阅读说明：本技术 一种红外导引头伺服指标测试系统 (Servo index test system of infrared seeker ) 是由 翟庆胜 霍明磊 宫志文 曹彦虎 刘士鑫 洪铮 张子鑫 王冬 王怀野 郭晓星 于 2020-12-23 设计创作，主要内容包括：本发明公开了一种红外导引头伺服指标测试系统,包括：导引头安装工装,用于引导待测试红外导引头安装至仿真测试台；仿真测试台,用于装载待测试红外导引头；根据接收到的测试指令,模拟红外导引头在炸弹上不同的工作环境,对待测试红外导引头进行测试；数据采集卡,用于在测试过程中,对待测试红外导引头进行数据采集；工控机,用于响应用户的测试项目选择操作,根据用户的测试项目选择操作生成相应的测试指令,将测试指令发送至仿真测试台；接收数据采集卡的采集数据,对采集数据进行处理,输出伺服指标测试结果,并显示。本发明可以全面测试红外导引头伺服系统的各项性能指标,同时可以智能处理试验数据,同时还可以自动给出判断结果。(The invention discloses a system for testing the servo index of an infrared seeker, which comprises: the seeker mounting tool is used for guiding the infrared seeker to be tested to be mounted on the simulation test board; the simulation test bench is used for loading the infrared seeker to be tested; simulating different working environments of the infrared seeker on the bomb according to the received test instruction, and testing the infrared seeker to be tested; the data acquisition card is used for acquiring data of the infrared seeker to be tested in the test process; the industrial personal computer is used for responding to the test item selection operation of the user, generating a corresponding test instruction according to the test item selection operation of the user, and sending the test instruction to the simulation test bench; and receiving the acquired data of the data acquisition card, processing the acquired data, outputting a servo index test result and displaying the servo index test result. The invention can comprehensively test various performance indexes of the infrared seeker servo system, can intelligently process test data and can automatically give out a judgment result.)

1. An infrared seeker servo index testing system is characterized by comprising: the simulation test bench, the seeker mounting tool, the industrial personal computer and the data acquisition card are arranged;

the seeker mounting tool is used for guiding the infrared seeker to be tested to be mounted on the simulation test board;

the simulation test bench is used for loading the infrared seeker to be tested; simulating different working environments of the infrared seeker on the bomb according to the received test instruction, and testing the infrared seeker to be tested;

the data acquisition card is used for acquiring data of the infrared seeker to be tested in the test process;

the industrial personal computer is used for responding to the test item selection operation of the user, generating a corresponding test instruction according to the test item selection operation of the user, and sending the test instruction to the simulation test bench; and receiving the acquired data of the data acquisition card, processing the acquired data, outputting a servo index test result and displaying the servo index test result.

2. The infrared seeker servo index testing system of claim 1, wherein the simulation test stand comprises: the infrared target simulator comprises a table body, an infrared target simulator and a control cabinet;

the infrared seeker to be tested is arranged on the table body under the guidance of the seeker mounting tool;

the infrared target simulator is used for simulating an infrared target so that the infrared seeker to be tested can lock the infrared target simulator during testing;

and the control cabinet is used for selecting a corresponding working mode according to a test instruction generated by the industrial personal computer, and setting parameters according to the selected working mode, so that the platform body completes corresponding test actions according to the set parameters, and the test of the infrared seeker to be tested is realized.

3. The infrared seeker servo index testing system of claim 1, further comprising: an input device; wherein, input device is connected with the industrial computer, and the user passes through input device and realizes test item selection operation, and input device includes: a keyboard and a mouse.

4. The infrared seeker servo index testing system of claim 1, further comprising: a power supply; the power supply is connected with the infrared seeker to be tested through a slip ring cable, and 28.0V voltage is provided for the infrared seeker to be tested.

5. The infrared seeker servo index testing system of claim 1, wherein the industrial personal computer is further configured to:

sending a version number reading instruction to an infrared seeker to be tested; the infrared seeker to be tested feeds back version information after receiving a version number reading instruction;

and judging whether the program version programmed in the infrared seeker to be tested is correct or not according to the version information fed back by the infrared seeker to be tested.

6. The infrared seeker servo index testing system of claim 2, wherein the industrial personal computer, when generating corresponding test instructions according to user test item selection operations, comprises: according to the test item selection operation of a user, a tracking center test instruction, a gyro deviation test instruction, a decoupling test instruction and a sight line precision test instruction are generated.

