SU834758A1 - Method of determining lateral oscillations of information carrier tape - Google Patents

Description

154) METHOD FOR DETERMINING TRANSVERSE VIBRATIONS OF TAPE MEDIA OF INFORMATION

one

The invention relates to instrumentation, namely to the field of measuring the motion parameters of electrostatic recording media, and can be used to determine the transverse vibrations of a moving tape carrier in vibration measuring laboratories and research institutes.

A known method of measuring transverse oscillations of a tape carrier, in which a control signal is recorded on one or several tracks on a dielectric carrier, is reproduced by scanning a ray of a cathode ray tube with a metal-fiber screen across the width of the carrier, and generating pulses that change the parameters of which are judged transverse carrier oscillations 1.

The disadvantage of this method is the difficulty of applying a pilot signal to the carrier.

The closest to the present invention is a method for determining transverse oscillations of a moving information carrier, in which a control signal is recorded on the carrier in the form of equipotential parallel signals.

electrostatic field bands, which are located at the same distance from each other, are scanned with the tube's beam across the carrier during playback, at the moments of intersection of the bands they form a sequence of pulses, by varying the amplitude of which the carrier oscillates perpendicular to its plane, and durations of oscillations in its plane 2.

However, this method cannot provide the required measurement accuracy.

five

The purpose of the invention is to improve the measurement accuracy.

The goal of the PS is achieved by the fact that in the method of determining the transverse oscillations of a tape carrier information, in which a control signal is recorded on a fixed carrier in the form of parallel equipotential lines spaced from each other

Claims (2)

5 electrostatic field along the tape carrier, reproduce the control signal by scanning the carrier width of the cathode ray tube with a metric fiber screen and then analyzing the reproduced signal, while the carrier is stationary, the scan time of the beam from the beginning of the sweep to the equipotential line and between them is measured moving media between the lines additionally record potential bands by scanning the radiation cathode ray tube with a metal fiber screen, during playback At the same time, the total pilot signal measures the scanning time of the beam between the lines and the width of the bands as well as from the beginning of the sweep to each of the lines and stripes, after which the ratios of the time of scanning the beam from the beginning of the sweep to each line with a fixed and moving carrier are determined, multiplied for the time of scanning the beam from the beginning of the sweep to the strip preceding this line, one half of the ratio of the scanning time of the beam between each two adjacent lines is added to the resulting product with a fixed and moving distance ms carrier multiplied by the scanning time of the beam across the width of the strip corresponding to these lines; to the change in the result of the summation over the scan time of the beam across the width of the carrier, the transverse oscillations of the tape carrier are determined. The method of determining the transverse oscillations of the tape carrier of information is performed as follows. Potential direct parallel electrostatic lines are applied to the fixed information carrier by an electrode system, ..., located at the same distance from each other, by contacting them with the carrier. When the carrier is stationary, the beam is scanned across the screen of the tube by applying a sweep current from the output generator and a constant voltage from the output of the high voltage source to the deflecting system of the sawtooth current. When an electron beam hits the tube electrodes, their potential reaches the screen-carrier voltage, and the result is a transfer of electrostatic charge to the carrier, the magnitude of which directly proportional to the potential difference between the electrodes and parts of the carrier. The carrier is then set in motion by a tape-driving mechanism, driven by an electric drive, while the carrier is being moved, a sawtooth current from the generator output is fed to the deflecting tube, and a sequence of rectangular pulses is applied to the cathode. This sequence of pulses opens the electron beam, which scans the tube screen. In the absence of transverse and perpendicular oscillations of the carrier, they are recorded in the middle between the lines, equiotential direct parallel axes having the same width along the carrier line, but in reality, due to transverse oscillations and perpendicular oscillations, the width of the recorded axes oscillates; the magnitude of the potential of the bands, since the equal number of yes and yes is distributed on different parts of the plate, in the presence of transverse, carrier oscillations, the average line of the e different times will be located at different distances x from the outermost electrode of the tube screen, i.e. due to transverse vibrations, the band becomes sinuous, and the perpendicular vibrations modulate the width of the bands. Thus, instead of straight stripes of the same width, wavy stripes of variable width are applied to the carrier. During the motion of the carrier, in order to measure the transverse and perpendicular oscillations of the carrier, the total recorded control signal, consisting of straight equipotential lines and bands, is reproduced. The physical processes occurring during reproduction are similar to the case of reproduction of equipotential lines with a fixed carrier. If the vector of the scanning speed of the beam during reproduction coincides with the velocity vector of transverse oscillations, then the relative scanning speed of the beam across the width of the strip will be less than the speed of the beam, therefore the duration of the generated pulse will be longer than the duration of it without oscillation. Otherwise, i.e. when the vectors are directed oppositely, the scanning time of the beam between two adjacent lines will be less than the duration of this pulse in the absence of lateral oscillations of the carrier. Therefore, in order to reduce the influence of transverse oscillations of the carrier during reproduction, namely, taking into account the direction of these oscillations relative to the direction of scanning the beam on the measurement of transverse oscillations during recording, the measured pulse durations are multiplied by correction factors showing the relative ratio of the scanning speeds of the beam in a static and dynamic state x carrier. The transverse oscillations of the carrier during recording in the presence of transverse oscillations during reproduction can be determined by the formula icTot / astatine Gadin 1 st ' astatine - scanning time of the beam between two adjacent lines, in the static and dynamic state of the carrier, X, -scanning time along the bandwidths between these lines and - the scan time of the paper from the beginning of the sweep to the line in the static and dynamic state; f, is the time at which the beam was scanned before the beginning of the preceding band. The second term of this sum characterizes the half of the corrected scan time of the beam jio to the width of the strips by which the perpendicular oscillations of the carrier, which occurred during the recording, are judged. The advantage of the proposed method lies in the fact that the laws of transverse and perpendicular vibrations of the carrier during recording are determined by reproducing the control signal using the same tape mechanism. Thus, a test tape mechanism is not required for analyzing vibrations when recording information. Using the proposed method on the same mechanism, one can determine very precisely the law of carrier oscillations. In addition, the method has high resolution, speed and accuracy. The method of determining the transverse oscillations of a tape information carrier, in which a control signal is recorded on a fixed carrier in the form of parallel at equal distances from each other located equipotent lines of the electrostatic field along the tape carrier, reproduce the control signal by scanning the beam of the electron beam a tube with a meta-fiber screen and the subsequent angles of the reproduced signal, characterized in that, in order to increase measurement accuracy, with a fixed carrier, the scanning time of the beam from the beginning of the sweep to the equipotential lines and between them is measured, then potential bands are also recorded onto the moving carrier between the lines by a scanning beam of a cathode ray tube with a metal fiber screen, while reproducing the total control signal, the scanning time is measured between the lines and the width of the stripes, as well as from the beginning of the sweep to the length of the line and the stripes, after which the ratios of the scanning time l From the beginning of the sweep to each line with a fixed and moving carrier, multiplied by the scanning time of the beam from the beginning of the sweep to the strip preceding this line, half the relative beam scanning time between each two adjacent lines with the fixed and moving the carrier multiplied by the scan time of the beam across the width of the corresponding lines of the line, and the transverse oscillations are determined by changing the result of the summation during the scanning time of the beam across the width of the carrier belt carrier. Sources of information taken into account during the examination 1. USSR author's certificate 568077, cl. G 11 B 9/08, 03/07/76. 2. USSR author's certificate number 339956, cl. 6 01 В 7/16, 07.04.76 (prototype).