CN106918360B

CN106918360B - Automatic detection method, server, device to be detected and terminal

Info

Publication number: CN106918360B
Application number: CN201510990907.1A
Authority: CN
Inventors: 马先明
Original assignee: EVOC Intelligent Technology Co Ltd
Current assignee: EVOC Intelligent Technology Co Ltd
Priority date: 2015-12-24
Filing date: 2015-12-24
Publication date: 2021-01-12
Anticipated expiration: 2035-12-24
Also published as: CN106918360A

Abstract

The invention relates to an automatic detection method, a server for automatic detection, equipment to be detected and a terminal. The method comprises the following steps: receiving a detection request sent by equipment to be detected; responding to the detection request; receiving detection data sent by equipment to be detected; analyzing the detection data to obtain abnormal data; generating an abnormal data report according to the abnormal data; and sending the abnormal data report to a terminal so that the terminal displays the abnormal item of the device to be detected according to the abnormal data report. According to the automatic detection method, the server for automatic detection, the equipment to be detected and the terminal, the terminal can visually demonstrate abnormal items of the equipment to be detected according to the abnormal data report, maintenance personnel can directly obtain the abnormal items of the equipment to be detected through the terminal, a large amount of detection time and labor cost are saved, and the working efficiency is improved.

Description

Automatic detection method, server, device to be detected and terminal

Technical Field

The invention relates to the field of computers, in particular to an automatic detection method, a server for automatic detection, a device to be detected and a terminal.

Background

In a traditional mode, when detecting medium-sized and large-sized equipment, maintenance personnel often check parts and data of the equipment item by item according to a maintenance manual of the equipment, the maintenance personnel need to detect all items according to the maintenance manual and then find problems and abnormal parts of the equipment, the experience of the maintenance personnel is highly relied on, and the detection process is time-consuming and labor-consuming. The maintenance staff may miss some inspection items due to carelessness, and the maintenance manual records various detection contents of the equipment in a text form, the contents are many and complicated, and the abnormal items of the equipment cannot be reflected visually.

Disclosure of Invention

Therefore, there is a need for an automatic detection method that can visually and intuitively demonstrate abnormal items of equipment and save detection time and labor cost.

In addition, it is necessary to provide a server, a device to be detected and a terminal for automatic detection, which can visually and intuitively demonstrate abnormal items of the device, thereby saving detection time and labor cost.

An automatic detection method, comprising the steps of:

receiving a detection request sent by equipment to be detected;

responding to the detection request;

receiving detection data sent by equipment to be detected;

analyzing the detection data to obtain abnormal data;

generating an abnormal data report according to the abnormal data;

and sending the abnormal data report to a terminal so that the terminal displays the abnormal item of the device to be detected according to the abnormal data report.

In one embodiment, before the receiving of the detection request sent by the device to be detected, the method further includes the following steps:

receiving basic identification information sent by equipment to be detected;

and establishing a database matched with the basic identification information.

In one embodiment, the method further comprises the steps of:

acquiring a detection item of the equipment to be detected according to the detection request;

sending a detection instruction to the equipment to be detected according to the detection item, so that the equipment to be detected detects according to the detection instruction and acquires detection data;

and receiving detection data sent by the equipment to be detected, and storing the detection data in a database matched with the basic identification information of the equipment to be detected.

In one embodiment, the analyzing the detection data to obtain abnormal data specifically includes the following steps:

and judging whether the detection data are in a preset normal numerical value interval or not, if so, determining that the detection data are normal data, and if not, determining that the detection data are abnormal data.

An automatic detection method, comprising the steps of:

establishing a connection with the server by accessing a server address;

sending a detection request to the server;

receiving a detection instruction sent by the server;

detecting according to the detection instruction and acquiring detection data;

and sending the detection data to the server so that the server analyzes the detection data and generates an abnormal data report, sending the abnormal data report to a terminal, and displaying an abnormal item by the terminal according to the abnormal data report.

