CN116366472A - Front-end control and server forwarding method for reducing server forwarding pressure - Google Patents

Abstract

The invention relates to the field of equipment communication, in particular to a front-end control and server forwarding method for reducing server forwarding pressure, which comprises the steps that equipment and a server are both in communication connection with the front end; detecting whether communication between the device and the device is smooth or not in real time; if yes, a first control instruction is sent to the equipment and the server; acquiring and displaying the working state of the equipment; otherwise, notifying the server to connect with the device; detecting whether communication between the server and the device is smooth in real time; if yes, a second control instruction is sent to the server; confirming and displaying the working state of the equipment according to the equipment state information fed back by the server in real time; otherwise, the display device is offline. The invention directly communicates with the equipment through the front end, saves the time of communication with the server and retransmission, and ensures that the data transmission is faster; the data forwarding pressure of the server is reduced, and the hardware and network bandwidth requirements of the server are greatly saved when the number of front ends and devices is large.

Description

Front-end control and server forwarding method for reducing server forwarding pressure

Technical Field

The invention relates to the field of equipment communication, in particular to a front-end control and server forwarding method for reducing server forwarding pressure.

Background

With the development of modern network communication technology, the application of the web is more and more extensive, and the web is also applied to the communication and control of equipment. However, with the expansion of services and the progress of technologies such as the internet of things, devices to be managed and controlled by a server also grow exponentially with the increase of usage scenarios.

The conventional device control mode is that when the server and the device network are unblocked, the front end of a web page or other user interfaces is set or operated by a user, then the server sends an instruction to the device, the device receives the instruction and then executes a related task, when the server and the device network are unblocked, the user stores the task instruction in the server after operating, waits for the device to be on line, then sends a command to the device by the server, and the operation is continued. However, the method can greatly increase the forwarding pressure of the server, and if the server is down, the user cannot control the equipment any more.

Disclosure of Invention

In order to overcome the problems, the invention provides a front-end control and server forwarding method for reducing server forwarding pressure.

The invention provides a front-end control method for reducing the forwarding pressure of a server, which comprises the following steps:

the equipment and the server are both in communication connection with the front end;

detecting whether communication with the device is unobstructed in real time;

if yes, sending a first control instruction to the equipment, and copying the first control instruction to the server for archiving;

acquiring and displaying the working state of the equipment according to the equipment state information fed back by the equipment in real time, and forwarding the equipment state information to the server for archiving;

otherwise, notifying the server to connect the equipment;

detecting whether communication between the server and the device is smooth in real time;

if yes, a second control instruction is sent to the server; the second control instruction is used for informing the server to enter a forwarding mode, archiving the second control instruction, forwarding the second control instruction to the equipment at the same time, and forwarding and storing equipment state information fed back by the equipment in real time;

confirming and displaying the working state of the equipment according to the equipment state information fed back by the server in real time;

otherwise, the device is displayed as offline.

Preferably, the device and the server are both in communication connection with the front end, specifically:

after the equipment is online, reporting the equipment state information to a server for storage;

the front end sends a communication request to the server, and the heartbeat connection between the server and the front end is established;

the front end requests the server and obtains the equipment state information;

and the front end establishes heartbeat connection with the equipment according to the equipment state information.

Preferably, the real-time detection is used for detecting whether communication with the device is smooth, specifically:

establishing heartbeat connection between a front end and equipment, and acquiring a first communication delay between the front end and the equipment in real time according to the heartbeat connection;

detecting whether the first communication delay is smaller than a first preset threshold value;

if so, judging that the communication between the front end and the equipment is unobstructed;

otherwise, judging that the communication between the front end and the equipment is not smooth.

Preferably, the method further comprises the steps of:

comparing a first communication delay between the front end and the device with a second communication delay between the front end and the device forwarded by the server;

when the first communication delay is larger than the second communication delay, the front end sends a second control instruction to the server; the front end confirms and displays the working state of the equipment according to the equipment state information fed back by the server in real time;

otherwise, the front end sends a first control instruction to the equipment, and the front end copies the first control instruction to the server for archiving;

the front end acquires and displays the working state of the equipment according to the equipment state information fed back by the equipment in real time, and forwards the equipment state information to the server for archiving.

Preferably, the method further comprises the steps of:

and when the front end is not in smooth communication with the server, the front end displays that the server is offline.

