JPH08147818A - Tape speed controller - Google Patents

Abstract

PURPOSE: To avoide the damage to a tape by feeding the tape at a high speed before reaching the vicinity of the tape terminal and at a low speed when coming very close to the terminal. CONSTITUTION: In a fixed speed mode, a tape length is calculated by a tape length arithmetic circuit 3 and the ratio of the rotation cycle of a winding reel 11 to that of a feeding reel 12 in the vicinity very close to the terminal of a tape 13 is calculated by a target cycle ratio calculating circuit 5. In a high-speed winding mode, a terminal vicinity detecting circuit 6 compares the ratio of the rotation cycle of a winding reel 11 to that of a feeding reel 12 calculated by a reel cycle ratio calculating circuit 4 with the ratio of the rotation cycle of a winding reel 11 to that of a feeding reel 12 in close vicinity to the terminal of the tape 13 calculated by the target cycle ratio calculating circuit 5 and controls the operation of a motor 8 so as to feed the tape 13 at a high speed before reaching the vicinity very close to the terminal, then at a low speed after passing through the close vicinity of terminal.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a tape speed control device used for high-speed music selection search processing, high-speed tape fast-forward processing, etc. in a voice recording / reproducing apparatus such as a DCC (Digital Compact Cassette Tape Recorder).

[0002]

2. Description of the Related Art In recent years, a magnetic recording / reproducing apparatus such as a DCC for recording / reproducing an audio signal on a magnetic tape has been put into practical use. In such a device, high-speed running of the magnetic tape, such as high-speed music selection search and high-speed fast-forward, is realized, but in order to avoid damage caused by plunging into the end of the magnetic tape at high speed, high speed is achieved until reaching the end. After feeding the magnetic tape and passing it near the end, it is necessary to feed the magnetic tape at a low speed. An example of a conventional tape speed control device will be described below with reference to the drawings.

FIG. 2 is a block diagram showing a schematic configuration of a conventional tape speed control device. As shown in FIG.
This tape speed control device has a winding side reel stand 29
The first cycle detection circuit 21 that detects the cycle of rotation of the (winding reel 31) and the supply-side reel stand 30 (supply reel 3
A second cycle detection circuit 22 for detecting the rotation cycle of 2) is provided. Further, a reel cycle ratio calculation circuit 23 that calculates the ratio of the rotation cycles of the take-up reel 31 and the supply reel 32 based on the output signal from the first cycle detection circuit 21 and the output signal from the second cycle detection circuit 22. From the reel cycle ratio maximum value storage circuit 24 for storing the maximum value of the rotation cycle ratio obtained based on the output signal from the reel cycle ratio calculation circuit 23. A target cycle ratio calculation circuit 25 for calculating the ratio of the rotation cycles of the take-up reel 31 and the supply reel 32 at the position near the end is provided based on the output signal. Further, the output signal of the reel cycle ratio calculation circuit 23 and the target cycle ratio calculation circuit 25
End proximity detection circuit 26 for comparing the output signals of the magnetic tape 3 and the magnetic tape 3 based on the output signal from the end proximity detection circuit 26.
A motor control circuit 27 is provided to control the rotation speed of the motor 28 so as to change the winding speed of No. 3.