An automatic detection method, comprising the steps of:

scanning and acquiring basic identification information of equipment to be detected;

sending a report request to a server according to the basic identification information;

receiving an abnormal data report which is sent by the server and matched with the basic identification information;

analyzing the abnormal data report and generating a corresponding abnormal item;

and demonstrating the abnormal item.

A server for automated inspection, comprising:

the receiving module is used for receiving a detection request sent by the equipment to be detected;

a response module for responding to the detection request;

the receiving module is also used for receiving detection data sent by the equipment to be detected;

the analysis module is used for analyzing the detection data to obtain abnormal data;

the generating module is used for generating an abnormal data report according to the abnormal data;

and the sending module is used for sending the abnormal data report to a terminal so that the terminal displays the abnormal item of the device to be detected according to the abnormal data report.

In one embodiment, the receiving module is further configured to receive basic identification information sent by a device to be detected;

the server further comprises:

the establishing module is used for establishing a database matched with the basic identification information;

the acquisition module is used for acquiring the detection item of the equipment to be detected according to the detection request;

the sending module is further used for sending a detection instruction to the equipment to be detected according to the detection item, so that the equipment to be detected detects according to the detection instruction and obtains detection data;

the receiving module is also used for receiving the detection data sent by the equipment to be detected and storing the detection data in a database matched with the basic identification information of the equipment to be detected;

the analysis module is further used for judging whether the detection data are within a preset normal numerical value interval or not, if yes, the detection data are normal data, and if not, the detection data are abnormal data.

An apparatus to be tested, comprising:

the connection module is used for establishing connection with the server by accessing the address of the server;

a sending module, configured to send a detection request to the server;

a receiving module, configured to receive a detection instruction sent by the server;

the detection module is used for detecting according to the detection instruction and acquiring detection data;

the sending module is further used for sending the detection data to the server so that the server analyzes the detection data and generates an abnormal data report, the abnormal data report is sent to a terminal, and the terminal shows abnormal items according to the abnormal data report.

A terminal, comprising:

the scanning module is used for scanning and acquiring basic identification information of the equipment to be detected;

the sending module is used for sending a report request to a server according to the basic identification information;

a receiving module, configured to receive an abnormal datagram table that is sent by the server and matches the basic identification information;

the analysis module is used for analyzing the abnormal data report and generating a corresponding abnormal item;

and the demonstration module is used for demonstrating the abnormal item.

According to the automatic detection method, the server for automatic detection, the equipment to be detected and the terminal, the server receives and analyzes detection data of the equipment to be detected to generate an abnormal data report, then the abnormal data report is sent to the terminal, the terminal can visually demonstrate abnormal items of the equipment to be detected according to the abnormal data report, maintenance personnel can directly obtain the abnormal items of the equipment to be detected through the terminal, a large amount of detection time and labor cost are saved, and working efficiency is improved.

Drawings

FIG. 1 is a system architecture diagram of an automated inspection method in one embodiment;

FIG. 2 is a schematic flow chart diagram of an automatic detection method in one embodiment;

FIG. 3 is a flow diagram illustrating the process of the server receiving the inspection data in one embodiment;

FIG. 4 is a schematic flow chart of an automatic detection method in another embodiment;

FIG. 5 is a schematic flow chart of an automatic detection method in yet another embodiment;

FIG. 6 is a block diagram of a server for automatic detection in one embodiment;

FIG. 7 is a diagram showing the structure of a server for automatic detection in another embodiment;

FIG. 8 is a schematic structural diagram of an apparatus to be tested in one embodiment;

fig. 9 is a schematic structural diagram of a terminal in one embodiment.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention is described in further detail below 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.