The invention also provides a server forwarding method for reducing the server forwarding pressure, which comprises the following steps:

the server is in communication connection with the front end;

when the communication between the front end and the equipment is smooth, the server stores the equipment control instruction and the equipment state information which are sent by the front end;

when the communication between the front end and the equipment is not smooth, the server is in communication connection with the equipment;

detecting whether the communication between the server and the equipment is smooth or not in real time;

if yes, the server forwards the equipment control instruction of the front end to the equipment in real time, the server acquires the equipment state information of the equipment in real time and forwards the equipment state information to the front end, and the server files the equipment control instruction and the equipment state information;

otherwise, the feedback device feeds back the offline information to the front end.

Preferably, the server is communicatively connected to the front end, specifically:

the server receives the communication request of the front end, establishes heartbeat connection between the server and the front end, and acquires third communication delay between the server and the front end in real time;

detecting whether the third communication delay is smaller than a second preset threshold;

if so, the server and the front-end communication link are successfully established;

otherwise, the front end displays that the server is offline.

Preferably, the real-time detection is used for detecting whether the communication between the server and the device is smooth, specifically:

establishing heartbeat connection between the server and the equipment, and acquiring fourth communication delay between the server and the equipment in real time;

detecting whether the fourth communication delay is smaller than a third preset threshold;

if so, judging that the communication between the server and the equipment is smooth;

otherwise, judging that the communication between the server and the equipment is not smooth.

The beneficial effects of the invention are as follows:

(1) Compared with the traditional forwarding through a server, the scheme has the advantages that the front end is directly communicated with the equipment, so that the time for communicating with the server and forwarding is saved, and the data transmission is faster;

(2) The data forwarding pressure of the server is reduced, and when the number of the front end and the devices is large, the hardware and network bandwidth requirements of the server are greatly saved;

(3) The equipment is directly controlled through the front end, and the server is used for forwarding communication as a backup scheme, so that a user can still control the equipment through the front end under the condition that the front end or the server is not smooth in communication with the equipment or the server is down, and the stability and the adaptability of the whole system are improved.

Drawings

The invention will be further described with reference to the accompanying drawings, in which:

FIG. 1 is a flow chart of a method according to one embodiment of the present invention;

FIG. 2 is a schematic diagram of data transmission when the device according to one embodiment of the present invention is in communication with a front end;

FIG. 3 is a schematic diagram illustrating data transmission when communication between a device and a front end is not smooth according to one embodiment of the present invention;

fig. 4 is a schematic diagram of data transmission when the device is offline according to one embodiment of the present invention.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

Referring to fig. 1 to 4, as one implementation of the present invention, in a complete remote device control system, a front end for providing a control interface or an operation terminal for a user, a server for system management and data recording, and a device for performing related operations are indispensable.

In order to reduce the forwarding pressure of a server in the traditional equipment control process, the embodiment discloses a front-end control method for reducing the forwarding pressure of the server, which comprises the following steps:

s1, equipment and a server are all in communication connection with the front end;

s2, detecting whether communication between the device and the device is smooth in real time;

s31, if yes (shown in fig. 2), sending a first control instruction to the equipment, and simultaneously, the front end transcribes the first control instruction to the server for archiving;

s4, acquiring and displaying the working state of the equipment according to the equipment state information fed back by the equipment in real time, and forwarding the equipment state information to a server for archiving;

s32, otherwise (as shown in figure 3), the front end informs the server of the connection device;

s5, the front end detects whether communication between the server and the equipment is smooth in real time;

s61, if so, the front end sends a second control instruction to the server; the second control instruction is used for informing the server to enter a forwarding mode, archiving the second control instruction, forwarding the second control instruction to the equipment at the same time, and forwarding and storing equipment state information fed back by the equipment in real time;

s7, confirming and displaying the working state of the equipment according to the equipment state information fed back by the server in real time;

s62, otherwise (as shown in fig. 4), the display device is offline.

According to the embodiment, the front end and the equipment are directly connected and controlled, so that the time for communication with the server and retransmission is saved, and data transmission is faster; meanwhile, the data forwarding pressure of the server is reduced, and when the number of front ends and devices is large, the hardware and network bandwidth requirements of the server are greatly saved. The equipment is directly controlled through the front end, and the server is used for forwarding communication as a backup scheme, so that when the front end is not smooth in communication with the equipment, a user can still control the equipment through the forwarding of the front end and the server; also, when the communication between the server and the equipment is not smooth, or when the server is down, any direct control equipment at the front end works; thus improving the stability and adaptability of the whole system.

