JPH0827915B2 - Test tape - Google Patents

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a test tape, and more particularly to a test tape used to adjust the position of a multi-channel head.

2. Description of the Related Art In a magnetic recording / reproducing apparatus having a two-channel magnetic head such as a tape deck, for example, a head adjusting mechanism for adjusting the position of the magnetic head is provided so that each core is in stable sliding contact with the magnetic tape. As this head adjusting mechanism, there is a mechanism configured as shown in FIG.
By rotating the adjusting screws 3a to 3d of the base 3 supporting the magnetic head 2, it is possible to adjust the A to D directions (tilt, vertical, height, direction) of the magnetic head 2 with respect to the test tape 1. It has become. Conventional test tape 1 is No. 7
As shown in the figure, two head position adjusting tracks 4a, 4b with which the respective cores 2a, 2b of the head are in sliding contact are recorded. The track widths of the head position adjusting tracks 4a and 4b are the core 2
It is formed to be the same as a and 2b, and is also formed at a position (height position) in the width direction (C direction) with respect to the entire tape width. The signals recorded on both tracks 4a and 4b have the same frequency, and the recording levels are the same.

Then, in the assembly process, the height position of the magnetic head 2 is adjusted while checking the output levels of both channels of the magnetic head 2 using this test tape so that the output levels of both channels are maximized.

DISCLOSURE OF THE INVENTION Problems to be Solved by the Invention However, in the conventional test tape, the pair of cores 2a, 2
In order for b to trace the head position adjusting tracks 4a, 4b accurately, the track width dimension of the pair of cores 2a, 2b must be manufactured with high accuracy.
It is necessary to record so that the recording levels of a and 4b are the same. However, in actuality, the width of the cores 2a and 2b is set to track 4
It is difficult to make it the same as the width of a and 4b.
It is also difficult to manufacture so that the distance from 2b coincides with the distance between tracks 4a and 4b.

Moreover, it is difficult to make the recording levels of the tracks 4a and 4b the same. Further, if the head position is deviated, both output levels drop similarly, so it is difficult to know where the maximum output level is.

Therefore, when the height of the magnetic head 2 is adjusted using the conventional test tape 1, it is difficult to find the position where the output level of the pair of cores 2a and 2b is the maximum, and the height of the magnetic head 2 is adjusted. There was a problem that it was difficult to perform accurately and adjustment work took time.

As a means for solving the above problems, there is a "head adjusting reference tape" as disclosed, for example, in JP-A-61-126623. In this publication, the pair of heads are adjusted to a position where they are in sliding contact with the adjustment track with a uniform width. Then, in the height adjustment of the head, the reproduction signal when the adjustment track is reproduced is envelope-detected by the detection circuit, and these detection signals are compared by the comparison circuit. The height of the pair of heads is adjusted based on the comparison output.

However, in the above publication, since the sliding contact width of the head with respect to the track is simply equalized, the output level of the reproduction signal of the head cannot be adjusted before adjusting the sliding contact position of the head. Moreover, after adjusting the slide contact position of the head, in order to check the output level of the playback signal of the head, it is necessary to replace it with a normal tape and play it back. Check the output level of the playback signal of the head immediately. There was a problem that I could not do it.

Then, this invention aims at providing the test tape which solved the said subject.

Means for Solving the Problems According to the invention of the above-mentioned claim 1, a reproducing output adjusting track in which an adjusting signal is recorded on the entire width of the magnetic tape and a pair of cores adjacent to each other and narrower than the reproducing output adjusting track are provided. The head position adjusting tracks that are in sliding contact with each other at the same time are recorded alternately, and the center of the head position adjusting track in the track width direction is substantially coincident with the center between the pair of cores, and the dimension of the track width is a pair. It is formed to have the same width as or less than the entire width of the core.

According to a second aspect of the present invention, a reproduction output adjustment track having an adjustment signal recorded on the entire width of the magnetic tape and a head position adjustment track narrower than the reproduction output adjustment track are alternately recorded. Recording on the head position adjustment track so that the output level when the position adjustment track is reproduced and the output level when the reproduction output adjustment track is reproduced are substantially the same level. The level is set higher than the recording level on the reproduction output adjusting track.

According to a third aspect of the present invention, a reproduction output adjustment track in which an adjustment signal is recorded on the entire width of the magnetic tape and a head position adjustment track narrower than the reproduction output adjustment track are alternately recorded. It is a test tape in which the frequencies of the adjustment signal recorded on the head position adjustment track and the adjustment signal recorded on the reproduction output adjustment track are recorded at different frequencies.

