utilizes a wireless network to receive program data written by students, then programs the program data to the chip end through a serial port, and verifies the data in the chip. The avr function teaching board of integrated long-range write function of burning can support long-range write with can support the line to burn and write, has still solved the problem of the arduino programming board of selling on the market in this board, can't burn the problem of writing when having the wiring on the serial ports, and the existence of long-range write simultaneously can not influence the chip use originally. The rapid programming device configurator is mainly used for configuring networks and the like of remote wireless programming devices in batches and is suitable for teaching of school batch artificial intelligent teaching products.

Drawings

FIG. 1 is a schematic front view of the present invention;

FIG. 2 is a schematic view of the backside structure of the present invention;

FIG. 3 is a schematic diagram of a USB programming circuit according to the present invention;

FIG. 4 is a schematic circuit diagram of the power control section of the present invention;

FIG. 5 is a schematic drawing of a pin header according to the present invention;

FIG. 6 is a circuit diagram of a main control chip according to the present invention;

FIG. 7 is a schematic diagram of the power supply and signal indicator circuit of the present invention;

FIG. 8 is a schematic diagram of the connection between the wireless programming and serial port switching circuit according to the present invention.

In the figure: 1. a wireless burner; 2. a chip pin interface; 3. the wireless burner enables a pull-up resistor; 4. a filter capacitor of the wireless burner; 5. burning a first indicator lamp; 6. a chip external crystal oscillator; 7. a crystal oscillator peripheral capacitor; 8. a main control chip; 9. a power indicator light; 10. a 5 volt regulator; 11. 5V voltage output; 12. a 3.3 volt regulator; 13. a USB signal resistor; 14. a chip reset key; 15. a chip reset pin pulls up a resistor; 16. programming and extending pins; 17. an integral interface; 18. burning a second indicator light; 19. a pull-down resistor of the wireless burner; 20. a wireless burner reset chip switch; 21. chip pin interface A0-A7; 22. a 5 volt, 3.3v power interface; 23. the chip simulates an input reference capacitor; 24. filtering a first power supply; 25. a current limiting resistor of the power indicator; 26. filtering a second power supply; 27. a serial port chip reset capacitor; 28. a serial port signal resistor I; 29. a serial port signal resistor II; 30. burning a first current limiting resistor of an indicator light; 31. a first wireless programming and wired programming conversion circuit; 32. burning a second current-limiting resistor of the indicator light; 33. burning a third current limiting resistor of an indicator light; 34. burning an indicator light current limiting resistor IV; 35. burning an indicator light current limiting resistor V; 36. a second wireless programming and wired programming conversion circuit; 37. a first crystal oscillator peripheral capacitor; 38. a serial port chip external crystal oscillator; 39. a second crystal oscillator peripheral capacitor; 40. a serial port chip; 41. a serial port chip peripheral filter capacitor; 42. burning an indicator light current limiting resistor six; 43. and programming the main board body.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1-8, the present invention provides a technical solution: a remote wireless programming mainboard for artificial intelligence teaching comprises a wireless programmer 1, a chip analog input reference capacitor 23 and a programming mainboard main body 43, wherein a chip pin interface 2 is fixedly connected to the upper right corner surface of the wireless programmer 1, a wireless programmer enabling pull-up resistor 3 is fixedly connected to the lower side of the chip pin interface 2, a wireless programmer filter capacitor 4 is fixedly connected to the left side of the wireless programmer enabling pull-up resistor 3, a programming indicator lamp I5 is fixedly connected to the left side of the wireless programmer filter capacitor 4, a chip external crystal oscillator 6 is fixedly connected to the lower left corner of the programming indicator lamp I5, a crystal oscillator peripheral capacitor 7 is fixedly connected to the upper outer side of the chip external crystal oscillator 6, a main control chip 8 is fixedly connected to the lower left side of the chip external crystal oscillator 6, and a power indicator lamp 9 is fixedly connected to the upper right corner of the chip external crystal oscillator 6, a 5V voltage stabilizer 10 is fixedly connected below the power indicator lamp 9, a 5V voltage output 11 is fixedly connected on the left side of the 5V voltage stabilizer 10, a 3.3V voltage stabilizer 12 is fixedly connected on the left side lower side of the 5V voltage output 11, a USB signal resistor 13 is fixedly connected on the position vertically below the 3.3V voltage stabilizer 12, a chip reset key 14 is fixedly connected on the right side lower side of the USB signal resistor 13, a programming and expansion pin 16 is fixedly connected on the left side end surface of the wireless burner 1, a chip reset pin pull-up resistor 15 is connected on the right side horizontal position of the chip reset key 14, an integrated interface 17 is fixedly connected on the right side end surface of the chip reset pin pull-up resistor 15, a burning indicator lamp II 18 is fixedly connected on the right upper corner position of the integrated interface 17, a wireless burner pull-down resistor 19 is fixedly connected on the right side direction of the burning indicator lamp II 18, and a wireless burner reset chip switch 20 is fixedly connected on the bottom end of the wireless burner pull-down resistor 19, a chip pin interface A0-A721 is fixedly connected to the right side of the integrated interface 17, a 5V power interface 22 is fixedly connected to the position right above the chip pin interface A0-A721, a first power filter 24 is fixedly connected to the position right above the chip analog input reference capacitor 23, a power indicator light current-limiting resistor 25 is fixedly connected to the position right above the first power filter 24, a second power filter 26 is fixedly connected to the left side of the first power filter 24, a serial chip reset capacitor 27 is fixedly connected to the left side of the second power filter 26, a serial signal resistor I28 is fixedly connected to the position below the left side of the serial chip reset capacitor 27, a serial signal resistor II 29 is fixedly connected to the left side of the serial signal resistor I28, a burn-in indicator light current-limiting resistor I30 is fixedly connected to the upper left side of the serial signal resistor II 29, and a wireless burn-in wire-in-line-burn-in-line conversion circuit I31, a burn-in-line conversion circuit I31 is fixedly connected to the left side in sequence from the position of the burn-in-line signal resistor II 29, The device comprises a second burning-in indicator light current-limiting resistor 32 and a third burning-in indicator light current-limiting resistor 33, a fourth burning-in indicator light current-limiting resistor 34 is fixedly connected under the second burning-in indicator light current-limiting resistor 32, a fifth burning-in indicator light current-limiting resistor 35 is fixedly connected under the fourth burning-in indicator light current-limiting resistor 34, a second wireless burning-in wire burning-in conversion circuit 36 is fixedly connected under the left side of the fifth burning-in indicator light current-limiting resistor 35, a first crystal oscillator peripheral capacitor 37 is fixedly connected at the right lower position of a first serial port signal resistor 28, a first serial port chip external crystal oscillator 38 is fixedly connected on the right side of the first crystal oscillator peripheral capacitor 37, a second crystal oscillator peripheral capacitor 39 is fixedly connected on the right side of the second serial port chip external crystal oscillator 38, a serial port chip 40 is fixedly connected over the serial port chip external crystal oscillator 38, a peripheral filter capacitor 41 of the serial port chip 40 is fixedly connected on the right side of the serial port chip 40, and a sixth burning-in indicator light current-limiting resistor 42 is fixedly connected on the left side of the second serial port signal resistor 29.