As a common means in the art, in the whole process of executing steps S2 to S7, when the front end of the present embodiment does not communicate with the device smoothly, the communication connection during the recovery is tried in real time, that is, steps S1 and S2 are repeated until the connection is recovered, and the flow of steps S1 to S4 is re-executed, which should not be understood as that the connection is not reconnected once communication is not smooth.

Preferably, step S1 of the present embodiment specifically includes the following sub-steps:

s11, reporting the equipment state information to a server for storage after equipment is online; the equipment state information comprises the communication address (such as ip address, mac address and the like) of the equipment and the current working state of the equipment;

s12, the front end sends a communication request to the server, and heartbeat connection between the server and the front end is established;

s13, the front end requests the server and obtains equipment state information;

s14, the front end establishes heartbeat connection with the equipment according to the equipment state information.

As a specific illustration example of the scheme, firstly, equipment is on line, equipment state information is reported to a server, the server stores the equipment state information, and the equipment is identified to be on line and can be called; when a user operates the front end to enter the equipment control page, the front end requests the server to acquire equipment state information, and then, direct connection is established with equipment according to the information; when the user operates the device through the front end, the front end directly sends the operation command to the device according to the device state information, and after the device finishes the operation command, the device state information is returned to the front end. Thus, the user can quickly know the state and information of the device.

The fact that the equipment state information is stored in the server is convenient for the dispatching management of the whole system, the front end can conveniently search corresponding equipment in the server directly without searching equipment on the whole network, and of course, in order to prevent the situation that the front end cannot establish connection with the equipment when the server is disconnected or down, the front end of the embodiment is also provided with a register for storing the equipment state information and used for storing the commonly used or connected equipment state information; or there is a method of directly inquiring the device and establishing a connection through a network (internet or local area network, etc.) without passing through a server; to ensure that the relevant device can be controlled even if the connection is not to the server.

When the communication between the front end and the server is not smooth, the front end display device is offline, at this time, the front end or the server can archive the control instruction which is not executed to be resent after the connection is recovered, or does not perform any operation, and abandons the subsequent control instruction until the connection is recovered.

The communication connection of the embodiment has no difference between the adopted communication protocol and the data format and the conventional scheme, the adopted communication protocol can be an http protocol, a tcp protocol or a udp protocol, and the data format can be json, binary codes and the like, which depend on the agreements of the two communication parties and the application environment, so that targeted development and deployment are carried out.

Preferably, step S2 of the present embodiment specifically includes:

s21, establishing heartbeat connection between the front end and the equipment, and accordingly acquiring a first communication delay between the front end and the equipment in real time;

s22, detecting whether the first communication delay is smaller than a first preset threshold value;

s231, if yes, judging that the communication between the front end and the equipment is smooth;

and S232, if not, judging that the communication between the front end and the equipment is not smooth.

The first preset threshold in this embodiment is preset to 100ms, and may be adjusted according to the actual network situation or the response speed requirement of the front end.

Preferably, the front-end control method for reducing forwarding pressure of a server in this embodiment further includes the following steps:

s8, comparing the first communication delay between the front end and the equipment with the second communication delay between the front end and the equipment forwarded through the server;

s91, when the first communication delay is larger than the second communication delay, executing step S61 and step S7;

and S92, otherwise, executing the step S31 and the step S4.

The method is used for comparing which connection mode is used for controlling the direct control and the server forwarding of the scheme, when the communication delay of the direct connection between the front end and the equipment is larger than that of the control by forwarding of the server, the equipment can be controlled to work by forwarding of the server, of course, the scheme is limited to be allowed to be executed when the forwarding pressure of the server is smaller, when the forwarding pressure of the server is large, the initial scheme of the embodiment is adopted, and as long as the front end and the equipment can normally communicate, the server only receives the first control instruction and the equipment state information for archiving, does not forward any information and reduces the forwarding pressure of the server.

Preferably, the front-end control method for reducing forwarding pressure of a server in this embodiment further includes the following steps:

s10, when the communication between the front end and the server is not smooth, the front end displays that the server is offline.

The situations that the communication between the front end and the server is not smooth include disconnection of the front end and the server network, too high delay between the front end and the server, or no network response caused by downtime of the server.