FIG. 1 is a system architecture diagram of an automated inspection method in one embodiment. As shown in fig. 1, the system architecture includes a device to be detected 10, a server 20 and a terminal 30. The device to be detected 10 establishes a connection with the server 20 by accessing the address of the server 20 and sends a detection request to the server 20. The server 20 responds to the detection request of the device to be detected 10 and sends a detection instruction to the device to be detected 10. The device to be detected 10 receives the detection instruction sent by the server 20, detects according to the detection instruction and obtains detection data. The device to be tested 10 sends the test data to the server 20. The server 20 receives the detection data sent by the device to be detected 10, analyzes the detection data to obtain abnormal data, and generates an abnormal data report according to the abnormal data. The terminal 30 scans and acquires the basic identification information of the device to be detected 10 and sends a report request to the server 20. The server 20 sends the abnormal data report of the device to be detected 10 to the terminal 30. The terminal 30 receives the abnormal data report which is sent by the server 20 and matches with the basic identification information of the device to be detected 10, analyzes the abnormal data report and generates a corresponding abnormal item. The terminal 30 demonstrates the anomalous project of the device 10 to be tested. The terminal 30 can visually demonstrate the abnormal items of the equipment to be detected according to the abnormal data report form of the equipment to be detected 10, and maintenance personnel can directly obtain the abnormal items of the equipment to be detected 10 through the terminal, so that a large amount of detection time and labor cost are saved.

As shown in fig. 2, in an embodiment, an automatic detection method is described from a server side, and includes the following steps:

step S210, receiving a detection request sent by a device to be detected.

Specifically, the server and the equipment to be detected carry out bidirectional data communication, a detection request can be sent to the server when the equipment to be detected breaks down, and the equipment to be detected can also send the detection request to the server at preset intervals for carrying out timing detection. The device to be detected can be medium-large-sized devices such as airplanes, large-sized measuring instruments and the like, but is not limited to the devices, and the server can be a cloud server and the like.

Step S220, responding to the detection request.

Specifically, the server responds to the detection request after receiving the detection request sent by the device to be detected.

In one embodiment, before the step of receiving the detection request sent by the device to be detected, the method further includes the steps of: and receiving the basic identification information sent by the equipment to be detected, and establishing a database matched with the basic identification information.

Specifically, the equipment to be detected can be connected with the server through accessing the address of the server, and the server and the equipment to be detected are in bidirectional data communication. The device to be tested may send basic identification information to the server, which may include information such as an ID (identification) of the device to be tested, a device type, a manufacturing date, and an operating time. After receiving the basic identification information sent by the equipment to be detected, the server establishes a database matched with the basic identification information, and because the IDs of different equipment to be detected are different, the server establishes a unique database corresponding to the equipment to be detected.

Step S230, receiving the detection data sent by the device to be detected.

Specifically, the detection data may include one or more of voltage data, current data, frequency data, temperature data, humidity data, rotational speed data, acceleration data, stress data, and battery data of the device to be detected. The equipment to be detected can detect according to different detection items and send various detection data to the server one by one. The server may store the received detection data in a database corresponding to the device to be detected.

Step S240, analyzing the detection data to obtain abnormal data.

Specifically, the server can analyze the received detection data of one or more devices to be detected, and judge which detection data are normal data and which detection data are abnormal data.

In an embodiment, the step of analyzing the detection data to obtain the abnormal data may specifically be: and judging whether the detected data is in a preset normal numerical value interval, if so, determining the detected data as normal data, and if not, determining the detected data as abnormal data.

Specifically, the server may store in advance normal value intervals corresponding to various detection data of the device to be detected. When the server receives one or more items of detection data sent by the equipment to be detected, the server sequentially judges whether the detection data are normal data or not. The server can obtain a preset normal value interval corresponding to the detection data, when the detection data is in the normal value interval, the detection data is judged to be normal data, and when the detection data is not in the normal value interval, the detection data is judged to be abnormal data.

And step S250, generating an abnormal data report according to the abnormal data.

Specifically, after analyzing the detection data of the device to be detected to obtain abnormal data, the server generates a corresponding abnormal data report according to the abnormal data.

And step S260, sending the abnormal data report to the terminal so that the terminal displays the abnormal item of the device to be detected according to the abnormal data report.

