CN115061615A

CN115061615A - Intelligent scientific equipment test system, method, medium and equipment

Info

Publication number: CN115061615A
Application number: CN202210610067.1A
Authority: CN
Inventors: 卫晓娜; 王珂; 刘翠红; 管洪飞
Original assignee: Technology and Engineering Center for Space Utilization of CAS
Current assignee: Technology and Engineering Center for Space Utilization of CAS
Priority date: 2022-05-31
Filing date: 2022-05-31
Publication date: 2022-09-16

Abstract

The invention relates to the technical field of aviation, in particular to an intelligent scientific equipment testing system, method, medium and equipment. The system comprises: the system comprises a data management module, a user interface, an instruction management module and an interface communication module; the instruction management module is used for generating a test control instruction according to basic information of the tested scientific equipment and sending the test control instruction to the interface communication module; the interface communication module is used for sending the test control instruction to the tested scientific equipment, receiving feedback data of the tested scientific equipment and sending the feedback data to the data management module; the data management module is used for carrying out classification analysis on the feedback data to obtain an analysis result and sending the analysis result to the user interface; the user interface is used for displaying the analysis result. The invention can achieve the effects of integrated control and cost saving.

Description

Intelligent scientific equipment test system, method, medium and equipment

Technical Field

The invention relates to the technical field of aviation, in particular to an intelligent scientific equipment testing system, method, medium and equipment.

Background

The space station is provided with a large number of scientific equipment, the communication interfaces of the scientific equipment are consistent with the communication protocols, and the types and formats of the uplink data and the downlink data are consistent. The difference of different scientific equipments is that the load identifiers of the subsystems, the equipment identifiers of the subsystems, the parameters contained in the uplink and downlink data and the intelligent criterion information are different. The detection and the investigation of manual equipment one by one are time-consuming and labor-consuming, and the problems of misjudgment and the like are easy to occur in the process of the investigation, so that an intelligent test system is urgently needed at present.

Disclosure of Invention

The invention aims to provide an intelligent scientific equipment testing system, method, medium and equipment.

The technical scheme for solving the technical problems is as follows: an intelligent scientific equipment testing system comprising: the system comprises a data management module, a user interface, an instruction management module and an interface communication module;

the instruction management module is used for generating a control instruction according to basic information of the tested scientific equipment and sending the control instruction to the interface communication module;

the interface communication module is used for sending the control instruction to the tested scientific equipment, receiving feedback data of the tested scientific equipment and sending the feedback data to the data management module;

the data management module is used for carrying out classification analysis on the feedback data to obtain an analysis result and sending the analysis result to the user interface;

the user interface is used for displaying the analysis result.

The invention has the beneficial effects that: the embedded test can be realized through the interface communication module, namely, the test system can be continuously updated in the research and development and test processes to deal with different tested scientific equipment, the problem that the quantity of control equipment is far less than that of the tested scientific equipment can be effectively solved through the test system, in addition, the test content is finally integrated and test control instructions are generated, and the effect of low cost is finally realized.

On the basis of the technical scheme, the invention can be further improved as follows.

Further, the basic information includes:

the system comprises a load identifier of a subsystem to which the tested scientific equipment belongs, the name of the tested scientific equipment, the identification of the tested scientific equipment and control instruction parameters.

Further, the feedback data includes:

digital quantities, engineering data, and application data.

Further, still include:

and the intelligent interpretation module is used for judging the running state of the tested scientific equipment and generating a judgment result.

Further, still include:

and the data storage module is used for storing the control instruction, the feedback data and the basic information.

Another technical solution of the present invention for solving the above technical problems is as follows: an intelligent scientific equipment testing method comprises the following steps:

step 1, an instruction management module generates a control instruction according to basic information of a tested scientific device and sends the control instruction to an interface communication module;

step 2, the interface communication module sends the control instruction to the tested scientific equipment, receives feedback data of the tested scientific equipment and sends the feedback data to a data management module;

step 3, the data management module carries out classification analysis on the feedback data to obtain an analysis result, and the analysis result is sent to a user interface;

and 4, displaying the analysis result by the user interface.

The invention has the beneficial effects that: the embedded test can be realized through the interface communication module, namely, the test system can be continuously updated in the research and development and test processes to deal with different tested scientific equipment, the problem that the number of control equipment is far less than that of the tested scientific equipment can be effectively solved through the test system, in addition, the test content is finally integrated and test control instructions are generated, and the effect of low cost is finally realized.