As another embodiment of the present solution, a server forwarding method for reducing server forwarding pressure is disclosed, including the steps of:

a1, the server is in communication connection with the front end;

a21, when the communication between the front end and the equipment is smooth, the server stores the equipment control instruction and the equipment state information which are sent by the front end;

a22, when the communication between the front end and the equipment is not smooth, the server is in communication connection with the equipment;

a3, detecting whether the communication between the server and the equipment is smooth in real time;

a41, if so, the server forwards the device control instruction of the front end to the device in real time, the server acquires the device state information of the device in real time and forwards the device state information to the front end, and the server files the device control instruction and the device state information;

and A42, otherwise, feeding back the offline information to the front end by the equipment.

Thus, the server of this embodiment only needs to forward the control instruction when the front end is not in communication with the device (see fig. 3),

preferably, the step A1 specifically includes the following steps:

a11, the server receives the communication request of the front end, the heartbeat connection between the server and the front end is established, and the third communication delay between the server and the front end is obtained in real time;

a12, detecting whether the third communication delay is smaller than a second preset threshold value;

a131, if so, the server and the front end communication link are successfully established;

and A132, if not, the front-end display server is offline.

The second preset threshold in this embodiment is preset to 100ms, and may be adjusted according to the actual network situation or the response speed requirement of the front end.

Preferably, the step A3 specifically includes:

a31, establishing heartbeat connection between the server and the equipment, and acquiring fourth communication delay between the server and the equipment in real time;

a32, detecting whether the fourth communication delay is smaller than a third preset threshold value;

a331, if so, judging that the communication between the server and the equipment is smooth;

and A332, if not, judging that the communication between the server and the equipment is not smooth.

The third preset threshold in this embodiment is preset to 100ms, and may be adjusted according to the actual network situation or the response speed requirement of the device.

Compared with the traditional communication mode, the embodiment directly communicates with the device by the front end, so that the time for forwarding the communication between the front end and the server to the device is actually reduced, and the time for waiting for the user to obtain the feedback is shorter after the device successfully executes and then directly returns the success information to the front end.

The invention also discloses a terminal device, which comprises a processor and a storage device, wherein the storage device is used for storing one or more programs; when the one or more programs are executed by the processor, the processor implements the front-end control method or the server forwarding method described above that reduces server forwarding pressure. The processor may be a central processing unit (Central Processing Unit, CPU), other general purpose processors, digital signal processors (Digital Signal Processor, DSP), application specific integrated circuits (Application Specific Integrated Circuit, ASIC), off-the-shelf programmable gate arrays (Field-Programmable Gate Array, FPGA) or other programmable logic devices, discrete gate or transistor logic devices, discrete hardware components, or the like. A general purpose processor may be a microprocessor or the processor may be any conventional processor or the like, referred to as a control center for the test equipment, that interfaces and lines to various parts of the overall test equipment.

The storage means may be used for storing computer programs and/or modules, and the processor may implement various functions of the terminal device by running or executing the computer programs and/or modules stored in the storage means, and invoking data stored in the storage means. The storage device may mainly include a storage program area and a storage data area, wherein the storage program area may store an operating system, an application program required for at least one function, and the like; the storage data area may store data created according to the use of the terminal device, etc. In addition, the storage device may include high-speed random access memory, and may also include non-volatile memory, such as a hard disk, memory, plug-in hard disk, smart Media Card (SMC), secure Digital (SD) Card, flash Card (Flash Card), at least one disk storage device, flash memory device, or other volatile solid state storage device.

Wherein the above-mentioned integrated modules/units of the terminal device may be stored in a computer readable storage medium if implemented in the form of software functional units and sold or used as separate products. Based on such understanding, the present invention may implement all or part of the flow of the method of the above-described embodiments, or may be implemented by a computer program to instruct related hardware, and the computer program may be stored in at least one computer readable storage medium, where the computer program, when executed by a processor, may implement the steps of each of the method embodiments described above. Wherein the computer program comprises computer program code, which may be in the form of source code, object code, executable files or in some intermediate form, etc. The computer readable medium may include: any entity or device capable of carrying computer program code, a recording medium, a U disk, a removable hard disk, a magnetic disk, an optical disk, a computer Memory, a Read-Only Memory (ROM), a random access Memory (RAM, random Access Memory), an electrical carrier signal, a telecommunications signal, a software distribution medium, and so forth.

It should be noted that the embodiments of the apparatus and device described above are only schematic, where the units described as separate units may or may not be physically separated, and units shown as units may or may not be physical units, may be located in one place, or may be distributed over multiple network units. Some or all of the modules may be selected according to actual needs to achieve the purpose of the solution of this embodiment.

