SU565325A1 - Device for measuring dynamic skews of moving magnetic tape - Google Patents

Description

one

The invention relates to the field of instrumentation and can be used to measure the dynamic distortions of a moving magnetic tape in a tape drive mechanism (LPM) of a magnetic recording apparatus (AMR).

In the process of movement of a magnetic tape (ML) in AMZ, even in the most accurate LVL, its parasitic oscillations take place, which affect the reliability of the recorded and reproducible information. The device for measuring the transverse displacement of the ML (1), including for measuring its skew, uses a moving element placed in the cavity of the inductor. A rather complicated electronic circuit was used to control the operation of this element. The presence of a moving element significantly complicates not only the design of the device, but also its operation, although the accuracy of the readings of such a device remains quite high.

From a constructive point of view, a simpler circuit is a device made with recording and playback heads in each channel of a two-channel system (2). But here, due to the fact that in each channel the distance between the working gaps of the recording and playback heads must be strictly equal, the setup is very complex. Otherwise, the measurement results will be

there are errors caused by channel inequality.

The closest to the technical essence of the invention is a device for measuring dynamic distortions of a moving magnetic tape, consisting of an indicator, first and second identical channels, each of which contains serially connected magnetic playback head, amplifier, band-pass filter and driver connected to a separate input common to both channels of the time discriminator (3). However, if there is a high level of schum in the input signal, this device cannot produce a sufficiently reliable result.

To increase the accuracy of the measurement output at an elevated level

the noise in the input signal of the proposed device is equipped with a series-connected narrow-band filter and a threshold circuit connected between the output of the amplifier of the first channel and the indicator, as well as

serially connected frequency and peak detectors connected between the output of the second channel amplifier and the second inputs of the bandpass filters of both channels, with the output of the time discriminator

connected to the second input of the threshold circuit.

The drawing shows a block diagram of the described device.

The magnetic playback head 1 through the amplifier 2, the band-pass filter 3 and the pulse former 4 is connected to one input of the time discriminator 5, and the magnetic playback head 6 through the amplifier 7, the band pass filter 8 and the former 9 are connected to another input of the discriminator 5.

Thus, in the device there are two identical drops: the first, consisting of the head 1, the amplifier 2, the band-pass filter 3 and the former 4, and the second, consisting of the head 6, the amplifier 7, the band-pass filter 8 and the former 9. To the output of the amplifier The first channel is connected in series with a narrowband filter 10, a threshold circuit 11 and an indicator 12, which provides an indication of unreliable readings, and a serially connected frequency detector 13 and a peak detector 14 connected to the output of the second channel amplifier the second inputs of filters 3 and 8 of both channels.

Initially, harmonic signals are recorded simultaneously on two tracks of the magnetic tape on the AMZ being monitored. Next, the tape returns to the beginning of the recorded portion, and the AMZ is switched to the playback mode. The reproduced and amplified signals are fed to filters 3 and 8 with controllable bandwidth. The signal that controls this band is extracted using frequency 13 and peak 14 detectors. The signal at the output of the first corresponds to the frequency deviation of the input signal, and the voltage at the output of the second determines the maximum value of the frequency deviation of the input signal having a parasitic frequency modulation. The filtered signals pass through the formers 4 and 9 and the resulting mismatch between the pulse sequences previously formed at the output of the formers is measured by the time discriminator 5, which allows us to judge the tape misalignment in the LPM path. Thus, due to the introduction of bandpass filters with controllable bandwidth, the level of noise in the input signal is significantly reduced. The remaining noise to improve the accuracy of the readings is also estimated using a narrow-band filter 10 and a threshold circuit 11. When the output voltage of the filter 10 exceeds a certain voltage, circuit 11 is triggered, and the moment of inaccurate readings is indicated, i.e. value.

For this invention, it is very important that with an increase in the measured value, the trigger threshold increases and, consequently, the noise level is higher.

Claims (3)

1. Copyright certificate № 356447, cl. G 01B 7/00, 1971. 2. Copyright certificate № 480899, cl. G 01B 7/00, 1974. 3. Copyright certificate № 348853, cl. Q 01B 7/00, 1971 (prototype).