7. The infrared seeker servo index testing system of claim 6, wherein the industrial personal computer is configured to:

responding to the test item selection operation of a user, and generating a tracking center test instruction; wherein, the "tracking center" test instruction comprises: a 'detection stop' instruction, a 'search center' instruction, a 'lock opening' instruction and a 'lock adjusting' instruction;

sequentially sending a detection stop command, a search center command and an opening locking command to the simulation test bench; the simulation test bench executes corresponding test operation according to a detection stop command, a search center command and an opening locking command, controls the infrared seeker to be tested to lock the center of the infrared target simulator and feeds back a locking result;

judging whether fine adjustment is needed according to a locking result fed back by the simulation test board; when the fine tuning is determined to be needed, sending an adjusting and locking instruction to the simulation test bench; the simulation test bench adjusts the infrared seeker to be tested according to the adjusting and locking command;

receiving data of a yaw frame and a pitching frame of an infrared seeker to be tested; the data of a yaw frame and a pitching frame of the infrared seeker to be tested are acquired by a data acquisition card;

calculating to obtain a yaw angle and a pitch angle of the infrared seeker to be tested according to the data of the yaw frame and the pitch frame of the infrared seeker to be tested;

according to the yaw angle and the pitch angle, completing the tracking center test of the infrared seeker to be tested; wherein, when the yaw angle satisfies-0.5 to + 0.5 degrees and the pitch angle satisfies +24.5 to +25.5 degrees, the test result of the tracking center is determined to be qualified.

8. The infrared seeker servo index testing system of claim 6, wherein the industrial personal computer is configured to:

responding to the selection operation of the test items of the user, and generating a 'gyro deviation' test instruction; wherein, the 'gyro deviation' test instruction comprises: a 'detection stop' instruction, a 'tracking return-to-zero' instruction, a 'start test' instruction, an 'acquisition deviation' instruction, a 'clear compensation' instruction and a 'compensation deviation' instruction;

sequentially sending a detection stopping command and a tracking zeroing command to a simulation test bench; the simulation test bench executes corresponding test operation according to the detection stop command and the tracking return-to-zero command, controls the infrared seeker to be tested to enter a preset working state, and feeds back working state information;

when the infrared seeker to be tested is determined to enter a preset working state according to the working state information fed back by the simulation test board, sending a 'test starting' instruction to the simulation test board; the simulation test bench executes corresponding test operation according to the test starting instruction and controls the infrared seeker to be tested to carry out gyro deviation test;

receiving a gyro deviation within a 100s test time; wherein, the gyro deviation is acquired by a data acquisition card;

according to the gyro deviation within the test time of 100s, completing the gyro deviation test of the infrared seeker to be tested; if the absolute value of the gyro deviation within 100s does not exceed 0.2 degrees, ending the gyro deviation test; and if not, sequentially sending a deviation acquiring command, a compensation clearing command and a deviation compensating command to the simulation test platform, and the simulation test platform realizes the compensation of the gyroscope according to the deviation acquiring command, the compensation clearing command and the deviation compensating command until the absolute value of the gyroscope deviation within 100s is not more than 0.2 DEG, and finishing the gyroscope deviation test.

9. The infrared seeker servo index testing system of claim 6, wherein the industrial personal computer is configured to:

responding to the selection operation of the test items of the user and generating a decoupling test instruction; wherein the "decoupled" test instructions comprise: a 'detection stop' instruction, a 'tracking return-to-zero' instruction and a 'start test' instruction;

sequentially sending a detection stopping command and a tracking zeroing command to a simulation test bench; the infrared seeker to be tested is installed in a yaw direction or a pitch direction, the simulation test bench executes corresponding test operation according to a detection stop command and a tracking zero command, the infrared seeker to be tested is controlled to enter a preset working state, an outer shaft of the simulation test bench is started at the frequency of 2 degrees and 3HZ, and working state information is fed back;

when the infrared seeker to be tested is determined to enter a preset working state according to the working state information fed back by the simulation test platform, and an outer shaft of the simulation test platform is started at the frequency of 2 degrees and 3HZ, sending a 'test starting' instruction to the simulation test platform; the simulation test bench executes corresponding test operation according to the test starting instruction and controls the infrared seeker to be tested to perform decoupling test;

receiving a decoupling test result; the decoupling test result is acquired by a data acquisition card;

analyzing the decoupling test result, determining a peak value of a curve, and completing the decoupling test of the infrared seeker to be tested; and determining that the decoupling test is qualified if the peak value of the curve is less than or equal to 5 percent/4 multiplied by 100 percent.