Further, the basic information includes:

Further, the feedback data includes:

digital quantities, engineering data, and application data.

Further, still include:

and 5, judging the running state of the tested scientific equipment by the intelligent interpretation module and generating a judgment result.

Further, still include:

and 6, storing the control instruction, the feedback data and the basic information by a data storage module.

Another technical solution of the present invention for solving the above technical problems is as follows: a storage medium having instructions stored therein, which when read by a computer, cause the computer to perform an intelligent scientific equipment testing method as in any one of the above.

Another technical solution of the present invention for solving the above technical problems is as follows: an electronic device includes the storage medium and a processor executing instructions in the storage medium.

Drawings

FIG. 1 is a structural framework diagram provided by an embodiment of an intelligent scientific equipment testing system of the present invention;

FIG. 2 is a schematic flow chart of an intelligent scientific equipment testing method according to an embodiment of the present invention;

FIG. 3 is a schematic diagram of information flow between modules provided by an embodiment of an intelligent scientific equipment testing system according to the present invention;

FIG. 4 is a schematic diagram illustrating a control command definition in an interface data sheet according to an embodiment of the intelligent scientific equipment testing system of the present invention;

fig. 5 is a schematic diagram of an example of detection provided by an embodiment of an intelligent scientific equipment testing system according to the present invention.

In the drawings, the components represented by the respective reference numerals are listed below:

1. the system comprises a test system 11, a data management module 12, a user interface 13, an instruction management module 14 and an interface communication module.

Detailed Description

The principles and features of this invention are described below in conjunction with examples which are set forth to illustrate, but are not to be construed to limit the scope of the invention.

As shown in fig. 1, an intelligent scientific equipment testing system 1 includes: a data management module 11, a user interface 12, an instruction management module 13 and an interface communication module 14;

the instruction management module 13 is configured to generate a control instruction according to basic information of the scientific equipment to be tested, and send the control instruction to the interface communication module 14;

the interface communication module 14 is configured to send the control instruction to the scientific equipment to be tested, receive feedback data of the scientific equipment to be tested, and send the feedback data to the data management module 11;

the data management module 11 is configured to perform classification analysis on the feedback data to obtain an analysis result, and send the analysis result to the user interface 12;

the user interface 12 is used for displaying the analysis result.

In some possible embodiments, the interface communication module 14 may implement embedded testing, that is, the testing system 1 may be continuously updated in the development and testing processes to deal with different scientific devices to be tested, and the problem that the number of control devices is much smaller than the number of scientific devices to be tested may be effectively solved by the testing system 1, in addition, the application finally integrates the testing content and generates the testing control instruction, and finally, the effect of low cost is achieved.

The space station is provided with a large number of scientific equipment, the communication interfaces of the scientific equipment are consistent with the communication protocols, and the types and formats of the uplink data and the downlink data are consistent. The difference of different scientific equipments is that the load identifiers of the subsystems, the equipment identifiers of the subsystems, the parameters contained in the uplink and downlink data and the intelligent criterion information are different.

Firstly, in the research and development and a series of test processes, the design can be continuously corrected and perfected, the embedded test system 1 has long hardware change period and high cost; secondly, the number of the control devices is far smaller than that of the scientific devices, the scientific devices are distributed in different cities and even different countries for research and development, the cost of docking and integration with the control devices is high, and thirdly, the communication interface and the functions of the pure software testing system 1 are very easy to expand, so that the parallel testing of a plurality of scientific devices is facilitated.

Based on the characteristics, the interface related to the difference points and the physical characteristics of various scientific equipment is configured by a human-computer interaction interface, the scientific equipment is uniquely represented by the load identifier of the subsystem and the equipment identifier of the scientific equipment, and the uplink and downlink data information and the intelligent criterion information of the scientific equipment are indexed, so that the general intelligent scientific equipment parallel test system 1 is designed.