According to the above-mentioned invention, since the reproduction output adjusting track and the head position adjusting track are alternately recorded, the output level of the reproduction signal of the head is adjusted before adjusting the sliding contact position of the head. In addition to the adjustment, the output level of the reproduction signal of the head can be confirmed immediately after adjusting the sliding contact position of the head, and the adjustment work can be repeated. Further, since the center between the cores coincides with the center of the head position adjusting track, if the positions of the cores are deviated, the difference in output level between the pair of cores is enlarged, and the accuracy of head position adjustment is improved. .

According to the second aspect of the invention, the output level when the position adjustment track is reproduced and the output level when the reproduction output adjustment track is reproduced are substantially the same level. The fluctuation of the head is small and the head position can be easily adjusted.

According to the invention of claim 3, by changing the frequency of the signal recorded on the head position adjusting track and the frequency of the signal recorded on the reproduction output adjusting track,
It is possible to determine which track the magnetic head is reproducing, and it is possible to confirm that the head is in sliding contact with the head position adjustment track when adjusting the head position.

EXAMPLE FIG. 1 and FIG. 2 show an example of the test tape according to the present invention.

In both figures, the test tape 7 is 1 on the recording surface of the magnetic tape 1.
A head position adjusting track 5 of the book is recorded. The head position adjusting track 5 has cores 2a, 2 provided on a magnetic head 2 having a two-channel center line O in the tape width direction.
It is recorded so as to coincide with the center between b. That is, the distances l ₁ and l ₂ from the center line O to the cores 2a and 2b are l ₁ = l ₂ .

Also, the track width dimension C of the track 5 is such that the pair of cores 2
It is smaller than the total width B of a and 2b and larger than the gap A between the pair of cores 2a and 2b (A <C <B). Therefore, when the head height is adjusted, the pair of cores 2a and 2b are slidably contacted with the peripheral edges of both sides of the track 5 so as to groin one track 5.

When the width dimensions of the pair of cores 2a and 2b are w ₁ and w ₂ , the tape sliding contact widths of the cores 2a and 2b are x and y, and the output difference between the pair of cores 2a and 2b is P, the following equation is established. .

The track width C is known because it is a recorded size.

From the relationship of the above equation, the head height adjustment adjusts the height positions of the cores 2a and 2b by turning each adjusting screw 3a to 3d (shown in FIG. 6) of the base 3 so that the output difference P becomes zero. . Alternatively, if the value of the output difference P is adjusted to fall within an allowable range of ± several% around zero, the core 2 with respect to the track 5 is
The relative positions of a and 2b can be adjusted to ideal positions.

Further, since it is sufficient that one head position adjusting track 5 is recorded on the pair of cores 2a and 2b, the position of the track 5 can be managed more easily than in the past, and the track 5 can be formed with high accuracy. You can

Further, on the magnetic tape 1, the head position adjusting tracks 5 and the reproduction output adjusting tracks 6 are alternately recorded. The reproduction output adjusting track 6 is recorded on the entire width of the magnetic tape 1. This is because the cores 2a and 2b for reproducing output adjustment, which will be described later, reproduce the same track 6 by the core 2a.
This is because the output levels of the reproduction signals of a and 2b are adjusted to have a predetermined constant value. Therefore, the head position can be adjusted by the head position adjusting track 5 immediately after adjusting the output levels of the reproduction signals of the cores 2a and 2b by the reproducing output adjusting track 6. Further, since the tracks 5 and 6 are recorded alternately, the output level of the reproduction signal of the head 2 can be adjusted before adjusting the sliding contact position of the cores 2a, 2b of the head 2, and the head 2 can be adjusted. The core 2a, 2
After adjusting the sliding contact position of b, the output level of the reproduction signal of the head 2 can be confirmed immediately, and the adjustment work can be repeated.

Further, the adjustment signal recorded on the reproduction output adjustment track 6 has a recording level smaller than that of the adjustment signal recorded on the head position adjustment track 5, and has a different frequency.

That is, the adjustment signal recorded on the head position adjusting track 5 is recorded at, for example, 0 dB, and the adjustment signal recorded on the output adjusting track 6 is recorded at −6 dB, and the recording levels of both tracks 5 and 6 are recorded. Is 6 dB. This means that if both tracks 5 and 6 are recorded at the same recording level, the playback output adjustment track 6 will have a pair of cores 2a and 2a.
Since b is in sliding contact with the entire surface, the output level of the reproduction signal is large, but in the head position adjusting track 5, a pair of cores is used.
This is because 2a and 2b are in sliding contact with each other, so that the output level of the reproduction signal is lowered. That is, when adjusting the head height, which will be described later, when adjusting the reproduction output of the pair of cores 2a and 2b, the needle of the voltmeter swings largely, and when adjusting the head position, the needle of the voltmeter swings slightly. In this case, since the degree of deflection of the needle of the voltmeter changes as described above, it is difficult to adjust the head position and the adjustment accuracy also deteriorates.

