SU951151A1 - Method of correcting electrical signal picture on the screen of cathode ray oscilloscope - Google Patents

Description

one

The invention relates to electrical measuring technology and can be used in calibrating digital oscilloscopes and automated oscillographic systems.

The closest to this invention in terms of technology is the method of correcting the image of an electrical signal on the screen of an electron-beam oscilloscope, which consists of recording a calibrated ION sshusoidal signal, measuring its ordinates at points of intersection with a given amplitude level, determined from these measurements of calibration coefficients and insertion Based on the corrections in image 1.

The disadvantage of this method is the small width of the calibrated part of the screen located between the first and the last intersections, which usually do not coincide with the borders of the screen due to the randomness of the initial phase of the calibration signal.

The purpose of the invention is to extend the calibrated part of the screen to the edges of the screen.

Claims (1)

This goal is achieved due to the fact that the method of correcting the image of an electrical signal on the screen of an electron-beam oscilloscope, which consists in recording a calibration sinusoidal signal, measuring its abscissas at intersection points with a given amplitude level, determining the correlation coefficients from these measurements and making corrections based on them. in the image, supplemented by the fact that a test capibration signal with a period close to a multiple of the sweep duration is written, an amplitude is chosen for this signal The correct intersection level equal to the first-recorded ordinate of the calibration signal is checked to match the value of the last recorded ordinate and the amplitude level equal to the first recorded ordinate, if there is no coincidence, the frequency of the calibration signal, repeat the calibration signal and select the level, check the match and change the frequency to match the last recorded order and the level equal to the first recorded ordinate, is determined for the calibration signal, which, due to the multiplicity the period and duration of the sweep there is a coincidence, the calibration coefficients. The drawing shows a structurally electric circuit of a variant of the device implementing the method. The device consists of a 1-gauge sinusoidal signal with a variable frequency, an oscilloscope 2 with a storage cathode-ray tube (CRT), and a unit 3 for controlling and processing measurement information. The method is implemented as follows. A calibration signal with a period close to a multiple of the sweep duration comes from the output of generator 1 to the input of the vertical deflection path of the oscilloscope 2. After the calibration signal is picked up, an amplitude level is selected, at the intersections with which the ordinates of the calibration signal are determined. The level of intersection is chosen equal to the first recorded ordinate of the calibration signal. An array of ordinates, determined at the intersections, is transmitted to block 3 of control and processing of measurement information, in which computer is used. Block 3 checks that the value of the last recorded ordinate and the amplitude level equal to the first recorded order of the calibration signal match (with a given accuracy). If there is no match, then block 3 issues a command to 1, due to the control input of the generator of which the frequency of the calibration signal changes. After recording the second calibration signal, the amplitude level is again equal to the first recorded ordinate of the calibration signal, the array of ordinates is transferred to block 3, and the match is checked. Sequential recording of the test signals of different frequencies continues until a match is made. The signal for which, due to the multiplicity of its period and the sweep duration, a coincidence takes place, is subjected to processing in block 3, whereby the measurements of its abscissa at the intersection points with the selected amplitude level determine the calibration factors along the entire length of the screen. Based on the calibration coefficients, the elements of the array of the signal under investigation are corrected, which is fed to the input of the vertical deflection of the oscilloscope 2 after the calibration is completed. The calibration coefficients are determined before each measurement, which is associated with a change in the sweep duration over time due to various factors. The method allows to expand the calibrated (working) part of the screen to the edges of the screen, since the choice of the level ensures the coincidence of the first intersection with the left border of the screen, and the period multiplicity coincides with the last intersection with the right border of the screen. Claims The method of correcting an image of an electrical signal on an electron-beam oscilloscope screen, which consists in recording a calibration sinusoidal signal, measuring its abscissa at intersection points with a given amplitude level, determining the calibration coefficients based on these measurements, and in order to expand the calibrated part of the screen to the edges of the screen, lock the test Calibration signal with a period close to a multiple of and sweep, select the amplitude of the intersection equal to the first recorded ordinate of the calibration signal for this signal, check the coincidence of the values of the last recorded ordinate and the amplitude level equal to the first recorded ordinate, change the frequency of the calibration signal if there is no match, repeat the recording of the calibration signal, select the level , the matching check and the frequency change to match the last recorded ordinate and the level equal to the first recorded ordinate is determined for the calibration th signal, which due to the multiplicity of scan period and the duration of coincidence is observed, calibration coefficients. Information sources. Taken into account during the examination 1. Mills, Triis. Digital system for recording nanosecond processes. - Electronics, 1971, N 25 (prototosh).