As shown in fig. 3, the interface communication module 14, i.e. the interface in fig. 3, communicates with the scientific equipment to be tested through RS422 and ethernet. After the scientific equipment to be tested is connected with the RS422 or Ethernet interface of the test software, the channel must be registered first, and the uplink and downlink data can be received and transmitted after the channel is registered. The interface communication module 14 sends a timing instruction (for time synchronization), a collection instruction (a digital quantity, engineering data and application data collection instruction), a registration instruction, a control instruction and the like to the scientific equipment to be tested, and forwards the digital quantity, the engineering data, the application data and the like received from the scientific equipment to be tested to the data management module 11 for processing. The data management module 11 is mainly responsible for: since the scientific device under test receives a bundle of hexadecimal source codes, each type of data has a header, a length and a checksum. The source code of the digital quantity, the engineering data and the application data is thus first identified from the header, the length and the checksum. And then, according to the definition of the interface data sheet, the source codes and physical values of the digital quantity, the engineering data and the application data are analyzed, so that the digital quantity, the engineering data and the application data are convenient to check and interpret.

The command management module 13, i.e. the command management in fig. 3, receives from the user interface 12 a subsystem load identifier (an identification number of a load, uniquely identifies a load), a name of a scientific device, an identifier of a scientific device, and control command parameters of the scientific device to be tested, and uses these information to construct a control command (a command for controlling the device to be tested, which generally includes a soft reset command, and a control command for external components of the device to be tested, such as a motor add/break unit, a motor speed control, etc.), which is required by the scientific device to be tested, and feeds these information back to the user interface 12 for display. The method aims to input a single parameter value by a user, display a complete instruction generated by the test system 1, display the complete instruction to be convenient for judging whether the instruction is correct or not in fault location, and comprehensively understand historical operation.

The data management module 11, i.e. the data management in fig. 3, classifies and analyzes the raw data (the data received from the communication interface without any processing, i.e. the feedback data) received from the interface communication module 14 according to the data type (each type of data includes a header, a length, and a checksum, and based on these information, the classified analysis is sent to the user interface 12 for display.

The user interface 12 is used for configuring a subsystem load identifier, a name of the scientific equipment, an identifier of the scientific equipment and communication interface information of the scientific equipment, and simultaneously displaying the generated control instruction, and various analyzed data lists and curves. The configuration is carried out on controls such as a text box, a pull-down selection box, a path selection dialog box and the like on an interface, a load identifier is already distributed to each subsystem during design, scientific equipment identification, names and the like are distributed to each tested device, the configuration is carried out according to values distributed during design, and the test system 1 is designed and realized for the purpose of design and demand.

The intelligent interpretation module, namely the intelligent interpretation in fig. 3, may perform intelligent interpretation at several levels, that is, the judgment on the operation state of the tested scientific equipment may be:

roughly judging a single parameter of the tested scientific equipment according to the upper limit and the lower limit defined in the interface data sheet, judging that the parameter is abnormal if the parameter is not in the specified upper limit and lower limit range, and highlighting the parameter;

automatically judging the receiving, analyzing and executing conditions of the control instruction according to the control instruction and criterion parameter information defined in the interface data sheet, and judging whether the state change of the equipment after execution meets the expectation;

judging the running state of the scientific equipment according to the associated logic relationship of a plurality of parameters (namely parameters in the interface data sheet) configured by the user interface 12;

intelligently judging the running states of a plurality of scientific equipment during parallel test according to the correlation logic relationship of a plurality of parameters (each tested scientific equipment has a plurality of parameters) of the plurality of scientific equipment configured by the user interface 12;

the test of the user for the physical characteristics of the tested scientific equipment can be met by opening a multi-parameter association logic relationship configuration interface for the user.

The individual parameters are: each parameter defined in the interface data sheet is called a single parameter; defining a value type when each parameter in the interface data sheet is defined, and simultaneously defining an upper limit and a lower limit if the value type is in a range; if the value type is value, defining the value at the same time; therefore, the upper limit and the lower limit can be used for carrying out the initial judgment on the correctness of the parameters according to the value type value in the interface data sheet; the data storage module takes the load identifier of the subsystem and the equipment identifier of the scientific equipment as indexes, stores various control instructions, original data, classified data and intelligent judgment results, and is convenient for positioning test problems.

The interface data sheet is as follows: the interface data sheet is defined by designers of each tested scientific device according to the measurement and control requirements of the tested device; the interface data sheet of each tested scientific equipment is different.