Specifically, the terminal can be a mobile terminal such as a tablet computer, a laptop, a smart phone and the like, preferably, the terminal can be a reinforced tablet computer, the reinforced tablet computer is more suitable for detection of medium and large-sized equipment in military units, and the reinforced tablet computer has better effects of drop resistance, shock resistance, battery endurance, autonomous system control and the like than a common tablet computer, a common laptop and the like. The terminal can scan the equipment to be detected and obtain the basic identification information of the equipment to be detected, and then sends a report request to the server. And the server responds to the report request of the terminal and sends the abnormal data report of the device to be detected to the terminal. The terminal analyzes the abnormal data report to obtain each detection item of the equipment to be detected with abnormality, and demonstrates each abnormal item of the equipment to be detected in the forms of three-dimensional dynamic, pictures, characters and the like, wherein each abnormal item comprises a fault point and an abnormal part of the equipment to be detected. The contents demonstrated by the terminal may include the function and effect of the fault point, the location of the fault point on the device to be tested, the size and structure of the fault point, the operation steps required to correctly find the fault point, etc. When maintenance personnel maintain on site, the fault point and abnormal part of the equipment to be detected can be positioned and searched only by carrying the terminal, so that the method is convenient and fast, and the working efficiency is improved.

According to the automatic detection method, the server receives and analyzes the detection data of the equipment to be detected to generate the abnormal data report, then the abnormal data report is sent to the terminal, the terminal can visually demonstrate the abnormal items of the equipment to be detected according to the abnormal data report, and maintenance personnel can directly obtain the abnormal items of the equipment to be detected through the terminal, so that a large amount of detection time and labor cost are saved, and the working efficiency is improved.

As shown in fig. 3, in an embodiment, the automatic detection method further includes the following steps:

and S310, acquiring a detection item of the device to be detected according to the detection request.

Specifically, after the server responds to the detection request of the equipment to be detected, the detection item of the equipment to be detected can be obtained according to the detection request. Aiming at different types of equipment to be detected, the server can preset different detection items, and the detection items can comprise one or more of voltage, current, frequency, temperature, humidity, rotating speed, acceleration, stress, batteries and the like.

And S320, sending a detection instruction to the equipment to be detected according to the detection item, so that the equipment to be detected detects according to the detection instruction and acquires detection data.

Specifically, the server can send corresponding detection instructions to the equipment to be detected one by one according to detection items of the equipment to be detected, and the detection instructions can include one or more of voltage detection instructions, current detection instructions, frequency detection instructions, temperature detection instructions, humidity detection instructions, rotating speed detection instructions, acceleration detection instructions, stress detection instructions, battery detection instructions and the like. The server can send a detection instruction to the equipment to be detected each time, the equipment to be detected can detect according to the detection instruction and acquire corresponding detection data, then the detection data is sent to the server, and the server sends the next detection instruction to the equipment to be detected. In other embodiments, the server may also send multiple detection instructions to the device to be detected at the same time, and the device to be detected returns multiple corresponding detection data to the server after detection.

And step S330, receiving the detection data sent by the equipment to be detected, and storing the detection data in a database matched with the basic identification information of the equipment to be detected.

Specifically, after receiving one or more items of detection data sent by the equipment to be detected, the server can store the detection data in the unique database corresponding to the equipment to be detected, so that data checking and calling are facilitated.

As shown in fig. 4, in an embodiment, an automatic detection method is described from a device to be detected, and includes the following steps:

step S410, establishing a connection with the server by accessing the server address.

Specifically, the device to be detected can be pre-installed with a specific device detection program, and then the connection is established with the server by accessing the server address to perform bidirectional data communication.

In one embodiment, after the step of establishing the connection with the server by accessing the server address, the method further comprises: and sending the basic identification information to the server.

Specifically, the device to be detected can send basic identification information such as an ID, a device type, a manufacturing date and operating time to the server, the server can establish a unique database matched with the basic identification information of the device to be detected, and the database can be used for storing data such as detection data and an abnormal data report of the device to be detected.

Step S420, sending a detection request to the server.

Specifically, when the device to be detected fails, a detection request may be sent to the server. The device to be detected may also send a detection request to the server at preset intervals, and perform a timing detection, for example, a detection is performed every 3 days, a week, and the like.