10. The infrared seeker servo index testing system of claim 6, wherein the industrial personal computer is configured to:

responding to the selection operation of the test items of the user, and generating a 'sight line precision' test instruction; wherein, the 'sight line precision' test instruction comprises: a 'detection stop' instruction, a 'search center' instruction, a 'lock opening' instruction and a 'test starting' instruction;

sequentially sending a detection stop command, a search center command and an opening locking command to the simulation test bench; the method comprises the following steps that when an infrared seeker to be tested is installed, the yaw direction or the pitch direction is selected, a simulation test bench executes corresponding test operation according to a detection stop command, a search center command and an opening locking command, controls the infrared seeker to be tested to lock the center of an infrared target simulator, and simultaneously generates a +/-15/S control command, a +/-0.5/S control command, a +/-0/S control command, a +/-1/S control command and a +/-2/S control command;

after the turntable is started, sending a 'test starting' instruction; the simulation test bench executes corresponding test operation according to a test starting instruction, and controls the rotary table to rotate at the speed of +/-15 degrees/S ', +/-0.5 degrees/S', +/-0 degrees/S ', +/-1 degrees/S' and +/-2 degrees/S in sequence, so that the sight line precision test of the infrared seeker to be tested is realized;

receiving a view field precision test result; wherein, the field precision test result is acquired by a data acquisition card;

and analyzing the field precision test result, determining a curve peak value and a pixel tracking standard deviation, and completing the 'sight line precision' test of the infrared seeker to be tested.

Technical Field

The invention belongs to the technical field of accurate guided weapons, and particularly relates to an infrared seeker servo index testing system.

Background

The infrared seeker is a core device which is used for detecting and tracking a target and generating attitude adjustment parameters on a guided weapon. The guidance of the guided munition can be achieved in a decisive manner. The servo system is used as an important component of the infrared seeker, various indexes of the servo system directly influence the ability of the seeker to accurately track the target, and how to actually and quickly test the servo performance index of one infrared seeker is particularly important. The infrared seeker servo index testing system is mainly used for detecting and troubleshooting the seeker independently and researching, developing and upgrading the seeker servo system after the infrared seeker is found to be in fault in the infrared seeker servo index debugging, seeker single-machine testing or whole bullet combination testing process.

The traditional seeker servo index testing system is complex in operation and not intelligent enough during continuous testing, manual calculation is needed after test data are collected, the calculation precision is low, data are easy to store and confuse during repeated testing, and the later data analysis and use are not facilitated. In addition, the traditional test method has single test item and insufficient precision, partial items can only roughly simulate the working environment of the seeker, and the test items can be tested completely only by rolling a plurality of test fields, so that the servo performance test of the seeker is incomplete and inaccurate.

Disclosure of Invention

The technical problem of the invention is solved: the infrared seeker servo index testing system overcomes the defects of the prior art, can comprehensively test various performance indexes of the infrared seeker servo system, can accurately test core indexes of the seeker, can intelligently process test data, and can automatically give a judgment result.

In order to solve the technical problem, the invention discloses an infrared seeker servo index testing system, which comprises: the simulation test bench, the seeker mounting tool, the industrial personal computer and the data acquisition card are arranged;

the seeker mounting tool is used for guiding the infrared seeker to be tested to be mounted on the simulation test board;

the simulation test bench is used for loading the infrared seeker to be tested; simulating different working environments of the infrared seeker on the bomb according to the received test instruction, and testing the infrared seeker to be tested;

the data acquisition card is used for acquiring data of the infrared seeker to be tested in the test process;

the industrial personal computer is used for responding to the test item selection operation of the user, generating a corresponding test instruction according to the test item selection operation of the user, and sending the test instruction to the simulation test bench; and receiving the acquired data of the data acquisition card, processing the acquired data, outputting a servo index test result and displaying the servo index test result.

In the above-mentioned infrared seeker servo index test system, the simulation test bench includes: the infrared target simulator comprises a table body, an infrared target simulator and a control cabinet;

the infrared seeker to be tested is arranged on the table body under the guidance of the seeker mounting tool;

the infrared target simulator is used for simulating an infrared target so that the infrared seeker to be tested can lock the infrared target simulator during testing;

and the control cabinet is used for selecting a corresponding working mode according to a test instruction generated by the industrial personal computer, and setting parameters according to the selected working mode, so that the platform body completes corresponding test actions according to the set parameters, and the test of the infrared seeker to be tested is realized.