The specific steps of automatically judging the receiving, analyzing and executing conditions of the control command according to the control command and the criterion parameter information defined in the interface data sheet and judging whether the state change of the equipment after execution meets the expectation are as follows:

fig. 4 is a definition of a control command for a tested scientific device, where each command code corresponds to a criterion parameter code, a criterion parameter name, and a criterion parameter value, such as event 5: and motor control, namely generating motor control instructions of motor power-off, motor power-on, motor locking, motor unlocking, motor stalling, motor main winding switching and motor standby winding switching according to the event 5. The method specifically comprises the following steps: event 5: motor control, which defines a function identifier, a command code and required parameters for executing a certain function; generating various types of control instructions according to events, dividing the control instructions into an immediate instruction and a delayed instruction according to whether the control instructions are executed immediately or not, and dividing the control instructions into an instruction containing one event and an instruction containing a plurality of events according to the number of the contained events; according to the event 5, a control command containing only one event can be generated, such as a motor power-off command, a motor power-on command, a motor locking command, a motor unlocking command, a motor stalling command, a motor main winding switching command or a motor standby winding switching command; control instructions containing multiple events, such as 4 events including motor power-up, motor locking, motor stalling and motor power-down at the same time, can also be generated; the tested device with time requirement can generate a time delay order containing time, such as a control instruction containing 3 minutes and 50 seconds of power-up of an execution motor and 5 minutes and 10 seconds of locking of the execution motor; the intelligent test system 1 finds corresponding parameters in the interface data sheet according to the code number and the name of the criterion parameter, and can carry out intelligent judgment according to the value of the parameter when receiving the data.

The specific operation state of the scientific equipment is judged according to the associated logical relationship of a plurality of parameters (namely parameters in the interface data sheet) configured by the user interface 12 as follows:

FIG. 5 is a definition of a fault criterion and related parameters in an interface data sheet for a scientific device under test; after the user inputs the logical relationship of the fault criterion through the user interface 12, the intelligent test system 1 converts the logical relationship into a judgment condition, and after receiving corresponding data, intelligent judgment can be performed.

The operation states of the multiple scientific devices during the parallel test are intelligently determined according to the associated logical relationship of multiple parameters of the multiple scientific devices (each tested scientific device has multiple parameters) configured by the user interface 12, specifically:

during design, a plurality of tested scientific equipment are defined, and if the faults are judged in a multi-parameter combined mode, interpretation rules need to be explained for each interpreter, and the judgment is easy to miss; the intelligent test system 1 inputs the logical relationship of a plurality of parameters through an interface and then carries out intelligent judgment in real time. On a human-computer interaction interface, corresponding parameters can be selected from a parameter list defined by digital quantity, engineering data or application data, and a multi-parameter joint judgment logical relation is defined, such as ((A & & B) | (A & & C)); and extracting corresponding parameters from the received data according to the defined logical relationship to perform joint judgment.

The general intelligent scientific equipment parallel test system 1 can be used for verifying the correctness of a scientific equipment communication interface, a communication protocol, software functions and the like, and a scientific equipment developer can complete a confirmation test before product delivery, so that the quality of delivery of scientific equipment is improved, and the butt joint test and integrated test time of the scientific equipment and control equipment thereof is shortened.

The general intelligent scientific equipment parallel test system 1 is realized by adopting a man-machine interaction interface and background intelligent data processing, wherein the man-machine interaction interface is responsible for configuring tested scientific equipment information, and the information comprises an RS422 port number, an Ethernet port number, an uplink control instruction function code, a downlink data parameter, historical data playback control, a test report automatic generation function and the like. The background is responsible for maintaining uplink and downlink data of each scientific device, intelligently interpreting the data, processing test reports and the like. The specific functions are as follows: configuring load identifiers, equipment numbers, equipment names, uplink and downlink data and association judgment relations; configuring an RS422 port number and an Ethernet port number; controlling the playback of the downlink data history data; the method comprises the following steps of intelligently interpreting downlink data, including automatic interpretation of upper and lower limits of parameters, automatic interpretation of the association relation between a control instruction and the downlink parameters, and automatic interpretation of the association relation of a plurality of parameters; uplink and downlink data and automatic interpretation result management; and automatically generating a test report.

