SU645187A1 - Method of measuring the error of rotation angle-to-code conversion - Google Patents

Description

A significant disadvantage of the known method is the accepted principle of comparing the current code value between two control points with a reference signal equivalent to the calculation code between these points, which leads to an accumulated conversion error that makes it difficult to process measurement results to determine the true conversion error in each control point relative to its design position in a large array of measurements.

The purpose of the present invention is to improve the accuracy of measuring the angle conversion error. The goal is achieved by measuring the current value of the signal at the time of the first code change after zero, taking it as a reference point, summing this signal with a reference signal of a constant value, and storing the first total signal corresponding to the position angle of the first checkpoint. a reference signal of a constant value is added to the total signal and the second total signal corresponding to the calculated angle of the position of the second control point is memorized, then the measurement process is repeated in a series of control points when turning the shaft through 360 °,

A block diagram of a device for checking angle-code converters that implements the proposed method for measuring conversion errors is shown in the drawing.

The device contains a reference converter 1 connected to one of the inputs of the converter 2 of the code, and a test converter 3 connected to the input of the converter 4 of the codes mounted on the same shaft. The output of the converter 4 is connected to one of the inputs of the control unit 5, the output of which is connected to the second input of the converter 2, and the output of the latter is connected to the input of the reference point logic 6. For the sake of simplicity, the remaining connections of unit 5 controlling the operation of the elements of the device are not shown. The second input of the logic element 6 is connected to the output of the converter 4.

The outputs of the converter 2 and the logic element 6 are connected to the corresponding inputs of the adder 7 of the current error analyzer, which also contains the calculated angle storage block 8, the tolerance storage block 9, the read block 10, the calculated numbers storage register AND, the current error buffer register 12 connected to the input block 13 alarm and error registration.

Moreover, blocks 8 and 9 are connected to the corresponding inputs of the adder 7, the other input of which is connected to the output of the register I, the input of the latter is connected via the reader 10 to the output of the adder, also connected to the buffer register 12.

The device works as follows. The device starts, and when the shaft rotates in the direction of increasing the angle from the output of the reference converter 1, a signal in the form of a special code is fed to the input of the converter 2, and the signal from the output of the checked converter 3 is fed to the input of the converter 4, from the output of which the binary code is fed to logical input

10 of the element 6 and to the input of the control unit 5. The binary code from the output of the converter 2 is fed to the second input of the logic element 6, in which the binary equivalent of the angle of rotation of the reference converter from the zero position is stored before the first zero point of the control point of the converter being checked when changing it code taken as a reference and is written to adder 7. According to

0, the command of block 5 in the adder 7, the initial error code is summed with the code of the design angle corresponding to a reference signal of a constant value between two adjacent test points,

5 which is entered from block 8 and then through block 10, the summation result is output for storing to register I. The resulting number is the code of the calculated value of the position angle of the first after the start of the reference point, when the output of the transducer 2 appears This point is recorded in the adder, where it is subtracted from the code of the calculated number. The code value of the number obtained in adder 7 is the value of the current value of the conversion error, and the sign of the error is also determined in the adder. Then, the sign and the error value are output for storing into the buffer register 12 into the adder is entered from block 9 to subtract the tolerance corresponding to the largest predetermined value of the current error of the reference point position

5 relative to the calculated.

In case of a conversion error over the tolerance value, the adder generates a exceed signal at block 13. After that, the magnitude and sign of the current error code, as well as the result of comparing it with the specified tolerance, are output to the recording device. Next, the adder 7 is reset to its initial state and the code of the calculated number from register 11 is written into it, and then from block 8 the code of the calculated angle of the register I is entered, and as a result of summation, the code of the calculated value of the angle of position of the next control point is obtained, which is displayed again register 11. When this checkpoint occurs, the operation cycle is repeated.

Further, the measurement process is repeated for all control points when turning the shaft of the tested transducer through 360 ° arcs. The end of the test occurs at

the equality of the code read from converter 2 and the initial mismatch code stored in the logic element 6. The economic effect of using this one. The method is determined by its technical advantage.

Claims (2)

1. USSR author's certificate number 479143, cl. G 08 C 25/00, 1973. 2. USSR author's certificate number 392535, cl. G 08 C 9/00, 1973.