JPS60182020A - Magnetic tape check device - Google Patents

Abstract

(57) [Summary] This bulletin contains application data before electronic filing, so abstract data is not recorded.

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a magnetic tape inspection device 11i-1 for inspecting magnetic tapes during the production of music magnetic tapes.

Conventionally, the production of music magnetic tapes involves multiple rolls of the playback signal No. 5 (hereinafter referred to as the 11f raw signal as the musical tone h' bow) which is reproduced from the master's (sigma tape) as shown in Figure 1. The recorded magnetic tapes 2 are sequentially mounted on the plurality of rolls of Kahino 1-Half.

It is desirable to inspect the magnetic tape 2 manufactured as described above at high speed.

The present invention has been made based on the following two objectives, and an object thereof is to provide a magnetic tape inspection device that can inspect magnetic tapes with high efficiency while running at high speed.

The present invention will be explained below with reference to Examples.

FIG. 2 is a block diagram showing one embodiment of the present invention.

10 records the music message J~ on the magnetic tape 2, and
4i:.

It is a magnetic recording and reproducing device. 11 and 12 respectively indicate the supply side reel of the magnetic tape 2 and the take-up side reel of the magnetic tape 2; 13. ]・;, L 1/l indicates recording magnetic heno 1' and jlF beef coke heno 1-, respectively, 15
and 16 indicate a recording amplifier and a beef cattle amplifier, and 17
is a sensor for detecting the rotation speed of the supply reel for detecting the tape length. The structure is such that it is driven at a speed of pj. The above case will be explained using the case of n-32 as an example.

On the other hand, 20 is a signal with a wave number of 32 k Hy and 128
A signal with a frequency of k Hz and a signal with a frequency of 256 k lI 2 υ
This is an oscillator that emits a 1hi mixed signal with the oscillator 2 (
) output and the musical tone signal pass through a changeover switch circuit 21,
It is supplied to a recording magnetic hen 113 via a recording amplifier 15. The output of the regenerative magnetism, , 71-14 is the regenerative amplifier I.
6 to bandpass filters 22-24. The center frequency of the Hough 1-pass filter 22 is 32k
Hz, the center frequency of Hunt Bass So C Sita 23 is 1
The center frequency of the Hough 1-bass filter 24 is set at 256 kHz and 11 degrees.

The outputs of the band pass filters 22, 23, and 24 are supplied to an A/1] converter 26 via a changeover switch circuit 25 to convert them into 8/l), and the output digital data of the Δ/1] converter 2 () is Recorded in the storage device 27? let

From record 1a anchorage 27, T7e peaked 3 2 k Ll
Calculate whether the digital data appearing in the level of the signal component of z is within the set value, and calculate the signal component level ratio of 32k II to the level of the signal component of z] and the signal component level ratio of A calculator 28 tests whether the signal component level is within a predetermined set value, and the output of the calculator 28 is supplied to a display 30 for display.

Further, the output pulse of the rotation speed detection sensor 17 is supplied to the preset counter 11, and the output of the pre-mono 1-counter 19 is supplied to the control circuit 21. The control circuit 29 switches the changeover switch circuit 21 to supply the oscillation output of the oscillator 20 to the recording amplifier 15 instead of the musical tone signal. It switches at a predetermined timing, switches the L7J switching circuit 25 at a predetermined timing, and controls the weak point timing of the arithmetic unit 28.

An embodiment of the present invention constructed as described above will be described on the assumption that four channels of musical tones are recorded on the magnetic tape 2.

First, a musical tone signal is transferred to the magnetic tape 2 by a switch circuit 21.
is supplied to the recording amplifier 15 via the recording magnetic heno 11.
3, each track of the magnetic tape 2 is recorded. On the other hand, magnetic tape 2 has a
Driven at twice the running speed.

As a result of the above, a musical tone signal is recorded on the magnetic tape 2, and at the same time, the rotation speed detection sensor 17 detects the rotation of the supply reel 11 and outputs a pulse corresponding to the rotation speed.
Supply to 9.

When the magnetic tape 2 has run a predetermined distance from the end of the magnetic tape 2, the preset counter 1 outputs an output.

Upon receiving this output, the changeover switch circuit 2I is switched to the oscillator 20 side by the output of the +l;1j control circuit 29. Therefore, the mixed signal from the oscillator 20 is supplied to the recording amplifier 15 via the changeover switch circuit 21, and after being amplified, it is supplied to the recording magnetic head 1"I:3 and is transferred to the magnetic tape 2-y as shown in FIG. It is recorded as being ranked 10 times as high as 41.

On the other hand, the mixed signal of the oscillator 20 recorded on the magnetic tape 2 is detected by the reproducing magnetic sensor F14.

In this case, from the control circuit 29, the first
The output of the regenerative magnetic sensor FI4+ for the track is supplied to the filter 22, 23, 24 via the regenerative amplifier I6. Therefore, the 32 kHz component is output from the filter 22, and the 128 kHz component is output from the filter 23.
A 256 kHz component is extracted from the filter 24.

On the other hand, the control circuit 29 sequentially switches the changeover switch circuit 25 so that the component of '(32k)Iz, 128kIIz
The components of 256k and 112 are supplied to the A/I converter 26, converted into digital data, and sequentially written as 1 and 0 in the storage device 27 by a write signal from the control circuit 29.

Note 1. Digital data corresponding to the level of the 32 kHz component stored in the O device 27, 128 klI
Digital data corresponding to the level of the z component, 256 k
The dental data corresponding to the level of the 112 component is read out by the readout signal from the control circuit 29, and the arithmetic unit 28 determines that the level of the 32 k 11 z component is within a predetermined setting range, but the level of the 1211 k If Z component is Digital data corresponding to rail and 32k lt z
Calculate the ratio between the digital data corresponding to the level of the component and check whether it is within a predetermined setting range or the digital data corresponding to the level of the z component: 32k 1
1 Calculate the ratio of the level of the z component to the digital data (1'+l,i>) to determine whether it is within the 91 constant setting range, and output the calculation result to the display 30.
Displayed at 0.

