JPS6123566B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a magnetic tape control system, and in particular, in a device in which the stop position on the beginning of tape marker changes, when writing data, it is possible to The present invention relates to a method for controlling a magnetic tape so that a remaining portion of a data recording density mark (hereinafter referred to as an island) does not occur.

In order to detect the beginning and end of the magnetic tape, reflective markers made of aluminum foil, for example, are attached to the back surface of the tape. Nowadays, when writing new data onto a magnetic tape, a Beginning of Tape Marker (hereinafter referred to as BOT) is attached to the beginning of the magnetic tape.
is detected by a photo sensor and data is written. However, since the BOT has a certain length, there may be a slight discrepancy in the stop position of the magnetic tape when the magnetic tape is driven in the forward direction and when it is driven in the reverse direction. occurs.

That is, as shown in FIG. 1, a BOT 2 made of, for example, aluminum foil is attached to the starting end of the magnetic tape 1. A photo sensor 3 is provided to detect this BOT2. The magnetic tape device is further provided with an erase head 4, a write head 5, a read head 6, etc. Now, when detecting BOT2 by driving the magnetic tape 1 in the forward direction from the winding start end, when the photo sensor 3 faces the front edge 2-1 of BOT2, as shown in A', the Upon receiving the reflected light,
BOT2 is detected and the running of the magnetic tape 1 is stopped. However, when detecting BOT2 by driving the magnetic tape 1 in the so-called reverse direction, such as in a rewinding state, the photo sensor 3 is
When facing the trailing edge 2-2 of BOT2, it receives reflected light from BOT2, detects BOT2, and stops the running of magnetic tape 1.

Therefore, when the magnetic tape 1 is driven in the forward direction and stops when BOT2 is detected, and when the magnetic tape 1 is driven in the reverse direction,
In the case where the magnetic tape 1 is stopped due to the detection of BOT2, there is a discrepancy in the stopping position of the magnetic tape 1 by an amount corresponding to the length b of BOT2. That is, as shown in FIG. 1B, when the magnetic tape 1 is driven in the forward direction, the BOT 2 is detected and stopped, and data is then written, the recording density indicator ( (hereinafter referred to as IDBST)
The first position of is located at point A, write head 5
However, as shown in FIG. 1C, if BOT2 is detected while the magnetic tape 1 is being rewound in the opposite direction, the write head 5 will be located corresponding to point B. .

Therefore, even if new data is written in the state shown in Figure 1C, the part between points A and B, that is, the period corresponding to the length b of BOT2, is the previously recorded data. The data will remain as is. Therefore, if writing is performed at a recording density different from the previous data recording density, an IDBST different from the newly written one at the beginning of the tape remains, resulting in so-called old IDBST islands 1-2.
When reading this magnetic tape, the real IDBST
Before reading part 1-1 where the above was recorded,
Since we will be reading IDBST islands 1-2,
Misidentification of IDBST or inability to determine IDBST may occur. In addition, if this magnetic tape is an existing tape that records important content, and if it becomes unplayable only when it is read six months after its creation, it is necessary to create the tape again. It requires considerable cost and time.

In order to prevent such IDBST islands 1-2 from occurring, conventional methods have been used to always keep the magnetic tape stop position constant, or to detect BOT once even if there is a discrepancy in the magnetic tape stop position. A method has been considered, such as stopping the BOT, then moving the magnetic tape to a point where it no longer detects the BOT, and then starting writing, but both methods require a complicated configuration to control the device. In the latter method, if the BOT breaks, the direction of light reflection changes, causing an error in BOT detection, and if the BOT becomes dirty or has dust, it becomes difficult to reflect light, which also causes malfunctions. It was hot.

In order to prevent such islands from occurring, the present invention provides a BOT detector that detects the BOT provided on the magnetic tape when recording information on the magnetic tape, and an output signal of the BOT detector and the writing. a tape drive device that drives a magnetic tape by a signal;
A tape length detector that detects the length of the magnetic tape to be driven; and a running control device that controls the tape drive device in response to a signal from the tape length detector. The magnetic tape first runs in the forward direction and is stopped by the output signal of the BOT detector, and the other case the magnetic tape first runs in the reverse direction and is stopped by the output signal of the BOT detector. When detecting the BOT mentioned above and recording the recording density mark, the magnetic tape is first moved relatively in the reverse direction, and then the magnetic tape is moved relative to each other by a certain distance in the forward direction. The recording density mark is moved, the recording density mark that has already been recorded is erased, and a new recording density mark is recorded.

An embodiment of the present invention will be described below with reference to FIGS. 2 and 3.

In FIG. 2, 1, 3, 4, 5, and 6 indicate the same parts as the same reference numerals in FIG. 7 is capstan roller, 8, 18, 20 is and gate, 9
is a photo sense amplifier circuit, 10, 11, 14, 1
9 and 23 are flip-flops, 12 and 22 are OR gates, 13 is a capstan control circuit, 15 is a tacho pulse detector, 16 is a tacho pulse counter, 1
7, 17' are decoding circuits, 21 is a read/write circuit, 24, 25, 26, 32 are inverters,
Reference numeral 27 indicates a signal circuit for creating a recording density marker, 28 a modulation circuit, 29 a demodulation circuit, 30 a write data/read data buffer circuit, and 31 a slit provided in the capstan.