Next, the operation of the conventional tape speed control device thus constructed will be described. First, the motor 28 is driven to rotate the winding-side reel stand 29 and the supply-side reel stand 30, and the first cycle detection circuit 2
The rotation cycle signals of the winding-side reel stand 29 and the supply-side reel stand 30 are input to the reel cycle ratio calculating circuit 23 from the first and second cycle detecting circuits 21, respectively. The reel cycle ratio calculation circuit 23, based on these signals, takes up the take-up reel 31.
And the rotation cycle of the supply reel 32 are calculated and output to the reel cycle ratio maximum value storage circuit 24 and the end vicinity detection circuit 26. Reel cycle ratio maximum value storage circuit 24
Constantly updates the maximum value of the ratio of the rotation cycles of the take-up reel stand 29 and the supply reel stand 30 based on the output signal from the reel cycle ratio calculating circuit 23, and outputs the signal to the target cycle ratio calculating circuit 25. To do. The target cycle ratio calculation circuit 25, based on the signal from the reel cycle ratio maximum value storage circuit 24, determines the rotation cycle of the take-up reel base 29 and the supply reel base 30 from the end position of the magnetic tape 33 to the vicinity of the end position. By subtracting the ratio, the reel cycle ratio at the end vicinity position (hereinafter, referred to as the end vicinity reel cycle ratio) is calculated, and the signal is output to the end vicinity detection circuit 26. The end vicinity detection circuit 26 compares the period ratio signal output from the reel period ratio calculation circuit 23 with the signal output from the target period ratio calculation circuit 25, and outputs the comparison result signal to the motor control circuit 27. To do. The motor control circuit 27 feeds the magnetic tape 33 at high speed until it reaches the end near the end based on the comparison result in the end close detection circuit 26 in the high-speed winding mode of the magnetic tape 33 such as the music selection search and the fast-forward mode. Further, after passing through the position near the end, operation control is performed to feed the magnetic tape 33 at a low speed.

As described above, even in the conventional tape speed control device, the magnetic tape 33 can be run at high speed and decelerated near the end, and damage to the magnetic tape 33 can be avoided.

[0006]

However, such a conventional tape speed control device has the following problems. First, in the case of the operation of the control circuit shown in FIG. 2 in the high speed mode near the center of the tape, the target period ratio calculating circuit 25 calculates the reel period ratio from the vicinity of the center of the magnetic tape 33 to the end thereof, and The tape end speed deceleration processing is executed based on the result of comparison between the reel cycle ratio signal output from the reel cycle ratio calculating circuit 23 and the near end reel cycle ratio signal. In this case, the reel cycle ratio near the end of the magnetic tape 33 near the center has almost no difference in the winding diameters of the tapes.
The value is far from the maximum value of the reel cycle ratio of the magnetic tape 33. Therefore, when processing such as fast-forwarding is performed by the processing operation in the high-speed winding mode, the operation of the magnetic tape 33 up to the first end is performed by decelerating considerably before the position near the end and once reaching the end. The deceleration processing operation will be performed near the end position. As a result, the magnetic tape 33 whose end-to-end reel cycle ratio is known near the end can be decelerated near the end, but the end-to-end reel cycle ratio is found near the center of the tape. With respect to 33, since deceleration processing is performed near the center of the tape, the terminal deceleration processing differs depending on the winding state of the magnetic tape 33, and in the worst case, the magnetic tape 33 continues tape speed control in the deceleration processing state. was there.

The present invention solves the above-mentioned conventional problems, regardless of the winding state of the magnetic tape.
(EN) Provided is a tape speed control device which can set the cycle ratio of the rotation of a take-up reel and a supply reel at the position near the end to an optimum value of the tape and can always perform the end deceleration processing near the end of the tape. The purpose is.

[0008]

In order to achieve the above object, a tape speed control device according to a first aspect of the present invention comprises a first cycle detecting means for detecting a cycle of rotation of a take-up reel and a rotation of a supply reel. And a tape length calculating means for calculating the tape length of the magnetic tape based on the output signal from the first cycle detecting means and the output signal from the second cycle detecting means. A target cycle ratio calculating means for calculating the ratio of the rotation cycles of the take-up reel and the supply reel at the position near the end of the magnetic tape based on the output signal from the tape length calculating means, and the first cycle detecting means. Reel cycle ratio calculation means for calculating the ratio of the rotation cycle of the take-up reel and the supply reel based on the output signal and the output signal from the second cycle detection means, and the output signal of the reel cycle ratio calculation means and the target cycle ratio calculation An end vicinity detection means for detecting the vicinity of the end of the magnetic tape based on the output signal of the stage, and a motor operation to change the winding speed of the magnetic tape based on the output signal from the end vicinity detection means. And a motor control means for controlling the operation of the motor so that the magnetic tape is sent at high speed up to the vicinity of the end, and after passing through the position near the end, the magnetic tape is sent at low speed.