In embodiment 1, in this embodiment, a tested scientific device is taken as an example of a power distribution unit of a high voltage switchgear to exemplify a test process, and first, basic information of the tested device is configured on a user interface, where the basic information includes: after communication is established, the interface communication module can receive digital quantity (such as heartbeat, health state, working mode, power on/off state, locking and unlocking state, instruction counting, software uploading state parameters) only containing important state information, engineering parameters (such as complete digital quantity information, analog quantity parameters of temperature, voltage, current and the like, software uploading complete information) containing detailed complete information and application data (such as displacement, attitude, relative angular velocity, moment, torque, etc.) containing specific parameters generated in the experimental process, Control force, etc.), the interface communication module sends the received data stream to the data storage module, and the data storage module stores the original data stream without changing the original data stream, thereby facilitating subsequent troubleshooting. Meanwhile, the interface communication module sends the data stream to the data management module, and the data management module identifies the digital quantity, the engineering parameters and the application data according to the frame header, the frame length and the verification information and analyzes the parameters contained in various data according to the interface data sheet. The intelligent interpretation module uses the parameters analyzed by the data management module and the upper and lower limits in the interface data sheet to roughly judge whether the parameters are correct or not, and simultaneously carries out intelligent interpretation according to the judgment conditions configured by the user. For example, the digital quantity of the distribution unit of the high-voltage micro-cabinet comprises the temperature of the cabinet of the distribution unit, the data management module analyzes that the temperature source code of the cabinet of the distribution unit is 8BH from the digital source code, the temperature is calculated to be 28.5 ℃ according to a formula y defined in the interface data sheet, and the temperature is automatically judged according to the conditions that the upper limit is 85 ℃ and the lower limit is-40 ℃, and the temperature is in the range and accords with the expectation. Meanwhile, according to a power supply normal criterion "((power board +12V voltage >11.5) & (power board +12V voltage <12.5)) & ((measurement and control load 28V voltage >27.5) & (measurement and control load 28V voltage <28.5)) & ((5V voltage >4.5) & (5V voltage < 5.5))", extracting a power board +12V voltage source code 0CH, a measurement and control load 28V voltage source code 1CH and a 5V voltage source code 05H from digital quantity source codes, calculating a power supply +12V voltage 11.84375V according to a formula in an interface data sheet, calculating measurement and control load 28V voltage 27.875V and 5V voltage 4.75V, and judging that the current power supply is normal if a criterion condition is met. When a certain function test is required, the instruction management module generates a data injection instruction according to information such as a load identifier, a function identifier, an instruction code and the like configured on the user interface, a complete source code of the generated data injection instruction can be displayed on the user interface, checking and subsequent troubleshooting are facilitated, meanwhile, the data storage module can store the complete instruction, the complete instruction can be used after subsequent direct loading, repeated configuration is not needed, the test time is saved, and the test efficiency is improved. During testing, the data injection instruction is sent to the tested equipment through the interface communication module, and the intelligent interpretation module performs automatic interpretation according to the criterion corresponding to the instruction code defined in the interface data sheet. For example, a power distribution unit 28V opens a control command, a user configures a load identifier 0x061 on an interface, a subsystem identifier is 0x1F, a function identifier 0x11, a command code 0x4407, and an immediate command 0x31 including an event, generates a 64-byte data injection command and sends the data injection command to a device to be tested, and an intelligent interpretation module extracts criterion information "power distribution unit 28V enable state" from an interface data sheet according to the subsystem identifier, the function identifier, and the command code: 11b, a power distribution unit data injection instruction receiving count +1 and a power distribution unit data injection instruction execution count + 1', corresponding fields are extracted from received digital quantity, the instruction receiving and execution conditions of the tested equipment are automatically judged, in order to prevent misjudgment caused by sending and receiving time delay, 5 packets of digital quantity information are continuously judged, correct information is not obtained, and the instruction execution is considered to be failed. After the test is finished, a Word-form test report is automatically generated, the front cover of the test report and the content of each chapter are automatically generated, the test condition of a high micro cabinet power distribution unit is taken as a chapter title, the title in section 1 is the receiving condition of various data, the digital quantity, the engineering parameters and the receiving packet number of application data are classified and counted, whether the packet serial numbers are continuous or not is given in a list form, whether the error condition is verified or not is given, the title in section 2 is an instruction and the execution condition thereof, which instruction is tested at what time is given, whether the execution is correct or not is wrongly given, the original data packet serial number is given, the title in section 3 is the intelligent interpretation condition, the criterion serial number configured on a user interface and the intelligent interpretation result thereof are given, and the error data is given to the original criterion packet serial number.

