JPH087246A - Rotary head type recording/reproducing device - Google Patents

Abstract

PURPOSE:To enhance overwrite characteristics and to prevent the occurrence of the erase remainder by reproducing a pilot signal by a head having the same azimuth for tracking control thereby enabling the pilot signal of a short wavelength to be used. CONSTITUTION:At a recording time, after the data are recorded through recording hands Hw1, Hw2, the pilot signal for ATF is recorded through a servo head Hs. At a reproducing time, the data are reproduced through reproducing heads Hs1, Hs2. Then, when a magnetic tape of a recording pattern is reproduced by the reproducing heads Hr1, Hr2, since the pilot signal for ATF is recorded by the recording head Hw1, the tracking control is performed by using the reproduced output signal of the reproducing head Hr1 having the same azimuth as the head Hw1. Then, a read enable signal REN is supplied to a reproducing amplifier 11, and the reproducing amplifier 11 is activated when the enable signal is a high level.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a helical head type rotary head type recording / recording apparatus for recording code data, audio information, video information and the like on a tape recording medium.
Reproduction device

[0002]

2. Description of the Related Art A rotary head type recording / reproducing apparatus is known in which a rotary head records / reproduces digital audio data, digital or analog video data on a magnetic tape running while being guided by a cylindrical surface of a drum. . Slant tracks are sequentially formed on the magnetic tape during recording, and the head must correctly scan the track position during reproduction. Tracking control is employed to accurately match the trace path of the head with the track.

Various tracking controls have been conventionally proposed. One of them is to record a control (CTL) signal at a predetermined interval in the longitudinal direction of the magnetic tape,
This is a method of controlling so that the phase of the reproduced CTL signal becomes a predetermined one. This method has a problem that a magnetic head dedicated to recording / reproducing CTL signals is required. The method using a rotary head dedicated to tracking control instead of a fixed head has the same problem. Also, with an 8 mm VTR,
In order to record pilot signals of four kinds of frequencies on four continuous tracks, the one in which the pilot signals are frequency-multiplexed with the recorded analog signal is adopted. The method of frequency-multiplexing such pilot signals is
It cannot be applied to a device for recording / reproducing a base band of digital data because frequency multiplexing and frequency separation are difficult.

As a method applicable to recording / reproducing of digital data and not requiring a head dedicated to tracking control, there is a method used in a digital audio tape recorder (so-called DAT). In this method, an ATF pilot signal is recorded in a predetermined section of a track, and the quality of the tracking state is determined based on the level relationship of pilot signals reproduced from two tracks adjacent to each other. In order to reduce crosstalk between adjacent tracks, the DAT uses a rotary head in which an angle (called azimuth) formed by the extension direction of the gap is different. Therefore, in order to reproduce the pilot signal from both adjacent tracks, a low-frequency (long wavelength) pilot signal with little azimuth loss is used.

[0005]

From the viewpoint of downsizing and simplification of the rotary head or the rotary transformer, it is preferable that the erasing can be performed by the overwriting method without using the rotary erasing head. However, in general, a long-wavelength signal is recorded up to the deep portion of the magnetic tape, and thus it is difficult to erase by overwriting. In particular, it is difficult to be erased by a short wavelength signal such as digital data. Therefore, in order to cancel the pilot signal, a cancellation signal of a special frequency having a longer wavelength than the data is required. Furthermore, in the case of a used magnetic tape, there is a possibility that the unerased residue will occur. Further, there is a problem that a position detection signal for detecting a pilot signal is required and a special circuit such as a pilot signal detection circuit and an erroneous detection prevention circuit is required.

Therefore, an object of the present invention is to solve the above-mentioned problems, to use a short-wavelength signal having a good overwrite characteristic as a pilot signal, and to use a rotary head type recording which does not require a new position detection signal. / To provide a reproducing apparatus.

[0007]

SUMMARY OF THE INVENTION The present invention relates to a rotary head type recording apparatus in which a digital signal is recorded as a diagonal track on a tape-shaped recording medium by a rotary head rotating at a predetermined speed. Different first and second recording rotary heads, and
And a servo head for recording a pilot signal having the same azimuth as one of the second recording rotary heads and having a head width Tw = 3Tp (where Tp is a track pitch); , And one lower edge of the second recording rotary head coincides with the lower edge of the servo head, and the first recording rotary head newly adds a mask section at a position corresponding to the pilot signal, A recording signal including a mask section for recording a pilot signal and a data section is recorded, and two mask sections recorded by the first recording rotary head by the second recording rotary head and a data section. To record a recording signal including and to control so that two mask sections are formed close to each other on the track formed by the first recording rotary head. A rotary head type recording apparatus comprising a recording control means.