According to another aspect of the tape speed control device of the present invention, the tape length calculating means calculates the sum of the output cycle signal from the first cycle detecting means and the output cycle signal from the second cycle detecting circuit. A configuration is provided in which a signal obtained by calculating the tape length of the magnetic tape is output, and the target period ratio calculation means outputs a signal obtained by calculating the reel period ratio at the position near the end of the magnetic tape based on the output signal from the tape length calculation means. There is.

According to another aspect of the tape speed control device of the present invention, the tape length calculating means has a value of a sum of squares of an output cycle signal from the first cycle detecting means and an output cycle signal from the second cycle detecting circuit. From the tape length calculating means, and the target period ratio calculating means outputs a signal calculating the reel cycle ratio of the magnetic tape at the position near the end of the magnetic tape based on the output signal from the tape length calculating means. I am trying.

[0011]

With such a structure, the tape speed control device according to the first aspect of the present invention can detect the output signal from the first cycle detecting means in a state where the magnetic tape is fed at a fixed speed, for example, in the reproducing mode. The tape length calculation means calculates the tape length of the magnetic tape based on the output signal from the second cycle detection means, and the target cycle ratio calculation means ends the magnetic tape based on the output signal from the tape length calculation means. The ratio of the rotation cycles of the take-up reel and the supply reel in the vicinity position is calculated. Then, in a mode in which the magnetic tape is wound at a high speed, such as a music selection search or a fast-forward mode, the end-end vicinity detection means determines the ratio of the rotation cycle of the take-up reel and the supply reel calculated by the reel cycle ratio calculation means to the target cycle ratio. The ratio of the rotation cycles of the take-up reel and the supply reel at the position near the end of the magnetic tape calculated by the calculating means is compared, and based on the result, the magnetic tape is fed at high speed until the vicinity of the end, and the end of the magnetic tape is fed. After passing the vicinity position, the operation of the motor is controlled so as to feed the magnetic tape at a low speed. Therefore, regardless of the winding state of the magnetic tape,
The period ratio near the end is set to the optimum value for the magnetic tape.

According to another aspect of the tape speed control device of the present invention, the tape length calculating means determines the magnetic value based on the sum of the output cycle signal from the first cycle detecting means and the output cycle signal from the second cycle detecting circuit. The tape length of the tape is calculated, the signal is output, and the target period ratio calculating means calculates the reel period ratio in the vicinity of the end of the magnetic tape based on the output signal from the tape length calculating means and outputs the signal. To do. As a result, the tape length of the magnetic tape can be easily calculated, and the cycle ratio of the position near the end can be calculated regardless of the winding state of the magnetic tape.
It is set to the optimum value for the magnetic tape.

According to another aspect of the tape speed control device of the present invention, the tape length calculating means determines the sum of squares of the output cycle signal from the first cycle detecting means and the output cycle signal from the second cycle detecting circuit. The tape length of the magnetic tape is calculated, the signal is output, and the target period ratio calculating means calculates the reel period ratio in the vicinity of the end of the magnetic tape based on the output signal from the tape length calculating means and outputs the signal. Output. Also by this, the tape length of the magnetic tape is easily calculated, and the cycle ratio of the position near the end is set to the optimum value of the magnetic tape regardless of the winding state of the magnetic tape.

[0014]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of a tape speed control device of the present invention will be described in detail below with reference to the drawings.