In embodiment 2, in this embodiment, a test process is exemplified by taking a tested scientific device as a main control unit of a fluid physical laboratory cabinet, and first, basic information of the tested device is configured on a user interface, including: after the communication is established, the interface communication module can receive digital quantity (such as control panel heartbeat state, alarm parameter, working state, ethernet, RS422 and RS232 communication state, reset count, instruction count and each peripheral switch state) only containing important state information, engineering parameters (such as complete digital quantity information, analog quantity parameters of temperature, voltage, current and the like, IP addresses, software uploading complete information and image processing information) containing detailed complete information, and application data (such as image data) containing specific parameters generated in the experimental process, spectrometer data, etc.), the interface communication module sends the received data stream to the data storage module, and the data storage module stores the original data stream without changing the original data stream, thereby facilitating subsequent troubleshooting. Meanwhile, the interface communication module sends the data stream to the data management module, and the data management module identifies the digital quantity, the engineering parameters and the application data according to the frame header, the frame length and the verification information and analyzes the parameters contained in various data according to the interface data sheet. The intelligent interpretation module uses the parameters analyzed by the data management module and the upper and lower limits in the interface data sheet to roughly judge whether the parameters are correct or not, and simultaneously carries out intelligent interpretation according to the judgment conditions configured by the user. For example, the digital quantity of the main control unit of the fluid cabinet includes 12V voltage of an I7 control board, the data management module analyzes that the source code of the 12V voltage of the I7 control board is B8H from the digital source code, the 12V voltage of the I7 control board is calculated to be 11.94V according to the formula y defined in the interface data sheet (x 16) 0.0005 8.108239, and the voltage of the I7 control board is automatically determined according to the upper limit of 14V and the lower limit of 10V, so that the voltage of the I7 control board is in the range and meets the expectation. And meanwhile, according to the temperature state criterion of the main control unit of the fluid cabinet (LDV probe shell temperature <115 ℃) & (white light source shell temperature <115 ℃) & (laser probe temperature <75 ℃) & (thermal imager probe temperature <75 ℃) "), extracting a probe shell temperature source code 19H, a white light source shell temperature 19H, a laser probe temperature 1AH and a thermal imager probe temperature 19H from digital quantity source codes, calculating to meet the criterion condition according to an interface data sheet, and judging that the current temperature is normal. When a certain function test is required, the instruction management module generates a data injection instruction according to information such as a load identifier, a function identifier, an instruction code and the like configured on the user interface, a complete source code of the generated data injection instruction can be displayed on the user interface, checking and subsequent troubleshooting are facilitated, meanwhile, the data storage module can store the complete instruction, the complete instruction can be used after subsequent direct loading, repeated configuration is not needed, the test time is saved, and the test efficiency is improved. During testing, the data injection instruction is sent to the tested equipment through the interface communication module, and the intelligent interpretation module automatically interprets according to the criterion corresponding to the instruction code defined in the interface data sheet. For example, when the LDV displacement table is opened, the user configures a load identifier 0x06A, a subsystem identifier 0x3F, a function identifier 0x1142, and a command code 0x76 on the interface, and includes an event immediate command 0x31, generates a 64-byte data injection command, and sends the data injection command to the device to be tested, and the intelligent interpretation module extracts criterion information "LDV displacement table 24V on-off state" from the interface data sheet according to the subsystem identifier, the function identifier, and the command code: 1b, I7 control board and LDV ethernet communication status: 0b, the communication state of the front control board and the LDV displacement table RS 232: 0 b', extracting corresponding fields from the received digital quantity, automatically judging the instruction receiving and executing conditions of the tested equipment, and continuously judging 5 packets of digital quantity information in order to prevent misjudgment caused by sending and receiving time delay, wherein correct information is not obtained, namely the instruction execution is considered to be failed. After the test is finished, a Word-form test report is automatically generated, the front cover of the test report and the content of each chapter are automatically generated, the test condition of a main control unit of the fluid cabinet is taken as a chapter title, the 1 st section of the test report is the receiving condition of various data, the digital quantity, the engineering parameters and the receiving packet number of application data are classified and counted, whether the packet serial numbers are continuous or not is given in a list form, whether the error condition is verified or not is given, the 2 nd section of the test report is an instruction and the execution condition thereof, which instruction is tested at what time is given, whether the execution is correct or not is wrongly given, the original data packet serial number is given by the 3 rd section of the test report as the intelligent interpretation condition, the criterion serial number configured on a user interface and the intelligent interpretation result thereof are given, and the error data is given by the packet serial number of the original criterion.

Preferably, in any of the above embodiments, the basic information includes:

Preferably, in any of the above embodiments, the feedback data comprises:

digital quantities, engineering data, and application data.