Step S430, receiving a detection instruction sent by the server.

Specifically, the detection instruction may include one or more of a voltage detection instruction, a current detection instruction, a frequency detection instruction, a temperature detection instruction, a humidity detection instruction, a rotational speed detection instruction, an acceleration detection instruction, a stress detection instruction, a battery detection instruction, and the like.

And step S440, detecting according to the detection instruction and acquiring detection data.

Specifically, after receiving the detection instruction sent by the server, the device to be detected can call each functional hardware detection module matched with the detection instruction one by one to perform detection, such as a voltage detection module, a current detection module, a frequency detection module, a temperature detection module, a humidity detection module, a rotation speed detection module, an acceleration detection module, a stress detection module, a battery detection module, and the like, and return detection results one by one to the server, that is, the obtained detection data.

And step S450, sending the detection data to the server so that the server analyzes the detection data and generates an abnormal data report, sending the abnormal data report to the terminal, and displaying an abnormal item by the terminal according to the abnormal data report.

Specifically, after the equipment to be detected sends the detection data to the server one by one, the server can analyze the detection data to obtain abnormal data, and generate an abnormal data report according to the abnormal data. And after the terminal sends a report request to the server, the server sends the abnormal data report of the equipment to be detected to the terminal. And the terminal analyzes the abnormal data report to obtain abnormal items of the equipment to be detected, and demonstrates each abnormal item of the equipment to be detected in the forms of three-dimensional dynamics, pictures, characters and the like.

As shown in fig. 5, in one embodiment, an automatic detection method, described in the following description, includes the following steps:

step S510, scanning and acquiring basic identification information of the device to be detected.

Specifically, the terminal scans the device to be detected and obtains basic identification information such as an ID of the device to be detected. The terminal can be a mobile terminal such as a tablet personal computer, a laptop, a smart phone and the like, preferably, the terminal can be a reinforced tablet personal computer which is more suitable for detection of medium and large-sized equipment in military units, and compared with a common tablet personal computer, a laptop and the like, the reinforced tablet personal computer has better effects of drop resistance, shock resistance, battery endurance, autonomous system control and the like.

In one embodiment, after the step of scanning and acquiring the basic identification information of the device to be detected, the method further includes: a connection is established with the server by accessing the server address.

Specifically, the terminal can also establish connection with the server by accessing the server address to perform bidirectional data communication.

Step S520, a report request is sent to the server according to the basic identification information.

Specifically, the terminal can send a report request to the server, the report request includes basic identification information such as the ID of the device to be detected, and the server can obtain the matched abnormal data report according to the basic identification information such as the ID of the device to be detected in the report request.

Step S530, receiving the abnormal datagram table matched with the basic identification information sent by the server.

Specifically, the server sends the abnormal data report matched with the basic identification information of the equipment to be detected to the terminal.

And step S540, analyzing the abnormal data report and generating a corresponding abnormal item.

Specifically, the terminal analyzes the received abnormal data report of the equipment to be detected, and can obtain each detection item of the equipment to be detected with abnormality, wherein each abnormal item comprises a fault point and an abnormal part of the equipment to be detected.

In step S550, an exception item is presented.

Specifically, the terminal can demonstrate each abnormal item of the equipment to be detected in the forms of three-dimensional dynamic, pictures, characters and the like, and the content demonstrated by the terminal can comprise functions and effects of fault points, positions of the fault points on the equipment to be detected, sizes and structures of the fault points, operation steps required for correctly finding the fault points and the like. The terminal demonstrates that each abnormal item of the equipment to be detected is more visual and vivid through three-dimensional dynamic. When maintenance personnel maintain on site, the fault point and abnormal part of the equipment to be detected can be positioned and searched only by carrying the terminal, so that the method is convenient and fast, and the working efficiency is improved.

As shown in fig. 6, in one embodiment, a server for automated inspection includes a receiving module 610, a responding module 620, an analyzing module 630, a generating module 640, and a sending module 650.