Then, the control circuit 29 changes the reproducing magnetic head 14 to the reproducing magnetic head 14-2 for the 21st rank.
As in Section 2, gIL/-(iii+'
,'i are performed. Next, the calculation is performed on the third track and the fourth trunk in the same manner, so that the calculation is performed over all the tracks.

Here, the final stage (inspection 4Z) of the magnetic tape 2 is as follows.
If an abnormality occurs at the beginning or in the middle, empirically, the abnormality continues until the end of the magnetic tape 2, so it can be detected by inspecting the end of the magnetic tape 2 as described in -1-. It is possible to inspect the anomaly of the θ energy depth as a whole.

Also, 32k + - 1z corresponds to l k It z for the magnetic tape speed when normal recording ij +' cow.
Similarly, 128 k + (z is 4 k l (Z, 256
k II y corresponds to 8kIt z.

32 kHz (l k II z ) is the center frequency of the musical tone, and ζ is the reference frequency for frequency characteristic measurement. If the volume of the side channel is decreased overall, it is a case of uneven sound where the volume of the right channel or left channel is decreased, and 32 k It z (I k lI z
) By detecting the level of the component, the overall low volume C and the C bias of the sound are detected.

Next, 128 kHz (4 kHz) is a frequency that affects the midrange and IQ range, such as lowering the level of musical sounds and eliminating 11"1j notes, and 256 kHz.
II z (3kilZ) is a frequency in the high range of musical tones, and it is a frequency that affects the 111 range such as treble pitch, and 128 k Hy, the rail of the (4k 11 z ) component, 2,'+6kllz (8kllz) When the level of the component is not within the predetermined range, the sound p in the iI'li range of both channels or the J1 channel
In the case of Mr. F, 128kl+2 (4kHz>
, 1r! by level detection of 256kHz (8 to 11Z) components! One range? ,) each time a drop is detected.

Next, a first modified embodiment, which is one embodiment of the present invention, will be described.

The first modified embodiment differs from the embodiment of the present invention in that (32kl to 41k tape 2).
I ZZ 128 kHz, 25 fi k Ll
An oscillator that independently oscillates the z component (2(1-+)
, (2(1-2) , , (20-]) are used instead of the oscillator 20 ζ, oscillation Z: ((20--+) , (2
(1-p,), (203) □ is selected by the control circuit 29 as the father 11-, and A, 13, as shown in FIG.
C, 1) Jff, no record 4 toranokuniwataqtei+now.

Therefore, in the case of reproduction, it is carried out in the same manner as in the embodiments of the present invention described above. So, for example, for the 1st track, the components of each frequency recorded in Δm are detected, for the 21st rack, the components of each frequency recorded in 13 Jl'r are detected, and similarly for the 3rd trunk, the components of each frequency recorded in Δm are detected. For CJli
', the components of each frequency recorded on the fourth track (C is I) JIY will be detected. Other aspects are the same as in the embodiment of the present invention.

Next, a second modified embodiment of the present invention will be described.

The second modified embodiment differs from the first modified embodiment in that the oscillators (20+), (20-7), and (20-3) are alternately selected by the control circuit 29, and the recording magnetic head 13 Switching for each rack -C1 As shown in Figure 5
, B+ , C+ , L)+ 71'I are sequentially recorded on four recording tracks.

Here, in the case of p1 raw, it is performed in the same manner as the above-described embodiment of the present invention and the first modified embodiment. For the first trunk, each frequency component recorded in A l jl'l' is detected, and for the second trunk, it is detected in I-31JIY, and in the third trunk, it is Jl
'ItZ, 40th) For the 1-rack, '(') is determined every time a component of each frequency recorded in 100 groups is detected.The rest is the same as in the embodiment of the present invention.

In addition, in the above-described embodiment, the explanation was given of recording signals of three frequencies, generating iTj signals, and performing the analysis, but it may also be performed for signals of one frequency. .

As explained above, according to the present invention, inspection can be carried out with high efficiency while the magnetic tape is running at a speed of 1 h.The configuration for this purpose is also simple.

[Brief explanation of the drawing]

FIG. 1 is an explanatory diagram for explaining the production of a music tape, and FIG. 2 is a block diagram showing the configuration of an embodiment of the present invention.
FIG. 3 is a schematic diagram showing the contents recorded on a magnetic tape according to an embodiment of the present invention, and FIGS. FIG. 1 is a schematic diagram showing the contents recorded on a magnetic tape according to an example. 2...Magnetic tape, I (1...Magnetic recording device 11, 13...Magnetic recording head,
14...[IT Raw Magnetism Heheno], 15...
...Recording amplifier, 16...Reproduction increase 11.jIj
+4I, 17...Rotation speed detection sensor, 19.
...Priceno I-counter, 20...Oscillator, 21 and 25...Switch circuit,
22-24...Filter, 2G...A
/D converter, 27...Note 1. a device, 28...
... Arithmetic unit, 29 ... Control circuit, 30 ...
····display.

Claims (1)

[Claims] The magnetic tape, which is driven at a running speed n times the speed of a magnetic tape that is normally used for recording and playback, is provided with a reliability generating means for recording a signal of one frequency on each track, and a magnetic recording means for recording a signal of one frequency on each track. detection means for detecting a signal level of 1.J on each track from the reproduction signal of the recommended mother; 1 stage of judgment to judge that there is a certain thing (,i
11. , II characteristics and 1- magnetic tape inspection device.