Further, the chip pin interface 2 is designed to be equidistant, and is vertically symmetrical to the chip pin interface a0-a721 at the position, the programming main board body 43 is designed to be fan-blade-shaped, and the periphery of the programming main board body 43 is designed to be open.

Furthermore, the first burn-in indicator lamp 5 and the second burn-in indicator lamp 18 are designed to be symmetrical to each other up and down, and the first burn-in indicator lamp current-limiting resistor 30 and the sixth burn-in indicator lamp current-limiting resistor 42 are in one-to-one correspondence with the first burn-in indicator lamp 5 and the second burn-in indicator lamp 18 in position.

Further, the upper side and the lower side of the main control chip 8 are respectively connected with external channels such as the wireless burner 1, and the external channels are designed to be concave with different lengths and at equal intervals.

Further, the 5 v regulator 10 is electrically connected to the power indicator 9, the integrated interface 17 is designed to be equidistant, and the internal portion is electrically connected to the programming and extension pin 16.

Further, the first power filter 24 and the second power filter 26 are connected to each accessory at positions through external channels.

Further, the serial port signal resistor I28 and the serial port signal resistor II 29 are connected in parallel, and the first burn-in indicator light current-limiting resistor I30, the second burn-in indicator light current-limiting resistor II 32, the third burn-in indicator light current-limiting resistor III 33, the fourth burn-in indicator light current-limiting resistor 34 and the fifth burn-in indicator light current-limiting resistor 35 are connected in series.

Further, the first crystal oscillator peripheral capacitor 37 and the second crystal oscillator peripheral capacitor 39 are designed to be symmetrical with each other left and right, and the serial chip external crystal oscillator 38 is electrically connected with the first crystal oscillator peripheral capacitor 37 and the second crystal oscillator peripheral capacitor 39.

The working principle is as follows: the server program is compiled by a Go language, when a user compiles a program on a programming platform and uploads the program, the client calls a websocket to establish long connection, the request passes through a gateway and is served to a specific service node in a cluster in a load balancing manner, the node receives the upload request and first initiates a program compiling request to a compiling cluster service, the compiling service is constructed by a Docker and is managed through Kubernetes, binary program content in a HEX form is returned after the construction is completed, meanwhile, the programming platform program is returned after the construction is completed, program data is sent to a programming service node corresponding to the equipment ID through the ID of a remote wireless programming mainboard carried by the request, the programming service node initiates a programming request to the equipment, the program programming task is completed by sub-packaging, the program verification is completed, and the programming platform is returned to prompt the user that the uploading is successful. The wireless transmission equipment with the hardware comprising the esp8266 as the core mainly receives and uploads instructions or data blocks through an external network, decodes the data and writes the data into corresponding flash blocks through serial ports, and a program of the wireless transmission equipment is written in c + + language. Firstly, hardware provides a device ID, the network configuration is carried out through an AP web, the configuration information is stored in a chip, and after the chip is connected with the network, the chip is connected with a server through TCP and keeps communication. And monitoring a command issued by the server at any moment, resetting and accessing the slave equipment by the equipment when the server issues the programming command, performing block writing and verification flash on the slave equipment, sending information to the server to write in state after the writing is completed, and disconnecting the slave equipment.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.