Further, according to the present invention, in the rotary head type recording / reproducing apparatus in which the digital signal is recorded as an oblique track on the tape-shaped recording medium by the rotary head rotating at a predetermined speed, the azimuths are different from each other. It has the same azimuth as the first and second recording rotary heads and one of the first and second recording rotary heads, and has a head width Tw = 3Tp (where Tp is a track pitch). The servo head for recording the selected pilot signal and the lower edge of one of the first and second rotary heads for recording coincides with the lower edge of the servo head, and the first rotary rotation for recording is performed. The head generates a recording signal including a mask section at a position corresponding to the pilot signal, a mask section for newly recording the pilot signal, and a data section. Recorded, and the second recording rotary head to record the two masks interval recorded by the first recording rotary head, a recording signal and a data section,
Recording control means for controlling the two mask sections to be formed close to each other on a track formed by the first recording rotary head; and first and second recording rotary heads, First of the same azimuth,
And a rotary head type recording / recording device comprising a second rotary head for reproduction and reproduction control means for generating a tracking error signal in accordance with the level relationship of pilot signals reproduced from the two mask sections by the first rotary head for reproduction.
It is a playback device.

[0009]

Data is recorded by the first rotary head with a width of 1.5 Tp, then data is recorded by the second rotary head having the same head width, and is recorded by the first and second rotary heads. The data is masked so as not to erase the pilot signal recorded by the third rotary head having a width of 3 Tp. Furthermore, the first
When overwriting with the rotary head of No. 1, data is recorded with a width of 1.5 Tp, and a mask section is provided so as not to erase the previously recorded pilot signal,
Similarly, data is recorded by the second rotary head and pilot signals are recorded by the third rotary head. Therefore, two adjacent pilot signal sections are formed on the magnetic tape in the track formed by the data recorded by the first rotary head. A tracking error signal is generated from the level relationship of the reproduction output in these pilot signal sections. Since the pilot signal is reproduced with the same azimuth, it is possible to use a short wavelength signal having a good overwrite characteristic.

[0010]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the present invention will be described below with reference to the drawings. FIG. 1 shows the head arrangement of this embodiment. Five magnetic heads are attached to the tape guide drum D that rotates at a predetermined number of rotations in the arrow direction. The magnetic tape T is wound around the tape guide drum D at a wrap angle slightly larger than 180 °. Although not shown, the magnetic tape T is fed at a constant speed in the arrow direction by a capstan and a pinch roller.

On the tape guide drum D, two recording heads Hw1 and Hw2 are mounted close to each other. The reproducing head Hr1 is attached at a position separated from the recording heads Hw1 by an angle of 180 °, and the reproducing heads Hr1 and
The reproducing head Hr2 is attached at a position separated by an angle of °. Further, a servo head Hs having the same azimuth as the recording head Hw1 and having a lower edge at the same position on the track as the azimuth of the recording head Hw1 is mounted.

The recording heads Hw1 and Hw2 and the servo head Hs have an integral structure and have a triple azimuth head configuration in which three gaps are provided very close to each other. The reproducing heads Hr1 and Hr2 have a double azimuth head configuration. Has been done. Further, the recording heads Hw1 and Hw2 have a step difference equal to the track pitch Tp in the height direction, and the reproducing heads Hr1 and Hr2 also have the same step difference. Furthermore, in order to reduce crosstalk between adjacent tracks, the azimuth of the head is set to the recording head Hw1.
And Hw2. The reproducing head Hr1, the recording head Hw1, and the servo head Hs have the same azimuth, and the reproducing head Hr2 and the recording head Hw2 have the same azimuth.

Further, the head width Tw of the recording heads Hw1 and Hw2 is selected to be 1.5 Tp. Tp
Is the track pitch. Reproduction heads Hr1 and H
Similarly, the head width Tr of r2 is selected to be 1.5 Tp. The head width Ts of the servo head Hs is selected to be 3Tp.

The recording operation performed by the head tape mechanism arranged as shown in FIG. 1 will be described with reference to FIG. First,
The preceding recording head Hw1 records a digital recording signal with a width of 1.5 Tp. The digital recording signal recorded on one track includes, for example, a data section, a mask section, an ATF pilot signal section, and a data section. The mask section is a section where the supply of the recording current to the recording head Hw1 is blocked, and the ATF pilot signal section is a section where the recording current is supplied to the servo head Hs. Note that, similarly to the following description, diagonal tracks are illustrated as horizontal tracks, and diagonal lines with respect to the tracks indicate the azimuths of the recording heads Hw1 and Hw2 and the servo head Hs that recorded the tracks. It represents.