FIG. 1 is a block diagram showing a schematic configuration of an embodiment of a tape speed control device of the present invention. In FIG. 1, this example shows a take-up reel stand 9 (take-up reel 1
1) A first cycle detection circuit 1 for detecting the cycle of rotation,
A second cycle detection circuit 2 for detecting the cycle of rotation of the supply-side reel stand 10 (supply reel 12), an output signal from the first cycle detection circuit 1 and an output signal from the second cycle detection circuit 2. Take-up reel 11 and supply reel 12 obtained based on
And a tape length calculation circuit 3 for calculating the tape length of the magnetic tape (hereinafter referred to as tape) 13 from the sum of the rotation cycles or the sum of squares of the rotation cycle. Furthermore, the first cycle detection circuit 1
Reel cycle ratio calculation circuit 4 for calculating the ratio of the rotation cycle of the take-up reel and the supply reel based on the output signal from the second cycle detection circuit 2 and the tape length calculation circuit 3
A target cycle ratio calculation circuit 5 for calculating the ratio of the rotation cycles of the take-up reel and the supply reel at the position near the end is provided based on the output signal from the. Further, the winding speed of the tape 13 is determined based on the output signal from the end vicinity detection circuit 6 that compares the output signal of the reel cycle ratio calculation circuit 4 with the output signal of the target cycle ratio calculation circuit 5, and the output signal from the end vicinity detection circuit 6. A motor control circuit 7 is provided for controlling the rotation speed of the motor 8 so as to change it. A belt 14 is wound around the rotation shaft of the motor 8, and the supply reel stage 10 is rotated via the belt 14 and rollers 15, 16, 17. And the tape cassette 18
When is mounted, the take-up reel 11 and the supply reel 12 are fitted to the take-up reel stand 9 and the supply-side reel stand 10, respectively. Further, the supply reel 12 rotates in accordance with the rotation of the supply-side reel stand 10, and the tape 13 wound on the take-up reel 11 is wound on the supply reel 12.

The operation of the tape speed control device of this embodiment having the above structure will be described below.

When the tape 13 is fed at a fixed speed in the reproduction mode or the like, the rotation cycle signal of the take-up reel stand 9 is input to the tape length calculation circuit 3 from the first cycle detection circuit 1. Then, the rotation cycle signal of the supply-side reel stand 10 is input from the second cycle detection circuit 2. In the tape length calculation circuit 3, the length of the tape 13 is determined from the sum of the rotation cycles of the winding side reel stand 9 and the rotation cycle of the supply side reel stand 10 or the sum of squares obtained, and the tape length decision signal is obtained. Output to the target cycle ratio calculation circuit 5.

Next, a first method for calculating the tape length of the tape 13 in the tape length calculation circuit 3 will be described. First, the winding diameter of the tape 13 wound on the take-up reel 11 is R ₁ , the winding diameter of the tape 13 wound on the supply reel 12 is R ₂ , the hub diameters of the supply reel 12 and the take-up reel 12 are R ₀ , The length of the tape 13 is L, the thickness of the tape 13 is d,
The moving speed of the tape 13 is V _t , the rotation cycle of the take-up reel stand 9 (take-up reel 11) obtained by the first cycle detection circuit 1 is T ₁ , and the rotation cycle of the tape is obtained by the second cycle detection circuit 2. The rotation cycle of the supply reel stand 10 (supply reel 12) is T ₂ .

The thickness d of the tape 13 is fixed, and the tape 1
When the moving speed V _t of the winding No. 3 is known, the winding side reel stand 9
The relationship between the rotation cycle T ₁ , the rotation cycle T ₂ of the supply-side reel stand 10 and the tape length (L) can be expressed by the following equation (Equation 1).

[0020]

[Equation 1]

Here, the tape winding diameter R2 of the supply reel 12 is
The minimum value is that there is no tape 13 on the supply reel 12.
In the case where it is not wound, in that case, the supply reel 12
Hub diameter (R₀) Is equal to. Meanwhile, the supply reel 12
Tape winding diameter R₂Is the maximum value (R _{2 (MAX)}) Is all
When all the tape 13 is wound on the supply reel 12,
Yes, maximum value (R_{2 (MAX)}) Is expressed by the following equation (Equation 2).