In the above-mentioned infrared seeker servo index test system, still include: an input device; wherein, input device is connected with the industrial computer, and the user passes through input device and realizes test item selection operation, and input device includes: a keyboard and a mouse.

In the above-mentioned infrared seeker servo index test system, still include: a power supply; the power supply is connected with the infrared seeker to be tested through a slip ring cable, and 28.0V voltage is provided for the infrared seeker to be tested.

In the above-mentioned infrared seeker servo index test system, the industrial computer still is used for:

sending a version number reading instruction to an infrared seeker to be tested; the infrared seeker to be tested feeds back version information after receiving a version number reading instruction;

and judging whether the program version programmed in the infrared seeker to be tested is correct or not according to the version information fed back by the infrared seeker to be tested.

In the above-mentioned infrared seeker servo index test system, when the industrial computer generates corresponding test instruction according to user's test item selection operation, include: according to the test item selection operation of a user, a tracking center test instruction, a gyro deviation test instruction, a decoupling test instruction and a sight line precision test instruction are generated.

In the above-mentioned infrared seeker servo index test system, the industrial computer is used for:

responding to the test item selection operation of a user, and generating a tracking center test instruction; wherein, the "tracking center" test instruction comprises: a 'detection stop' instruction, a 'search center' instruction, a 'lock opening' instruction and a 'lock adjusting' instruction;

sequentially sending a detection stop command, a search center command and an opening locking command to the simulation test bench; the simulation test bench executes corresponding test operation according to a detection stop command, a search center command and an opening locking command, controls the infrared seeker to be tested to lock the center of the infrared target simulator and feeds back a locking result;

judging whether fine adjustment is needed according to a locking result fed back by the simulation test board; when the fine tuning is determined to be needed, sending an adjusting and locking instruction to the simulation test bench; the simulation test bench adjusts the infrared seeker to be tested according to the adjusting and locking command;

receiving data of a yaw frame and a pitching frame of an infrared seeker to be tested; the data of a yaw frame and a pitching frame of the infrared seeker to be tested are acquired by a data acquisition card;

calculating to obtain a yaw angle and a pitch angle of the infrared seeker to be tested according to the data of the yaw frame and the pitch frame of the infrared seeker to be tested;

according to the yaw angle and the pitch angle, completing the tracking center test of the infrared seeker to be tested; wherein, when the yaw angle satisfies-0.5 to + 0.5 degrees and the pitch angle satisfies +24.5 to +25.5 degrees, the test result of the tracking center is determined to be qualified.

In the above-mentioned infrared seeker servo index test system, the industrial computer is used for:

responding to the selection operation of the test items of the user, and generating a 'gyro deviation' test instruction; wherein, the 'gyro deviation' test instruction comprises: a 'detection stop' instruction, a 'tracking return-to-zero' instruction, a 'start test' instruction, an 'acquisition deviation' instruction, a 'clear compensation' instruction and a 'compensation deviation' instruction;

sequentially sending a detection stopping command and a tracking zeroing command to a simulation test bench; the simulation test bench executes corresponding test operation according to the detection stop command and the tracking return-to-zero command, controls the infrared seeker to be tested to enter a preset working state, and feeds back working state information;

when the infrared seeker to be tested is determined to enter a preset working state according to the working state information fed back by the simulation test board, sending a 'test starting' instruction to the simulation test board; the simulation test bench executes corresponding test operation according to the test starting instruction and controls the infrared seeker to be tested to carry out gyro deviation test;

receiving a gyro deviation within a 100s test time; wherein, the gyro deviation is acquired by a data acquisition card;

according to the gyro deviation within the test time of 100s, completing the gyro deviation test of the infrared seeker to be tested; if the absolute value of the gyro deviation within 100s does not exceed 0.2 degrees, ending the gyro deviation test; and if not, sequentially sending a deviation acquiring command, a compensation clearing command and a deviation compensating command to the simulation test platform, and the simulation test platform realizes the compensation of the gyroscope according to the deviation acquiring command, the compensation clearing command and the deviation compensating command until the absolute value of the gyroscope deviation within 100s is not more than 0.2 DEG, and finishing the gyroscope deviation test.