The recording head Hw1 overlaps the track formed by the recording head Hw1 with a width of 0.5 Tp.
w2 performs a recording (overwriting) operation. Recording head Hw
The recording operations of 1 and Hw2 are performed almost at the same time,
In FIG. 2, the recording operation of each head is shown separately for easy understanding. Then, the ATF pilot signal is recorded with a width of 3 Tp by the servo head Hs. This pilot signal is applied to the recording heads Hw1 and Hw2.
Recording (overwriting) is performed so as to overlap the track recorded by. Further, the recording head Hw1 scans the magnetic tape T again, and the recording data is overwritten with the track formed by the recording head Hw2 with an overlapping width of 0.5 Tp.

The recorded pilot signal is recorded so as to be overwritten on the track formed by the recording heads Hw1 and Hw2, and as a result, remains unerased. However, in addition, the recording head H
When w1 overwrites the recording data, the recording head Hw
In the case of 1, the recorded pilot signal remains without being erased by providing the mask section. As described above, by repeating the recording operation shown in FIG. 2, a recording section of the pilot signal having a width of 3 Tp is formed at a predetermined position on the tape. Focusing on the track formed by the recording head Hw1, a pilot signal section in contact with one track edge and a pilot signal section in contact with the other track edge are formed in this track. Here, the print head Hw2 does not have a mask section, but it is possible to provide a mask section.

The circuit configuration shown in FIG. 3 is used to perform the above-described recording operation. 3, print data for the print head Hw1 is supplied to the input terminal 1 and print data for the print head Hw2 is supplied to the input terminal 2. The input terminal shown by 3 is AT
A pilot signal for F is supplied. The frequency of this pilot signal can be selected as a frequency at which overwriting can be performed well. For example, the maximum frequency of recorded data is 2
When it is set to 6 MHz, 6.5 MHz which is a quarter frequency
z. The value of this frequency is the ATF in the previously proposed digital audio tape recorder.
It is sufficiently higher than the frequency of the pilot signal for use.

A timing reference signal is supplied to the input terminal indicated by 4. This timing reference signal is a signal that is formed based on the drum servo reference signal and the like, and is synchronized with the trace of the rotary head. Formatting circuit 5a
Receives the data from the input terminal 1 and the timing reference signal from the input terminal 4, and generates print data for the print head Hw1. Formatting circuit 5b
Generates print data for the print head Hw2.
The formatting circuits 5a and 5b use a predetermined track format (for example, FIG. 2) based on the timing reference signal.
(Shown in (1)) is generated.

These recording data are recorded by the recording amplifiers 6a and 6a.
It is supplied to the recording heads Hw1 and Hw2 via b and a rotary transformer (not shown), respectively. Recording amplifier 6
The write enable signal WEN1 is supplied from the formatting circuit 5a to a. The write enable signal WEN2 is also supplied from the formatting circuit 5b to the recording amplifier 6b. Further, the timing reference signal supplied from the input terminal 4 is supplied to the write enable signal generating circuit 7, and the write enable signal generating circuit 7 is supplied.
The write enable signal WENs generated in 1 is supplied to the recording amplifier 8. In the recording amplifier 8, the pilot signal supplied from the input terminal 3 is supplied to the servo head Hs according to the write enable signal WENs.

FIG. 4 is a more specific example of a recording pattern to which the present invention is applied. Position of data and pilot signal on magnetic tape and recording heads Hw1, Hw
2, the positions of the servo head Hs and the reproducing heads Hr1 and Hr2 are shown. At the time of recording, after the data is recorded via the recording heads Hw1 and Hw2, the pilot signal for ATF is recorded via the servo head Hs. At the time of reproduction, the data is reproduced via the reproduction heads Hs1 and Hs2.

Next, a process of reproducing the magnetic tape having the above recording pattern by the reproducing heads Hr1 and Hr2 will be described. The pilot signal for ATF is the recording head H
Since the recording is performed by w1, the tracking control is performed by using the reproduction output signal of the reproducing head Hr1 whose azimuth is the same as that of w1.