[0022]

[Equation 2]

The rotation period and supply of the take-up reel stand 9
Sum of rotation cycles of the side reel stand 10 (T ₁+ T₂) And tape length
Relationship with the tape winding diameter R of the supply reel 12₂Is the minimum value
To the maximum value, the DCC cassette
In the case of a loop, only about 5% changes. Therefore,
Rotation cycle of the take-up reel stand 9 and rotation of the supply-side reel stand 10
Sum of turning cycles (T₁+ T₂), You can easily
The length can be calculated.

Next, a second method for calculating the tape length of the tape 13 in the tape length calculation circuit 3 will be described.

Here, the rotation cycle (T
₁ ) and the sum of squares of the rotation period (T ₂ ) of the supply-side reel stand 10 and the tape length (L) are expressed by the following equation (Equation 3).

[0026]

(Equation 3)

Therefore, the approximate tape length can be easily calculated by using the sum of squares of the rotation cycle (T ₁ ) of the take-up reel stand 9 and the rotation cycle (T ₁ ) of the supply reel stand 10. it can. In the target cycle ratio calculation circuit 5, the reel end cycle ratio near the end corresponding to the position near the end corresponding to each tape length is calculated based on the output signal from the tape length calculation circuit 3, and the signal is calculated as the end vicinity detection circuit 6. Output to. on the other hand,
In a mode for winding a magnetic tape at a high speed, such as a music selection search or a fast-forward mode, a rotation cycle signal of the winding-side reel stand 9 is input to the reel cycle ratio calculation circuit 4 from the first cycle detection circuit 1. The rotation cycle signal of the supply reel stand 10 is input from the second cycle detection circuit 2. The reel cycle ratio calculation circuit 4 calculates the ratio of the rotation cycle of the take-up reel stand 9 to the rotation cycle of the take-up reel stand 9 based on these signals, and sends the signal to the end vicinity detection circuit 6. Output.
In the terminal end vicinity detection circuit 6, the reel cycle ratio signal output from the reel cycle ratio calculation circuit 4 and the reel cycle near the terminal end calculated from the target cycle ratio calculation circuit 5 calculated while the tape 13 is being sent at a fixed speed. The ratio signal is compared and the resultant signal is output to the motor control circuit 7. In the high-speed winding mode such as the music selection search and the fast-forward mode, the motor control circuit 7 feeds the tape 13 at high speed until it reaches the end, and after passing the position near the end, based on the comparison result in the end vicinity detection circuit 6. Controls the operation of the motor 8 to feed the tape 13 at a low speed. As a result, the tape 13 can be run at high speed and decelerated near the end. That is, damage to the tape 13 can be avoided.

As described above, in this embodiment, the output signal from the first cycle detecting circuit 1 and the second cycle detecting circuit 2 are output in a state where the tape 13 is being fed at a fixed speed, for example, in the reproducing mode. The tape length calculation circuit 3 calculates the tape length of the tape 13 based on the output signal, and the target period ratio calculation circuit 5 calculates the tape length at the position near the end of the tape 13 based on the output signal from the tape length calculation circuit 3. Since the ratio of the rotation cycles of the take-up reel 11 and the supply reel 12 is calculated, the cycle ratio of the position near the end is set to the optimum value of the tape 13 regardless of the winding state of the tape 13, and the end is always decelerated. The processing can be reliably performed near the end of the tape 13.

The present invention can be applied not only as a cassette tape for DCC but also as a tape speed control device for various cassette tapes.

[0030]

As is apparent from the above description, according to the tape speed control device of the first aspect, the tape length of the magnetic tape is in a state where the magnetic tape is fed at a fixed speed in, for example, the reproducing mode. Based on this tape length, while calculating the ratio of the rotation cycle of the take-up reel and the supply reel in the position near the end of the magnetic tape, in the mode for winding the magnetic tape at high speed such as music selection search and fast-forward mode. Compares the ratio of the rotation cycle of the take-up reel and the supply reel with the ratio of the rotation cycle of the take-up reel and the supply reel at the position near the end of the magnetic tape calculated by the target cycle ratio calculating means. Based on this, the operation of the motor is controlled so that the magnetic tape is sent at high speed until it reaches the vicinity of the end, and after passing the position near the end, the magnetic tape is sent at low speed. Therefore, the cycle ratio of the position near the end is set to the optimum value of the magnetic tape regardless of the winding state of the magnetic tape, and the deceleration process at the end can always be reliably performed near the end of the magnetic tape. This has the effect of avoiding damage.