In the above-mentioned infrared seeker servo index test system, the industrial computer is used for:

responding to the selection operation of the test items of the user and generating a decoupling test instruction; wherein the "decoupled" test instructions comprise: a 'detection stop' instruction, a 'tracking return-to-zero' instruction and a 'start test' instruction;

sequentially sending a detection stopping command and a tracking zeroing command to a simulation test bench; the infrared seeker to be tested is installed in a yaw direction or a pitch direction, the simulation test bench executes corresponding test operation according to a detection stop command and a tracking zero command, the infrared seeker to be tested is controlled to enter a preset working state, an outer shaft of the simulation test bench is started at the frequency of 2 degrees and 3HZ, and working state information is fed back;

when the infrared seeker to be tested is determined to enter a preset working state according to the working state information fed back by the simulation test platform, and an outer shaft of the simulation test platform is started at the frequency of 2 degrees and 3HZ, sending a 'test starting' instruction to the simulation test platform; the simulation test bench executes corresponding test operation according to the test starting instruction and controls the infrared seeker to be tested to perform decoupling test;

receiving a decoupling test result; the decoupling test result is acquired by a data acquisition card;

analyzing the decoupling test result, determining a peak value of a curve, and completing the decoupling test of the infrared seeker to be tested; and determining that the decoupling test is qualified if the peak value of the curve is less than or equal to 5 percent/4 multiplied by 100 percent.

In the above-mentioned infrared seeker servo index test system, the industrial computer is used for:

responding to the selection operation of the test items of the user, and generating a 'sight line precision' test instruction; wherein, the 'sight line precision' test instruction comprises: a 'detection stop' instruction, a 'search center' instruction, a 'lock opening' instruction and a 'test starting' instruction;

sequentially sending a detection stop command, a search center command and an opening locking command to the simulation test bench; the method comprises the following steps that when an infrared seeker to be tested is installed, the yaw direction or the pitch direction is selected, a simulation test bench executes corresponding test operation according to a detection stop command, a search center command and an opening locking command, controls the infrared seeker to be tested to lock the center of an infrared target simulator, and simultaneously generates a +/-15/S control command, a +/-0.5/S control command, a +/-0/S control command, a +/-1/S control command and a +/-2/S control command;

after the turntable is started, sending a 'test starting' instruction; the simulation test bench executes corresponding test operation according to a test starting instruction, and controls the rotary table to rotate at the speed of +/-15 degrees/S ', +/-0.5 degrees/S', +/-0 degrees/S ', +/-1 degrees/S' and +/-2 degrees/S in sequence, so that the sight line precision test of the infrared seeker to be tested is realized;

receiving a view field precision test result; wherein, the field precision test result is acquired by a data acquisition card;

and analyzing the field precision test result, determining a curve peak value and a pixel tracking standard deviation, and completing the 'sight line precision' test of the infrared seeker to be tested.

The invention has the following advantages:

(1) the test content is richer: the tracking center test can read the frame zero position of the infrared seeker; the performance of the seeker gyroscope can be determined through the gyroscope deviation test; the "decoupling" test may determine that the seeker is isolated from outside interference; the 'sight line precision' test comprises a plurality of rate test items of plus or minus 0 degree/S, plus or minus 0.5 degree/S, plus or minus 1 degree/S, plus or minus 2 degree/S and plus or minus 15 degree/S, and can comprehensively reflect index conformity conditions of the seeker under different rates.

(2) The test process is simpler: in the past, the tracking center needs to manually input the angle information of the zero position of the infrared seeker, and the invention can directly send a zero position angle instruction; in the past, the data processing link needs manual calculation, the invention can realize automatic data acquisition and processing, and directly display the test result on an industrial personal computer, thereby simplifying the test flow and improving the test speed; in addition, when different projects are tested, the test can be completed only by sending different test instructions, and the operation is simple and quick.

(3) The test result is more accurate: in the prior art, test data needs to be manually acquired and then is mapped, calculated and interpreted through Matlab.

(4) The test industrial personal computer is more intelligent: the current operation item is displayed in real time in the testing process, a user can independently select a testing item according to requirements, parameters can be automatically changed according to the selected testing item, unnecessary keys and input boxes are automatically shielded, the possibility of misoperation is greatly avoided, and the usability of software is improved.

Drawings

Fig. 1 is a block diagram of a system for testing a servo index of an infrared seeker according to an embodiment of the invention.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the embodiments of the present invention will be described in detail with reference to the accompanying drawings.

One of the core ideas of the invention is that: the invention discloses an infrared seeker servo index testing system which mainly comprises a simulation test board, a seeker mounting tool, an industrial personal computer, a data acquisition card and the like, wherein the simulation test board, the data acquisition card and the industrial personal computer work cooperatively to finish instruction sending, data acquisition, data processing and result output, and further test of different test items is realized.