FIG. 5 shows an example of a configuration for processing the reproduction signal of the reproduction head Hr1. For simplification, in FIG. 5, the configuration of processing of reproduced digital data (code data, audio data, video data, etc.) is omitted. The reproduction signal of the reproduction head Hr1 is passed through the reproduction amplifier 11 and a rotary transformer (not shown) to the filter 1
2 is supplied. The read enable signal REN is supplied to the reproduction amplifier 11, and the reproduction amplifier 11 is activated when the enable signal is at a high level. The filter 12 has a band centered on the frequency of the pilot signal, and the reproduction pilot signal is separated from the output thereof.

The reproduced pilot signal is supplied to the envelope detection circuit 13 and the position detection signal generation circuit 14.
The detection output of the envelope detection circuit 13 is the A / D converter 1
5 is supplied. The output signal of the position detection signal generation circuit 14 is supplied to the sampling timing generation circuit 16,
A sampling pulse for the / D converter 15 is generated. The detection data TE1 and TE2 sampled by the A / D converter 15 and digitized are stored in the memory (or register) 17.

These detection data TE1 and TE2 are supplied to the subtractor 18, and the output of the subtractor 18 represented by TE1-TE2 is supplied to the adder 19. A digital speed error signal for the capstan motor is supplied from the input terminal 20 to the adder 19. The digital speed error signal output from the adder 19 to the output terminal 21 is supplied to the drive circuit of the capstan motor. In this embodiment, tracking is controlled by controlling the rotation speed of the capstan motor, that is, the tape feed speed, but a means for changing the head height is provided to move the head trace position. Thus, tracking may be controlled.

FIG. 6 is an enlarged view showing an example of a state where the reproducing head Hr1 traces a track on the tape. Paying attention to three consecutive tracks T _i-1, T _{i, and} T _{i + 1} on the tape, the reproducing head Hr1 traces the track T _i at the position shown in the figure. As described above, the pilot signals SP1, SP2, SP3, ... Are recorded in the width of three tracks. First, the pilot signal SP2 is transmitted to the reproducing head Hr.
1 reproduces, and then the reproducing head Hr1 reproduces the pilot signal SP3. Therefore, as shown in FIG. 7, during the reproduction operation in which the read enable signal REN is at the high level, the filter 12 outputs the reproduction pilot signal SP.
2 and the reproduction pilot signal SP3 are separately output.

[0026] As in the example of FIG. 6, in the case of trace position shifted to the side of the track T _i-1 from the center of the track T _i, it is large reproduced pilot signal SP3 than the level of the reproduced pilot signal SP2. The detection output of the envelope detection circuit 13 has the same level relationship as shown in FIG. Further, the position detection signal generation circuit 14 generates a position detection signal which is at a high level while the reproduction pilot signal is being generated from the filter 12.

This position detection signal is supplied to the sampling timing generation circuit 16 and sampling pulses S1 and S having a predetermined phase with respect to the rising edge of the position detection signal.
2 is generated. The time difference t between the sampling pulses S1 and S2 corresponds to the interval between the recording positions of the adjacent pilot signals. The sampling pulses S1 and S2 are supplied to the A / D converter 15, and the envelope detection circuit 1
The pilot envelope signal from 3 is sampled and converted to a digital signal. In FIG. 7, the output signal of the A / D converter 15 generated by sampling is TE
It is represented by 1 and TE2. In this example, TE1 <TE
It is 2.

Then, in the subtractor 18, TE1-T
A tracking error signal of E2 is formed. The polarity and value of this tracking error signal indicate the direction and amount of tracking error. If, in the example of FIG.
If the reproducing head Hr1 traces the center of the track T _i , TE1 = TE2. Further, unlike the example of FIG. 6, when the reproducing head Hr1 is displaced toward the track T _{i + 1} , the relationship of TE1> TE2 is established. In this way, a tracking error signal indicating the direction and amount of the tracking error is formed. Since the capstan motor is controlled by this tracking error signal,
Tracking error can be reduced.

The other reproducing head Hr2 cannot reproduce the pilot signal because the azimuth is different, but only the tracking control by the reproducing head Hr1 is sufficient. In addition, the configuration for forming the tracking error signal shown in FIG.
A configuration in which digital data from the D converter 15 is processed by a microcomputer can also be used.

FIG. 8 shows another embodiment of the recording pattern to which the present invention is applied. The positions of the data and pilot signals on the magnetic tape and the positions of the recording heads Hw1 and Hw2, the servo head Hs, and the reproducing heads Hr1 and Hr2 are shown. Servo head H during recording
After the pilot signal for ATF is recorded via s, the data is recorded via the recording heads Hw1 and Hw2. At the time of reproduction, the data is reproduced via the reproduction heads Hs1 and Hs2.