Preferably, in any of the above embodiments, further comprising:

As shown in fig. 2, an intelligent scientific equipment testing method includes:

step 1, an instruction management module 13 generates a control instruction according to basic information of a tested scientific device and sends the control instruction to an interface communication module 14;

step 2, the interface communication module 14 sends the control instruction to the scientific equipment to be tested, receives feedback data of the scientific equipment to be tested, and sends the feedback data to the data management module 11;

step 3, the data management module 11 performs classification analysis on the feedback data to obtain an analysis result, and sends the analysis result to the user interface 12;

and 4, displaying the analysis result by the user interface 12.

Preferably, in any of the above embodiments, the basic information includes:

Preferably, in any of the above embodiments, the feedback data comprises:

digital quantities, engineering data, and application data.

Preferably, in any of the above embodiments, further comprising:

In some possible embodiments, the interface communication module 14 may implement embedded testing, that is, the testing system 1 may be continuously updated in research and development and test processes to deal with different scientific devices to be tested, and the problem that the number of control devices is far smaller than the number of scientific devices to be tested may be effectively solved by the testing system 1, in addition, the testing content is finally integrated and a testing control instruction is generated, so as to finally achieve an effect of low cost.

The reader should understand that in the description of this specification, reference to the description of the terms "one embodiment," "some embodiments," "an example," "a specific example," or "some examples," etc., means that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the invention. In this specification, the schematic representations of the terms used above are not necessarily intended to refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples. Furthermore, various embodiments or examples and features of different embodiments or examples described in this specification can be combined and combined by one skilled in the art without contradiction.

In the several embodiments provided in the present application, it should be understood that the disclosed apparatus and method may be implemented in other ways. For example, the above-described method embodiments are merely illustrative, and for example, the division of steps into only one logical functional division may be implemented in practice in another way, for example, multiple steps may be combined or integrated into another step, or some features may be omitted, or not implemented.

The above method, if implemented in the form of software functional units and sold or used as a stand-alone product, may be stored in a computer readable storage medium. Based on such understanding, the technical solution of the present invention essentially or partially contributes to the prior art, or all or part of the technical solution can be embodied in the form of a software product stored in a storage medium and including instructions for causing a computer device (which may be a personal computer, a server, or a network device) to execute all or part of the steps of the method according to the embodiments of the present invention. And the aforementioned storage medium includes: various media capable of storing program codes, such as a usb disk, a removable hard disk, a Read-only memory (ROM), a Random Access Memory (RAM), a magnetic disk, or an optical disk.

While the invention has been described with reference to specific embodiments, it will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. Therefore, the protection scope of the present invention shall be subject to the protection scope of the claims.

Claims

1. An intelligent scientific equipment testing system, comprising: the system comprises a data management module, a user interface, an instruction management module and an interface communication module;

the instruction management module is used for generating a test control instruction according to basic information of the tested scientific equipment and sending the test control instruction to the interface communication module;

the interface communication module is used for sending the test control instruction to the tested scientific equipment, receiving feedback data of the tested scientific equipment and sending the feedback data to the data management module;

the user interface is used for displaying the analysis result.

2. The intelligent scientific equipment test system of claim 1, wherein the basic information comprises:

3. The intelligent scientific equipment test system of claim 1 wherein the feedback data comprises:

digital quantities, engineering data, and application data.

4. The intelligent scientific equipment test system of claim 1, further comprising:

5. The intelligent scientific equipment test system of claim 4, further comprising:

and the data storage module is used for storing the test control instruction, the feedback data and the basic information.

6. An intelligent scientific equipment testing method is characterized by comprising the following steps:

step 1, an instruction management module generates a test control instruction according to basic information of tested scientific equipment and sends the test control instruction to an interface communication module;

step 2, the interface communication module sends the test control instruction to the tested scientific equipment, receives feedback data of the tested scientific equipment and sends the feedback data to a data management module;

and 4, displaying the analysis result by the user interface.

7. The intelligent scientific equipment testing method of claim 6, wherein the basic information comprises:

8. The intelligent scientific equipment testing method of claim 6, wherein the feedback data comprises:

digital quantities, engineering data, and application data.

9. A medium having stored therein instructions which, when read by a computer, cause the computer to perform an integrated wireless optical communication, positioning, energy storage and transmission method according to any one of claims 6 to 8.

10. A device comprising the storage medium of claim 9, a processor to execute instructions within the storage medium.