The simulation test bench is an important device of the whole infrared seeker servo index test system, and mainly comprises a bench body and a control cabinet: the table body is divided into an inner shaft and an outer shaft, the inner shaft has two working modes of position and swing, the outer shaft has three working modes of position, speed and swing, the control cabinet selects the working modes of the inner shaft and the outer shaft according to test items and sends executable control instructions to the table body so as to test various performance indexes of the infrared seeker.

The industrial personal computer is an indispensable tool for completing test work and comprises four test items of tracking center test, gyro deviation test, decoupling test and sight line precision test. The tracking center test reads the zero feedback information of the infrared seeker frame by locking the center of the infrared target simulator after the simulation test board enables zero searching; the 'gyro deviation' test is carried out for 100s after the simulation test bench enables zero searching, the gyro zero drift value is read, the industrial personal computer automatically judges whether the gyro zero drift value is out of tolerance, and if the gyro zero drift value is out of tolerance, the industrial personal computer automatically calculates a compensation value and compensates the gyro zero drift value; the decoupling test is carried out at the frequency of 2 DEG and 3HZ in the simulation test bench, the test industrial personal computer automatically takes test data and draws a curve, and the test result is displayed in a prompt dialog box; the 'sight accuracy' test is used for determining the maximum sight tracking angular rate, the sight angle tracking accuracy and the sight angular speed tracking accuracy of the seeker, the industrial personal computer automatically acquires and processes test data, and a test result is directly displayed in the prompt dialog box. The infrared seeker can select test items according to requirements after being normally powered on, the industrial personal computer can select instructions corresponding to the items to perform testing, all data in the testing process are stored in a text format, and the infrared seeker is convenient to check and use later.

Referring to fig. 1, in the present embodiment, the infrared seeker servo index testing system includes: the device comprises a simulation test bench, a seeker mounting tool, an industrial personal computer and a data acquisition card. The seeker mounting tool is used for guiding the infrared seeker to be tested to be mounted on the simulation test bench. The simulation test bench is used for loading the infrared seeker to be tested; and simulating different working environments of the infrared seeker on the bomb according to the received test instruction, and testing the infrared seeker to be tested. And the data acquisition card is used for acquiring data of the infrared seeker to be tested in the test process. The industrial personal computer is used for responding to the test item selection operation of the user, generating a corresponding test instruction according to the test item selection operation of the user, and sending the test instruction to the simulation test bench; and receiving the acquired data of the data acquisition card, processing the acquired data, outputting a servo index test result and displaying the servo index test result.

Preferably, the simulation test bench may specifically include: the infrared target simulator comprises a table body, an infrared target simulator and a control cabinet. The infrared seeker to be tested is arranged on the table body under the guidance of the seeker mounting tool. And the infrared target simulator is used for simulating an infrared target so that the infrared seeker to be tested locks the infrared target simulator during testing. And the control cabinet is used for selecting a corresponding working mode according to a test instruction generated by the industrial personal computer, and setting parameters according to the selected working mode, so that the platform body completes corresponding test actions according to the set parameters, and the test of the infrared seeker to be tested is realized.

In this embodiment, the infrared seeker servo index testing system may further include: an input device. Wherein, input device is connected with the industrial computer, and the user realizes test item selection operation through input device, and input device includes but not limited to: a keyboard and a mouse.

In this embodiment, the infrared seeker servo index testing system may further include: and (4) a power supply. The power supply is connected with the infrared seeker to be tested through a slip ring cable, and 28.0V voltage is provided for the infrared seeker to be tested.

In this embodiment, the industrial computer can also be used for: sending a version number reading instruction to an infrared seeker to be tested; and after receiving the version number reading instruction, the infrared seeker to be tested feeds back version information. And judging whether the program version programmed in the infrared seeker to be tested is correct or not according to the version information fed back by the infrared seeker to be tested.

In this embodiment, the infrared seeker servo index testing system can realize testing items such as a "tracking center" test, a "gyro deviation" test, a "decoupling" test, a "line of sight accuracy" test and the like based on an industrial personal computer. That is, when the industrial personal computer generates a corresponding test instruction according to the test item selection operation of the user, the method includes: according to the test item selection operation of a user, a tracking center test instruction, a gyro deviation test instruction, a decoupling test instruction and a sight line precision test instruction are generated.