Therefore, in this embodiment, the head position adjusting track 5
By setting the recording level of the above to be higher than the recording level of the reproduction output adjusting track 6, the output levels of the pair of cores 2a and 2b on both tracks 5 and 6 are made substantially the same. This allows the pair of cores 2a and 2b to be adjusted even when the head position is adjusted.
Output becomes high level, adjustment operation becomes easy,
As a result, the adjustment accuracy is improved.

The adjustment signal recorded on the head position adjustment track 5 is recorded at a frequency of about 400 Hz, for example. On the other hand, the adjustment signal recorded on the output adjustment track 6 is recorded at a frequency of about 440 Hz, for example. This is for confirming which track 5, 6 the magnetic head 2 is in sliding contact with, as will be described later.

Next, an operation for adjusting the head position using the test tape 7 will be described.

FIG. 3 shows the structure of a measuring device for adjusting the head position. In FIG. 3, a pair of cores 2a, 2b that are in sliding contact with the test tape.
The reproduction signal output from the amplifier is supplied to the amplifiers 8 and 9, and the reproduction signal amplified by the amplifiers 8 and 9 is output to the measuring instruments 10 and 11.

Measuring instruments 10 and 11 are variable resistors 12 and 13, voltmeters 14 and 15, respectively.
It consists of speakers 16 and 17.

When the tape 7 is wound in the tape running direction, the pair of cores 2a, 2b of the magnetic head 2 are slidably brought into contact with the output adjusting track 6 and the head position adjusting track 5 of the test tape 7, and each track 5, Play the adjustment signal recorded in 6.

Since the adjustment signals recorded on both tracks 5 and 6 are signals of different frequencies, the operator determines which track is being reproduced by the sound emitted from the speakers 16 and 17 of the measuring instruments 10 and 11. Can be determined. That is, in this embodiment, the adjustment signal of the head position adjustment track 5 is 400H.
At z, since the adjustment signal of the output adjustment track 6 is 440 Hz, when the pair of cores 2a and 2b slidably contact the track 5, the speaker sound becomes low temperature and the pair of cores 2a and 2b slidably contact the track 6. The speaker sound at this time becomes high-pitched sound.

Therefore, when the sound from the speakers 16 and 17 is high, the operator operates the variable resistors 12 and 13 so that the needles of the voltmeters 14 and 15 point to the same level. Make a correction.

When the pair of cores 2a and 2b are in sliding contact with the head position adjusting track 5, the sound from the speakers 16 and 17 becomes low. Therefore, the operator can confirm that the pair of cores 2a and 2b slidably contact the track 5 when the speaker sound is switched to the low sound.
The height (position in the C direction) of the magnetic head 12 is adjusted by turning each adjusting screw 3a to 3d of the base 3 shown in the figure.

In that case, the pair of cores 2a and 2b are connected to each other as shown in FIG.
The height position in the C direction is adjusted so as to evenly contact both side edge portions of the head position adjusting track 5. When the center between the pair of cores 2a and 2b coincides with the center line of the track 5,
The output of the pair of cores 2a, 2b becomes the same level, and the voltmeter 14,
The 15 needle indications are also the same.

In the test tape 7, since the recording level of the adjustment signal of the track 5 is higher than that of the adjustment signal of the track 6, the sliding contact area of the pair of cores 2a, 2b with respect to the track 5 is small, but the voltmeter 14, The level indicated by the 15 needles is track 5,6
It is almost the same level regardless of. Therefore, the outputs of the cores 2a and 2b do not decrease even when the head position is adjusted, and the needles of the voltmeters 14 and 15 indicate the high level. Therefore, it is easy to confirm the output level during the head position adjusting operation, and the adjusting accuracy can be maintained.

When the pair of cores 2a and 2b are displaced upward with respect to the track 5 as shown in FIG. 4, the sliding contact width x of the upper core 2a with the track 5 is small, and the track of the lower core 2b is The sliding contact y with 5 becomes large (x <y). Therefore, the output level of the core 2a decreases and the output level of the core 2b increases. This is shown in a diagram in FIG. In FIG. 5, the line I shows the change in the output level of the core 2a, and the line II shows the change in the output level of the core 2b. Both lines I and II are left-right symmetrical. In FIG. 5, the head height is 0, which is the target value. At this time, the output levels of the cores 2a and 2b are the same.