The receiving module 610 is configured to receive a detection request sent by a device to be detected.

And a response module 620, configured to respond to the detection request.

The receiving module 610 is further configured to receive detection data sent by a device to be detected.

And the analysis module 630 is configured to analyze the detection data to obtain abnormal data.

The generating module 640 is configured to generate an abnormal data report according to the abnormal data.

A sending module 650, configured to send the abnormal data report to the terminal, so that the terminal displays an abnormal item of the device to be detected according to the abnormal data report.

Above-mentioned a server for automated inspection, server generate abnormal data report form through receiving the detection data of waiting to examine equipment and carry out the analysis, then send unusual data report form for the terminal, the terminal can demonstrate the unusual project of waiting to examine equipment directly perceivedly according to this unusual data report form, and maintainer can directly obtain the unusual project of waiting to examine equipment through the terminal, saves a large amount of check-out time and human cost, improves work efficiency.

The server for automatic detection includes a building module 660 and an obtaining module 670, in addition to the receiving module 610, the responding module 620, the analyzing module 630, the generating module 640 and the sending module 650.

The receiving module 610 is further configured to receive the basic identification information sent by the device to be detected.

Specifically, the equipment to be detected can be connected with the server through accessing the address of the server, and the server and the equipment to be detected are in bidirectional data communication. The device to be tested can send basic identification information to the server, and the basic identification information can comprise information such as the ID, the device type, the manufacturing date and the operating time of the device to be tested. After receiving the basic identification information sent by the equipment to be detected, the server establishes a database matched with the basic identification information, and because the IDs of different equipment to be detected are different, the server establishes a unique database corresponding to the equipment to be detected.

An establishing module 660, configured to establish a database matching the basic identification information.

An obtaining module 670, configured to obtain a detection item of the device to be detected according to the detection request.

The sending module 650 is further configured to send a detection instruction to the device to be detected according to the detection item, so that the device to be detected performs detection according to the detection instruction and obtains detection data.

The receiving module 610 is further configured to receive the detection data sent by the device to be detected, and store the detection data in a database matched with the basic identification information of the device to be detected.

The analysis module 630 is further configured to determine whether the detected data is within a preset normal value range, if so, the detected data is normal data, and if not, the detected data is abnormal data.

As shown in fig. 8, in one embodiment, an apparatus to be detected includes a connection module 810, a sending module 820, a receiving module 830, and a detecting module 840.

A connection module 810, configured to establish a connection with the server by accessing the server address.

A sending module 820, configured to send the detection request to the server.

Specifically, when the device to be detected fails, a detection request may be sent to the server. The device to be detected may also send a detection request to the server at preset intervals, and perform timing detection, for example, performing detection every 3 days, a week, and the like.

In one embodiment, the sending module 820 is further configured to send the basic identification information to a server.

A receiving module 830, configured to receive the detection instruction sent by the server.

And the detection module 840 is used for detecting according to the detection instruction and acquiring detection data.

The sending module 820 is further configured to send the detection data to the server, so that the server analyzes the detection data and generates an abnormal data report, and sends the abnormal data report to the terminal, and the terminal displays an abnormal item according to the abnormal data report.

Above-mentioned check out test set, server are through receiving check out test set's detection data and carry out the analysis, generate abnormal data report form, then send unusual data report form for the terminal, and the terminal can demonstrate the unusual project of check out test set directly perceivedly according to this unusual data report form, and maintainer can directly obtain the unusual project of check out test set through the terminal, saves a large amount of detection time and human cost, improves work efficiency.

As shown in fig. 9, in one embodiment, a terminal includes a scanning module 910, a transmitting module 920, a receiving module 930, a parsing module 940, and a presentation module 950.

The scanning module 910 is configured to scan and obtain basic identification information of a device to be detected.

The sending module 920 is configured to send a report request to the server according to the basic identification information.

A receiving module 930, configured to receive the abnormal datagram table sent by the server and matched with the basic identification information.

And the parsing module 940 is configured to parse the exception datagram table and generate a corresponding exception entry.