Tracking center test

In this embodiment, the specific flow of the "tracking center" test may be as follows: the industrial personal computer responds to the test item selection operation of the user and generates a tracking center test instruction; wherein, the "tracking center" test instruction comprises: the system comprises a detection stop command, a search center command, an unlocking command and an adjusting locking command. The industrial personal computer sequentially sends a detection stop command, a search center command and an opening locking command to the simulation test platform. The simulation test bench executes corresponding test operation according to the detection stop command, the search center command and the opening locking command, controls the infrared seeker to be tested to lock the center of the infrared target simulator, and feeds back a locking result. The industrial personal computer judges whether fine adjustment is needed or not according to a locking result fed back by the simulation test board; when the fine tuning is determined to be needed, an adjusting locking instruction is sent to the simulation test bench. And the simulation test bench adjusts the infrared seeker to be tested according to the adjusting and locking command. The industrial personal computer receives data of a yaw frame and a pitching frame of the infrared seeker to be tested; the data of the yaw frame and the pitching frame of the infrared seeker to be tested are acquired by a data acquisition card. The industrial personal computer calculates and obtains the yaw angle and the pitch angle of the infrared seeker to be tested according to the data of the yaw frame and the pitch frame of the infrared seeker to be tested; and completing the tracking center test of the infrared seeker to be tested according to the yaw angle and the pitch angle. As shown in table 1, when the yaw angle satisfies-0.5 ° and the pitch angle satisfies +24.5 ° -25.5 °, the "tracking center" test result is determined to be qualified.

Serial number	Direction	Instructions	Basis of judgment
				1	Yaw	Zero control and stable locking center of simulation test bench	﹣0.5°～﹢0.5°
2	Pitching	Zero control and stable locking center of simulation test bench	+24.5°～+25.5°

TABLE 1 tracking center judgment reference table

"Gyro bias" test

In this embodiment, a specific flow of the "gyro deviation" test may be as follows: the industrial personal computer responds to the test item selection operation of the user and generates a 'gyro deviation' test instruction; wherein, the 'gyro deviation' test instruction comprises: the "detect stop" instruction, the "track return to zero" instruction, the "start test" instruction, the "get offset" instruction, the "clear offset" instruction, and the "offset" instruction. And the industrial personal computer sequentially sends the detection stop command and the tracking return-to-zero command to the simulation test board. The simulation test bench executes corresponding test operation according to the detection stop command and the tracking return-to-zero command, controls the infrared seeker to be tested to enter a preset working state, and feeds back working state information. And after the infrared seeker to be tested is determined to enter the preset working state according to the working state information fed back by the simulation test platform, the industrial personal computer sends a test starting command to the simulation test platform. The simulation test bench executes corresponding test operation according to the test starting instruction and controls the infrared seeker to be tested to carry out gyro deviation test. The industrial personal computer receives the gyro deviation within the test time of 100 s; wherein, the gyro deviation is acquired by a data acquisition card. And the industrial personal computer completes the 'gyro deviation' test on the infrared seeker to be tested according to the gyro deviation within the test time of 100 s. If the absolute value of the gyro deviation within 100s does not exceed 0.2 degrees, ending the gyro deviation test; and if not, sequentially sending a deviation acquiring command, a compensation clearing command and a deviation compensating command to the simulation test platform, and the simulation test platform realizes the compensation of the gyroscope according to the deviation acquiring command, the compensation clearing command and the deviation compensating command until the absolute value of the gyroscope deviation within 100s is not more than 0.2 DEG, and finishing the gyroscope deviation test.

"decoupling" testing

In this embodiment, the specific flow of the "decoupling" test may be as follows: the industrial personal computer responds to the test item selection operation of the user and generates a decoupling test instruction; wherein the "decoupled" test instructions comprise: a "probe stall" instruction, a "trace return to zero" instruction, and a "start test" instruction. And the industrial personal computer sequentially sends the detection stop command and the tracking return-to-zero command to the simulation test board. When the infrared seeker to be tested is installed, the yaw direction or the pitch direction is selected, the simulation test bench executes corresponding test operation according to the detection stop command and the tracking zero command, the infrared seeker to be tested is controlled to enter a preset working state, the outer shaft of the simulation test bench is started at the frequency of 2 degrees and 3HZ, and working state information is fed back. And when the infrared seeker to be tested is determined to enter a preset working state according to the working state information fed back by the simulation test platform, and the outer shaft of the simulation test platform is started at the frequency of 2 degrees and 3HZ, the industrial personal computer sends a test starting instruction to the simulation test platform. The simulation test bench executes corresponding test operation according to the test starting instruction and controls the infrared seeker to be tested to perform decoupling test. The industrial personal computer receives a decoupling test result; wherein, the decoupling test result is acquired by a data acquisition card. The industrial personal computer analyzes the decoupling test result, determines the peak value of the curve and completes the decoupling test of the infrared seeker to be tested.