However, when the pair of cores 2a and 2b shift as shown in FIG. 4, the head height shifts to the + side, and the output level of the cores 2a and 2b changes to a level that intersects with the alternate long and short dash line. Therefore,
When the height position of the magnetic head 2 with respect to the track 5 is high,
The output level of the core 2a decreases and the output level of the core 2b increases.

On the contrary, when the height position of the magnetic head 2 is low, the head height moves to the negative side in FIG. 5, the output level of the core 2a rises, and the output level of the core 2b falls.

That is, the head height adjustment operation is performed by the voltmeter 1 of the measuring instruments 10 and 11.
Since it is performed while checking the output levels of the cores 2a and 2b with 4,15, the adjustment screws 3a to 3d may be finally turned so that the hands of both voltmeters 14 and 15 indicate the same level.

Also, if the head height shifts, the voltmeters 14 and 15
Since the output level of one decreases and the output level of the other increases, it can be seen at a glance that the magnetic head 2 is displaced with respect to the track 5, and the direction in which the magnetic head 2 is displaced is also known. Therefore, the operator can not only adjust the head height accurately but also can easily perform the adjustment work in a short time.

In the conventional case, if the head height shifts, the pair of cores 2a, 2b
It was difficult to determine which output level was in the correct position, because both output levels were reduced. However, in this embodiment, both output levels change in the opposite directions when the head height shifts, so that even an inexperienced operator can perform the adjustment work with high accuracy.

Although the height adjustment of the two-channel magnetic head 2 has been described as an example in the above embodiment, the present invention is not limited to this.

EFFECTS OF THE INVENTION As described above, according to the first aspect, since the reproduction output adjustment track and the head position adjustment track are recorded alternately, the reproduction signal of the head is adjusted before adjusting the sliding contact position of the head. The output level of the head can be adjusted, the output level of the reproduction signal of the head can be confirmed immediately after adjusting the sliding contact position of the head, and the adjustment work can be repeated. Further, since the center between the cores coincides with the center of the head position adjusting track, when the positions of the cores are deviated, the difference in output level between the pair of cores is increased, and the accuracy of head position adjustment is improved. You can

Further, according to claim 2, since the output level when the position adjustment track is reproduced and the output level when the reproduction output adjustment track is reproduced are substantially the same level, the output when the head position is adjusted. You can prevent the level from lowering,
The output level change depending on the head position becomes easy to understand,
Head position can be adjusted easily.

Further, according to claim 3, the magnetic head reproduces which track by changing the frequency of the signal recorded on the head position adjusting track and the frequency of the signal recorded on the reproduction output adjusting track. It is possible to determine whether the magnetic head is in contact with the head position adjusting track when adjusting the head position.

[Brief description of drawings]

1 and 2 are front views showing an embodiment of the test tape according to the present invention, FIG. 3 is a block diagram of a measuring device for adjusting the head position, and FIG. 4 is a case where the head height position is displaced. 5 is a front view showing the relative positional relationship between the core and the head position adjusting track, FIG. 5 is a diagram showing the output levels of the pair of cores according to the head height, and FIG. 6 is an explanatory view of the head position adjusting mechanism. FIG. 7 is a front view of a conventional test tape. 1 ... magnetic tape, 2 ... magnetic head, 2a, 2b ... core, 3a-3d ... adjusting screw, 4a, 4b, 5 ... head position adjusting track, 6 ... playback output adjusting track, 7 ...
Test tape, 10,11 …… Measuring instrument, 14,15 …… Voltmeter, 1
6,17 …… Speaker.

Claims (3)

[Claims] 1. A reproduction output adjusting track in which an adjusting signal is recorded on the entire width of a magnetic tape, and a head position adjusting track in which a pair of adjacent cores narrower than the reproduction output adjusting track are in sliding contact with each other at the same time. The recording is performed alternately, and the center of the head position adjusting track in the track width direction substantially coincides with the center between the pair of cores, and the dimension of the track width is equal to or less than the total width of the pair of cores. A test tape characterized by being formed as follows. 2. A test tape in which a reproduction output adjustment track in which an adjustment signal is recorded over the entire width of a magnetic tape and a head position adjustment track narrower than the reproduction output adjustment track are alternately recorded. The recording level to the head position adjusting track so that the output level when the position adjusting track is reproduced and the output level when the reproducing output adjusting track is reproduced are substantially the same level. A test tape characterized by having a higher level than the recording level on the output adjustment track. 3. A test tape in which a reproduction output adjustment track in which an adjustment signal is recorded over the entire width of a magnetic tape and a head position adjustment track narrower than the reproduction output adjustment track are alternately recorded. The test tape is characterized in that the adjustment signal recorded on the head position adjustment track and the adjustment signal recorded on the reproduction output adjustment track are recorded at different frequencies.