FIG. 9 shows an embodiment in which recording patterns are different. The positions of the data and pilot signals on the magnetic tape and the positions of the recording heads Hw1 and Hw2, the servo head Hs, and the reproducing heads Hr1 and Hr2 are shown. At the time of recording, after the data is recorded via the recording head Hw1, the pilot signal for ATF is recorded via the servo head Hs. After that, the recording head H
Data is recorded via w2. At the time of reproduction, the data is reproduced via the reproduction heads Hs1 and Hs2.

[0032]

According to the present invention, since the pilot signal is reproduced by the head having the same azimuth for tracking control, the pilot signal of short wavelength can be used.
Therefore, the overwrite characteristic can be made good, and it is possible to prevent the need for a special pilot signal erasing signal and the occurrence of unerased signals. Moreover, in this invention, 3
Since the pilot signal is recorded in the width of the track,
The reproduced signal can be used as a position detection signal, and there is an advantage that it is not necessary to separately record the position detection signal or to provide a processing circuit for the position detection signal.

[Brief description of drawings]

FIG. 1 is a schematic diagram showing a head arrangement according to an embodiment of the present invention.

FIG. 2 is a schematic diagram for explaining a recording operation of an embodiment of the present invention.

FIG. 3 is a block diagram of an example of a recording control circuit according to an embodiment of the present invention.

FIG. 4 is a timing chart used to explain a recording operation according to an embodiment of the present invention.

FIG. 5 is a block diagram of an example of a reproduction control circuit according to an embodiment of the present invention.

FIG. 6 is a schematic diagram for explaining generation of a tracking error signal in one embodiment of the present invention.

FIG. 7 is a timing chart for explaining generation of a tracking error signal in the embodiment of the present invention.

FIG. 8 is a schematic diagram of an example of a track pattern formed according to the present invention.

FIG. 9 is a schematic diagram of another example of the track pattern formed according to the present invention.

[Explanation of symbols]

 D Tape guide drum Hw1, Hw2 Recording head Hr1, Hr2 Playback head

Claims (5)

[Claims] 1. A rotary head type recording apparatus in which a digital signal is recorded as an oblique track on a tape-shaped recording medium by a rotary head rotating at a predetermined speed, wherein first and second azimuths are different from each other. And the same azimuth as one of the first and second recording rotary heads, and the head width Tw = 3Tp (however, Tp
Is a track pitch), a servo head for recording a selected pilot signal, a lower edge of one of the first and second rotary heads for recording, and a lower edge of the servo head. In agreement, the first recording rotary head records a recording signal including a mask section at a position corresponding to the pilot signal, a mask section for newly recording a pilot signal, and a data section, A second recording rotary head records a recording signal including the two mask sections recorded by the first recording rotary head and a data section, and is formed by the first recording rotary head. And a recording control means for controlling so that two mask sections are formed close to each other on a track. 2. The rotary head type recording apparatus according to claim 1, wherein the pilot signal is selected as a frequency capable of overwriting by data and the pilot signal. 3. A rotary head type recording / reproducing apparatus in which a digital signal is recorded as an oblique track on a tape-shaped recording medium by a rotary head rotating at a predetermined speed. The second recording rotary head has the same azimuth as one of the first and second recording rotary heads, and the head width Tw = 3Tp (however, Tp
Is a track pitch), a servo head for recording a selected pilot signal, a lower edge of one of the first and second rotary heads for recording, and a lower edge of the servo head. In agreement, the first recording rotary head records a recording signal including a mask section at a position corresponding to the pilot signal, a mask section for newly recording a pilot signal, and a data section, A second recording rotary head records a recording signal including the two mask sections recorded by the first recording rotary head and a data section, and is formed by the first recording rotary head. Recording control means for controlling so that the two mask sections are formed close to each other on the track, and the first and second recording rotations. Head, and a first and second reproducing rotary heads each having the same azimuth, and a tracking error signal is generated according to a level relationship between pilot signals reproduced from the two mask sections by the first reproducing rotary head. A rotary head type recording / reproducing apparatus comprising a reproducing control means for performing the operation. 4. The rotary head type recording apparatus according to claim 1 or 2, wherein the first and second rotary heads for recording and the servo head are arranged very close to each other. Rotating head type recording device. 5. The rotary head type recording / reproducing apparatus according to claim 3 or 4, wherein the first and second recording rotary heads and the servo head are arranged very close to each other. A rotary head type recording / reproducing apparatus characterized in that the second reproducing rotary head and the second reproducing rotary head are arranged at a facing interval of 180 ° with respect to the first and second recording rotary heads.