Wherein, as shown in Table 2, if the peak value of the curve/4 multiplied by 100 percent is less than or equal to 5 percent, the decoupling test is determined to be qualified.

TABLE 2 decoupling judgment reference table

Wherein, if the data curve needs to be checked, the curve can be checked by clicking the curve drawing command.

"line of sight accuracy" test

In this embodiment, the specific flow of the "line-of-sight accuracy" test may be as follows: the industrial personal computer responds to the test item selection operation of the user and generates a sight line precision test instruction; wherein, the 'sight line precision' test instruction comprises: a "probe off" instruction, a "search center" instruction, an "unlock lock" instruction, and a "start test" instruction. The industrial personal computer sequentially sends a detection stop command, a search center command and an opening locking command to the simulation test platform; the method comprises the steps that when an infrared seeker to be tested is installed, the yaw direction or the pitch direction is selected, a simulation test bench executes corresponding test operation according to a detection stop command, a search center command and an opening locking command, the infrared seeker to be tested is controlled to lock the center of an infrared target simulator, and meanwhile the simulation test bench generates a +/-15/S control command, a +/-0.5/S control command, a +/-0/S control command, a +/-1/S control command and a +/-2/S control command. After the turntable is started, the industrial personal computer sends a test starting command; the simulation test bench executes corresponding test operation according to the test starting instruction, and controls the rotary table to rotate at the speed of +/-15 degrees/S, +/-0.5 degrees/S, +/-0 degrees/S, +/-1 degrees/S and +/-2 degrees/S in sequence, so that the sight line precision test of the infrared seeker to be tested is realized. The industrial personal computer receives a field precision test result; wherein, the test result of the field precision is acquired by a data acquisition card. The industrial personal computer analyzes the field precision test result, determines the peak value of the curve and the standard deviation of pixel tracking, and completes the 'sight line precision' test of the infrared seeker to be tested. The criterion of the "line-of-sight accuracy" test is shown in table 3.

TABLE 3 Sight accuracy judgment reference table

Therefore, when the speed is +/-15 degrees/s, stable tracking needs to be met, and the sight line precision is judged to be qualified if the target does not appear in the visual field. When the speed is +/-0.5 degree/s, the sight line precision is qualified if the sigma is less than or equal to 4 degrees/s. When the speed is +/-0 degree/s, the requirement that 3 x [ sigma ] is less than or equal to 0.1 degree/s is met, and the sight line precision is judged to be qualified. When the speed is +/-1 degree/s, the sight line precision is qualified if the sigma is less than or equal to 0.2 degree/s. When the speed is +/-2 degrees/s, the sight line precision is qualified if the sigma is less than or equal to 0.2 degrees/s. Where σ represents the standard deviation of the line-of-sight angular velocity.

It should be noted that when the infrared seeker to be tested is a frame-type infrared seeker, the frame-type infrared seeker has indexes in yaw and pitch directions to be tested, and since the simulation test bench is a two-axis test bench, when the pitch direction is tested, the seeker needs to be rotated clockwise by 90 degrees, and a test result displayed on the industrial personal computer is a result of the current seeker mounting direction. And after physical connection is finished, a main power switch of the simulation test board control cabinet is turned on, simulation test board control software is turned on, an industrial personal computer is turned on, a power switch is turned on, voltage is adjusted to 28.0V and then the power switch is powered on, the seeker is waited to be subjected to self-checking, and when the status bar shows that the self-checking of the seeker is finished, the seeker can start servo index testing when physical connection, an electrical interface and communication of the seeker are normal. The seeker tool is rotated to the yaw direction, test items are selected, the test items comprise four types of test items including a tracking center test, a gyro deviation test, a decoupling test and a sight line precision test, and corresponding working modes need to be selected under different test items. And after the yaw direction test is finished, switching the guide head to the pitching direction to finish the subsequent test. In the testing process, each testing item on the interface of the industrial control computer is an independent module, so that the possibility of misoperation is greatly avoided.

Although the present invention has been described with reference to the preferred embodiments, it is not intended to limit the present invention, and those skilled in the art can make variations and modifications of the present invention without departing from the spirit and scope of the present invention by using the methods and technical contents disclosed above.

Those skilled in the art will appreciate that the invention may be practiced without these specific details.