According to another aspect of the tape speed control device of the present invention, the tape length calculating means determines the magnetic value based on the sum of the output cycle signal from the first cycle detecting means and the output cycle signal from the second cycle detecting means. Since the tape length of the tape is calculated and the reel cycle ratio at the position near the end of the magnetic tape is calculated, the tape length of the magnetic tape can be easily calculated, regardless of the winding state of the magnetic tape. The position cycle ratio is set to the optimum value of the magnetic tape, and the end deceleration processing can always be reliably performed near the end of the magnetic tape.

According to a third aspect of the present invention, in the tape speed control device, the tape length calculating means calculates the sum of squares of the output cycle signal from the first cycle detecting means and the output cycle signal from the second cycle detecting means. Since the tape length of the magnetic tape is calculated and the reel cycle ratio near the end of the magnetic tape is calculated, the tape length of the magnetic tape can be easily calculated,
Regardless of the winding state of the magnetic tape, the cycle ratio of the position near the end is set to the optimum value of the magnetic tape, and the end deceleration processing can always be reliably performed near the end of the magnetic tape.

[Brief description of drawings]

FIG. 1 is a block diagram showing the configuration of a tape speed control device according to an embodiment of the present invention.

FIG. 2 is a block diagram showing the configuration of a conventional tape speed control device.

[Explanation of symbols]

 1 1st cycle detection circuit 2 2nd cycle detection circuit 3 Tape length calculation circuit 4 Reel cycle ratio calculation circuit 5 Target cycle ratio calculation circuit 6 Near end detection circuit 7 Motor control circuit 8 Motor 9 Winding reel stand 10 Supply Side reel stand 11 Take-up reel 12 Supply reel 13 Magnetic tape

Claims (3)

[Claims] 1. A first cycle detecting means for detecting a rotation cycle of a take-up reel, and a second cycle detecting means for detecting a rotation cycle of a supply reel.
Cycle detecting means, tape length calculating means for calculating the tape length of the magnetic tape based on the output signal from the first cycle detecting means and the output signal from the second cycle detecting means, and the tape length calculating means. Based on the output signal from the means,
Target cycle ratio calculating means for calculating a ratio of rotation cycles of the take-up reel and the supply reel at a position near the end of the magnetic tape, an output signal from the first cycle detecting means, and the second cycle detecting means. Reel cycle ratio calculating means for calculating the ratio of the rotation cycle of the take-up reel and the supply reel based on the output signal from the reel, the output signal of the reel cycle ratio calculating means and the output signal of the target cycle ratio calculating means. And a motor control means for controlling the operation of the motor so as to change the winding speed of the magnetic tape based on the output signal from the end vicinity detection means. The magnetic tape is fed at a high speed up to near the end of the magnetic tape, and the magnetic tape is fed at a low speed after passing through the position near the end. Tape speed control device and controls the operation of the motor. 2. The tape length calculating means determines the tape length of the magnetic tape from the sum of the output cycle signal from the first cycle detecting means and the output cycle signal from the second cycle detecting circuit. The target period ratio calculating means outputs the calculated signal, and the target period ratio calculating means outputs a signal in which the reel period ratio at the position near the end of the magnetic tape is calculated based on the output signal from the tape length calculating means. The tape speed control device according to claim 1. 3. The tape length of the magnetic tape is calculated from the sum of squares of the output cycle signal from the first cycle detecting means and the output cycle signal from the second cycle detecting circuit, the tape length calculating means. Is output, and the target period ratio calculating means outputs a signal in which the reel period ratio at the position near the end of the magnetic tape is calculated based on the output signal from the tape length calculating means. The tape speed control device according to claim 1.