A demonstration module 950 for demonstrating the exception item.

In an embodiment, the terminal further includes a connection module, configured to establish a connection with the server by accessing the server address.

According to the terminal, the server receives and analyzes the detection data of the equipment to be detected, the abnormal data report is generated, then the abnormal data report is sent to the terminal, the terminal can visually demonstrate the abnormal items of the equipment to be detected according to the abnormal data report, maintenance personnel can directly obtain the abnormal items of the equipment to be detected through the terminal, a large amount of detection time and labor cost are saved, and the working efficiency is improved.

The technical features of the embodiments described above may be arbitrarily combined, and for the sake of brevity, all possible combinations of the technical features in the embodiments described above are not described, but should be considered as being within the scope of the present specification as long as there is no contradiction between the combinations of the technical features.

The above-mentioned embodiments only express several embodiments of the present invention, and the description thereof is more specific and detailed, but not construed as limiting the scope of the invention. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the inventive concept, which falls within the scope of the present invention. Therefore, the protection scope of the present patent shall be subject to the appended claims.

Claims

1. An automatic detection method is characterized by comprising the following steps:

receiving a detection request sent by equipment to be detected; responding to the detection request;

sending detection instructions to the equipment to be detected one by one according to the detection items, so that the equipment to be detected detects according to the detection instructions and obtains detection data;

receiving detection data sent by equipment to be detected;

analyzing the detection data to obtain abnormal data;

generating an abnormal data report according to the abnormal data;

2. The automatic detection method according to claim 1, characterized in that it further comprises, before said receiving a detection request sent by a device to be detected, the steps of:

receiving basic identification information sent by equipment to be detected;

and establishing a database matched with the basic identification information.

3. The automatic detection method according to claim 1, characterized in that it further comprises the steps of:

and storing the detection data in a database matched with the basic identification information of the equipment to be detected.

4. The automatic detection method according to claim 1 or 2, wherein the analyzing the detection data to obtain abnormal data specifically comprises the following steps:

5. An automatic detection method is characterized by comprising the following steps:

establishing a connection with the server by accessing a server address;

sending a detection request to the server;

receiving a detection instruction sent by the server; the detection instructions are sent to the equipment to be detected one by the server according to the detection items of the equipment to be detected obtained by the detection request;

detecting according to the detection instruction and acquiring detection data;

6. An automatic detection method is characterized by comprising the following steps:

receiving an abnormal data report which is sent by the server and matched with the basic identification information; the abnormal data report is generated by abnormal data obtained by analyzing detection data, and the detection data are obtained by acquiring detection items of the equipment to be detected according to a detection request and sending detection instructions to the equipment to be detected one by one so that the equipment to be detected is detected and acquired according to the detection instructions;

and demonstrating the abnormal item.

7. A server for automated inspection, comprising:

a response module for responding to the detection request;

the sending module is used for sending the abnormal data report to a terminal so that the terminal can show the abnormal item of the device to be detected according to the abnormal data report;

the sending module is further used for sending a detection instruction to the equipment to be detected according to the detection item, so that the equipment to be detected can detect according to the detection instruction and obtain detection data.

8. The server for automatic detection according to claim 7, wherein the receiving module is further configured to receive basic identification information sent by a device to be detected;

the server further comprises:

9. An apparatus to be tested, comprising:

a sending module, configured to send a detection request to the server;

a receiving module, configured to receive a detection instruction sent by the server; the detection instructions are sent to the equipment to be detected one by the server according to the detection items of the equipment to be detected obtained by the detection request;

10. A terminal, comprising:

a receiving module, configured to receive an abnormal datagram table that is sent by the server and matches the basic identification information; the abnormal data report is generated by abnormal data obtained by analyzing detection data, and the detection data are obtained by acquiring detection items of the equipment to be detected according to a detection request and sending detection instructions to the equipment to be detected one by one so that the equipment to be detected is detected and acquired according to the detection instructions;

and the demonstration module is used for demonstrating the abnormal item.