The basic idea of the present invention will be explained with reference to FIG. As shown in FIG. 3A, when the magnetic tape 1 is driven in the forward direction and the BOT 2 is detected by the photo sensor 3 at its front edge 2-1, the magnetic tape 1 is moved in the opposite direction by a length l ₁ from the stopped position. let it run,
The write head 5 moves the magnetic tape 1 to a position corresponding to the magnetic tape 1 at point E. On the other hand, when the magnetic tape 1 is driven in the unwinding direction, that is, in the reverse direction, and the BOT 2 is detected by the photo sensor 3 at the rear edge 2-2, the magnetic tape 1 is moved in the opposite direction by a length l ₂ from the stopped position. run it. This length l ₂ is equal to the length l ₁ plus the width b of BOT2. Therefore, when driven in the opposite direction by a length l ₂ , the write head 5
corresponds to magnetic tape 1 at point E.

As mentioned above, once BOT2 is detected and the magnetic tape 1 is stopped, the magnetic tape 1 is sent in the opposite direction by a length of _l1 or _l2 , and after the write head 5 and the magnetic tape 1 correspond at point E, The magnetic tape 1 is put in a writing state and is run for a length l ₃ in the forward direction, and information recorded on the medium is erased only from this length l ₃ . and light head 5 at point S
If you write IDBST when the BOT has reached the position, even if there is some error in the BOT detection position, you can erase a sufficient range to compensate for this error.
The conventional drawback of IDBST islands is improved.

A specific configuration of the present invention will be explained with reference to FIG.

First, when the magnetic tape 1 is set in the magnetic tape unit MTU and driven in the forward direction, the photo sensor 3 detects the BOT 2 at its leading edge 2-1, and the detection signal is amplified by the photo sense amplifier circuit 9. is transmitted to the flip-flop 10, a logic "1" is generated from the flip-flop 10, and the logic "1" is applied to one input terminal of the AND gate 8. When the photo sensor 3 detects the BOT 2, the magnetic tape unit MTU stops driving the magnetic tape 1, as is well known. When a write command for instructing to write information on the magnetic tape 1 is transmitted from the terminal T-1 while the magnetic tape 1 is stopped, the flip-flop 19 outputs a logic "1" and at the same time the AND gate 8 outputs a logic "1". "1"
causes the flip-flop 11 to generate a logic "1", and the OR gate 12 transmits a reverse rotation signal to the capstan control circuit 13. Then, after a certain period of time has elapsed, when a command is applied from the terminal _T3 to instruct the necessary tape running timing, the flip-flop 14 generates a logic "1" and becomes a drive signal for the capstan 7, and the flip-flop 14 generates a logic "1" and becomes a drive signal for the capstan 7. When the magnetic tape 1 is rotated in a certain opposite direction, the magnetic tape 1 is also run in the opposite direction.

As shown in FIG. 2B, the capstan 7 is provided with a plurality of slits 31, and as the capstan 7 rotates, the light pulses passing through the slits 31 are detected by the tacho pulse detector shown in FIG. 2A. 15, and the number of pulses is counted by a tacho pulse counter 16. Therefore, when the pulse of light instructing the rotation of the capstan 7 corresponding to the length _l1 is counted by the tacho pulse counter 16, an output is generated from the decoding circuit 17, which passes through the OR gate 22 and resets the flip-flop 14. Then, the driving of the capstan 7 is stopped.
As a result, the magnetic tape 1 runs in the opposite direction by the length _l1 , and the write head 5 becomes in a state corresponding to point E, as shown in FIG. 3B. Further, the flip-flop 11 is reset by the output of the decode circuit 17, and the inverter 25 outputs a logic "1", thereby preparing the capstan control circuit 13 to drive the capstan 7 in the forward direction.

As the flip-flop 11 is reset, the inverter 24 also generates a logic "1", causing the AND gate 20 to generate a logic "1" and instructing the read/write circuit 21 to read/write.
Then, when the tape running necessary timing command is applied again from the terminal _T3 , the flip-flop 14
outputs a logic "1" and drives the capstan 7 so as to run the magnetic tape 1 in the forward direction,
An output is produced when the tacho pulse counter 16 counts pulses corresponding to length _l3 . magnetic tape 1
When the inverter 32 travels in the forward direction, the output of the inverter 32 is applied to the tacho pulse counter 16, and the output of the tacho pulse counter 16 is provided to the decoding circuit 17', so that the IDBST etc. generation signal circuit 27 is activated. , via modulator 28
IDBST write signal occurs when magnetic tape 1 has length l ₃
After the write head 5 has traveled for the length of time, as shown in FIG.