In addition, in the drawings of the device embodiment provided by the invention, the connection relation between the modules represents that the modules have communication connection, and can be specifically implemented as one or more communication buses or signal lines. Those of ordinary skill in the art will understand and implement the present invention without undue burden.

Claims (8)

1. The front-end control method for reducing the forwarding pressure of the server is applied to the front end and is characterized by comprising the following steps of:

the equipment and the server are both in communication connection with the front end;

detecting whether communication with the device is unobstructed in real time;

if yes, sending a first control instruction to the equipment, and copying the first control instruction to the server for archiving;

acquiring and displaying the working state of the equipment according to the equipment state information fed back by the equipment in real time, and forwarding the equipment state information to the server for archiving;

otherwise, notifying the server to connect the equipment;

detecting whether communication between the server and the device is smooth in real time;

if yes, a second control instruction is sent to the server; the second control instruction is used for informing the server to enter a forwarding mode, archiving the second control instruction, forwarding the second control instruction to the equipment at the same time, and forwarding and storing equipment state information fed back by the equipment in real time;

confirming and displaying the working state of the equipment according to the equipment state information forwarded by the server;

otherwise, the device is displayed as offline.

2. The front-end control method for reducing server forwarding pressure according to claim 1, wherein the device and the server are both communicatively connected to the front-end, specifically:

after the equipment is online, reporting the equipment state information to a server for storage;

the front end sends a communication request to the server, and the heartbeat connection between the server and the front end is established;

the front end requests the server and obtains the equipment state information;

and the front end establishes heartbeat connection with the equipment according to the equipment state information.

3. The front-end control method for reducing server forwarding pressure according to claim 1, wherein the real-time detection of whether communication with the device is unobstructed is specifically:

establishing heartbeat connection between the front end and the equipment, and acquiring a first communication delay between the front end and the equipment in real time according to the heartbeat connection;

detecting whether the first communication delay is smaller than a first preset threshold value;

if so, judging that the communication between the front end and the equipment is unobstructed;

otherwise, judging that the communication between the front end and the equipment is not smooth.

4. A front-end control method for reducing server forwarding pressure according to claim 3, further comprising the steps of:

comparing a first communication delay between the front end and the device with a second communication delay between the front end and the device forwarded by the server;

when the first communication delay is larger than the second communication delay, the front end sends a second control instruction to the server; the front end confirms and displays the working state of the equipment according to the equipment state information fed back by the server in real time;

otherwise, the front end sends a first control instruction to the equipment, and the front end copies the first control instruction to the server for archiving;

the front end acquires and displays the working state of the equipment according to the equipment state information fed back by the equipment in real time, and forwards the equipment state information to the server for archiving.

5. The front-end control method for reducing server forwarding pressure according to claim 1, further comprising the steps of:

and when the front end is not in smooth communication with the server, the front end displays that the server is offline.

6. A server forwarding method for reducing server forwarding pressure is characterized by comprising the following steps:

the server is in communication connection with the front end;

when the communication between the front end and the equipment is smooth, the server stores the equipment control instruction and the equipment state information which are sent by the front end;

when the communication between the front end and the equipment is not smooth, the server is in communication connection with the equipment;

detecting whether the communication between the server and the equipment is smooth or not in real time;

if yes, the server forwards the equipment control instruction of the front end to the equipment in real time, the server acquires the equipment state information of the equipment in real time and forwards the equipment state information to the front end, and the server files the equipment control instruction and the equipment state information;

otherwise, the feedback device feeds back the offline information to the front end.

7. The server forwarding method for reducing server forwarding pressure according to claim 6 wherein the server is communicatively connected to the front end, specifically:

the server receives the communication request of the front end, establishes heartbeat connection between the server and the front end, and acquires third communication delay between the server and the front end in real time;

detecting whether the third communication delay is smaller than a second preset threshold;

if so, the server and the front-end communication link are successfully established;

otherwise, the front end displays that the server is offline.

8. The server forwarding method for reducing server forwarding pressure according to claim 6, wherein the real-time detection of whether the server and the device communicate smoothly is specifically:

establishing heartbeat connection between the server and the equipment, and acquiring fourth communication delay between the server and the equipment in real time;

detecting whether the fourth communication delay is smaller than a third preset threshold;

if so, judging that the communication between the server and the equipment is smooth;

otherwise, judging that the communication between the server and the equipment is not smooth.

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