Also, when magnetic tape 1 is in the rewind state,
When the trailing edge 2-2 of BOT2 is detected by the photo sensor 3 and is stopped, a backward command is applied from the terminal _T2 for rewinding, so a logic "1" is output from the flip-flop 23. This output is applied to the capstan control circuit 13 through the OR gate 12. At the same time, the logic "1" of the flip-flop 23
The output of is also applied to the decoder 17. On the other hand, since the photo sensor 3 is detecting the trailing edge 2-2 of the BOT 2, the flip-flop 10 is producing a logic "1".

In this state, when a write command is transmitted from the terminal T-1, the capstan 7 causes the magnetic tape 1 to run in the opposite direction in the same manner as in the above case. However, since the logic "1" from the flip-flop 23 is applied to the decoding circuit 17 as described above, the output of the tacho pulse counter 16 does not operate when the magnetic tape running length is _l1 .
It is configured to operate in the case of l ₂ .

Therefore, when the magnetic tape 1 is run in the reverse direction by a length _l2 , an output is generated in the decoding circuit 17, which causes the flip-flop 14 to be reset via the OR gate 22, and the capstan 7 to be stopped. At this time, as shown in FIG. 3C, the magnetic tape 1 stops at a position corresponding to the write head 5 at point E.

Therefore, in the same manner as in the above case, after the magnetic tape has traveled forward by the length l ₃ and the information previously recorded on the magnetic tape 1 during that time has been erased,
IDBST will be newly written from point S onwards.

After that, write information as usual. That is, when a write signal is transmitted from the terminal _T4 , the write signal is applied to the write head 5 via the write data/read data buffer circuit 30 and the modulation circuit 28, and the desired information is written on the magnetic tape 1. written. Further, the information read from the read head 6 is transferred to the demodulation circuit 29 and the write data/read data buffer circuit 30.
It can be taken out from terminal _T5 via.

As explained above, according to the present invention, when new information is written on the magnetic tape 1, even when the leading edge 2-1 of the BOT 2 is detected and stopped, the trailing edge 2-1
2, even if the magnetic tape is detected and stopped, the magnetic tape is further run backwards by a distance corresponding to the stopped position, and the magnetic tape is restarted from the same point for a certain length while erasing the information that has already been recorded. Since new information is recorded after the vehicle is run, it is possible to completely solve the problem of the conventional IDBST islands. In this case, as mentioned above, if the BOT breaks, the direction of light reflection will change, causing an error in BOT detection, and if the BOT becomes dirty or has dust attached to it, light reflection will be less likely to occur.
This also had the drawback of causing malfunctions, but with the present invention, even if there is some error in the detection position of the BOT for the reasons mentioned above, when the BOT is detected in the opposite direction, the error will be greater than the length of the BOT plus the error. The vehicle is controlled to travel in the reverse direction for a long time, and when the BOT is detected in the forward direction, the vehicle is controlled to travel in the reverse direction for a longer time than the error, so even if there is a slight error in the BOT detection position as described above, it will not have a negative effect. do not have.

Furthermore, the present invention provides a flip-flop that stores the detection of B0T, a flip-flop that stores the write command, and a flip-flop that stores the write command in the load state.
It can be easily configured by adding a very small mechanism, such as a circuit that changes the length of the magnetic tape to be rewinded when BOT is detected and when BOT is detected in the rewind state.

[Brief explanation of the drawing]

FIG. 1 is a diagram explaining the problems of conventional magnetic tape control, FIG. 2 is a diagram showing an embodiment of the present invention, and FIG. 3 is a diagram explaining the basic functions of the present invention. In the figure, 1 is a magnetic tape, 2 is a BOT, 3 is a photo sensor, 4 is an erase head, 5 is a write head, 6 is a read head, 7 is a capstan roller, 8, 18, 20 are AND gates, 9 is a photo sense Amplifier circuit, 10, 11, 14, 19, 23
is a flipflop, 12 and 22 are or gates,
13 is a capstan control circuit, 15 is a tacho pulse detector, 16 is a tacho pulse counter, 17, 17'
is a decoding circuit, 21 is a read/write circuit, 2
4, 25, 26, 32 are inverters, 27 is
IDBST etc. created signal circuit, 28 is modulation circuit, 29
3 shows a demodulation circuit, 30 a write data/read data buffer circuit, and 31 a slit provided in the capstan.

Claims (1)

[Claims] 1. A BOT detector that detects a beginning of tape marker provided on a magnetic tape when recording information on the magnetic tape, and a tape drive device that drives the magnetic tape using the output signal and write signal of the BOT detector. a tape length detector that detects the length of the magnetic tape being driven; and a running control device that controls the tape drive device in response to a signal from the tape length detector, and the running control device includes: The magnetic tape first runs in the forward direction and is stopped by the output signal of the BOT detector, and the other case the magnetic tape first runs in the reverse direction and is stopped by the output signal of the BOT detector. When detecting the beginning of tape marker and recording the recording density mark, the magnetic tape is first relatively moved in the reverse direction, and then the magnetic tape is moved in the forward direction. A magnetic tape control system characterized in that the magnetic tape is relatively moved a certain distance to erase a recording density mark that has already been recorded, and a new recording density mark is recorded.