JPH0227756B2 - - Google Patents

Description

[Detailed description of the invention]

[Technical Field of the Invention] The present invention relates to an automatic cassette discriminating device for automatically discriminating the type of a cassette that is attached to or detached from, for example, a video tape recorder. [Technical Field of the Invention] In a video tape recorder using a cassette tape, a device has been developed that measures the rotation period of the reel and displays the remaining amount of tape. According to this method, the type of cassette must be known in advance, and the scale of the remaining tape display must be changed depending on the type. For this reason,
An automatic discrimination device has also been developed that automatically discriminates the type of cassette (those with different recording time lengths).
Regarding this cassette automatic discriminating device, the applicant of the present application also proposed in Japanese Patent Application No. 102419/1982. According to the above-mentioned automatic cassette discrimination device, a rotation detection device detects the rotation of the tape supply reel and take-up reel, and a rotation detection pulse of each supply reel and take-up reel is inputted to detect each rotation at a constant tape running speed v. Reel period T ₁ ,
T _{1 2} using ^the means to obtain T 2 and the early periods T ₁ and _{T 2}
+T ₂ ² is calculated and the resulting value is compared with each constant data that was previously calculated and memorized as (2π/v) ² (2R ² +Lod/π) according to the tape type. , constant data having the same or closest result value is detected, and the type of cassette tape corresponding to this constant data is determined as the tape to be used. v is the speed of the tape, R is the radius of the hub, Lo is the total length of the tape, and d is the tape thickness. [Problems with Background Art] The automatic cassette discriminating device described above is based on the premise that the tape running speed is constant. Therefore, if the running speed changes during measurement of the rotation period of the reel, there is a possibility that the determination may be incorrect. [Object of the Invention] The present invention has been made in view of the above-mentioned circumstances, and it is an object of the present invention to provide an automatic cassette discriminating device that performs correct discrimination without being affected by the running speed of the tape. [Summary of the Invention] This invention provides a rotation detection device 2 that generates pulses proportional to the rotation of a take-up reel and a supply reel.
1, 22, a rotation detection device 27 that generates a pulse proportional to the amount of tape running is provided, and the rotation detecting device 27 is provided to detect the amount of tape running obtained during each predetermined rotation period (1/2 rotation, 1 rotation, 2 rotations, etc.) of each reel. Proportional number of pulses F ₁ ,
By finding the sum F ₁ ² +F ₂ ² of each square of F ₂ ,
This is used to determine the tape type. [Embodiments of the Invention] Examples of the present invention will be described below with reference to the drawings. First, to explain the basic principle of the present invention, FIG. 1 shows the tape winding state of a general cassette tape. 11 is a hub on the take-up reel side, and 12 is a hub on the supply reel side. Now, the radius of the hubs 11 and 12 is R, the tape winding radius on the take-up reel side is γ ₁ ,
Let the tape winding radius on the supply reel side be γ ₂ . Further, the maximum winding radius of the tape 13 is assumed to be γo. Here, considering the projected area of the tape, 2π(γ ₁ ² −R ² )+2π(γ ₂ ² −R ² )=2π(γo ² −R ² ) (1) holds true. From equation (1), γ ₁ ² + γ ₂ ² = γo ² + R ² ......(2) holds true. Focusing on the right side of equation (2), this is a constant unique to the tape type. Therefore, if γ ₁ ² +γ ₂ ² of the tape loaded on the reel is found, the type of tape can be determined. Next, the hub diameter R on the right side of equation (2) is a unique value depending on the tape type. Further, the maximum tape radius γo can be determined from the tape total length Lo, tape thickness d, and hub radius R as follows. Measure the length of the tape wound on the take-up reel.
When L ₁ and the tape winding diameter at that time are γ ₁ , πγ ₁ ² = πR ² +L ₁ d ∴γ ₁ ² =R ² +L ₁ d/π (3). Therefore, the maximum winding diameter γo is determined as γo ² =R ² +Lod/π (4) by substituting L ₁ =Lo in equation (3). Here, by substituting equation (4) into equation (2), we get γ ₁ ² + γ ₂ ² = 2R ² + Lod/π (5). Here, when paying attention to the above equation (5), the right side thereof is a constant, and these values vary depending on differences in the tape overall length Lo, tape thickness d, and hub diameter R.
Therefore, if the sum of the squares of the tape winding radii of both reels, γ ₁ ² +γ ₂ ² , is known at any position on the tape, it is possible to determine the tape type. However, it is generally difficult to directly measure the winding diameter of a tape immediately after the cassette is installed in a video tape recorder. Therefore, the tape running speed v
A method has been proposed in which the rotation period T of the reel is measured and the tape winding diameter is obtained from 2πγ=vT (6). In other words, when the speed v is constant and the rotation period of each reel is T ₁ and T ₂ , T ₁ =2πγ ₁ /v ∴γ ₁ =vT ₁ /2π T ₂ =2πγ ₂ /v ∴γ ₂ =vT γ ₁ and γ ₂ are determined using the relationship ₂ /2π. However, as described above, the method for determining γ ₁ and γ ₂ requires that the tape running speed v be always constant during the measurement of the rotation periods T ₁ and T ₂ . In a typical video tape recorder, tracking servo is used not only to keep the tape traveling speed constant during playback, but also to ensure that the rotating head accurately traces the video track. Therefore, when recording a videotape, a control signal (CTL) corresponding to the video track is sent in advance.
is recorded, and during reproduction, phase control is performed using this reproduction control signal as a reference. Therefore, if the control signal is recorded accurately and completely in advance, the tape running speed v is controlled to be constant, but the control signal may be missing at the recording connection point or recording start point. The tape may be overloaded, or the previous signal may remain, resulting in an extra signal, which may cause disturbances in the servo system, causing fluctuations in the tape running speed.
In such a case, the tape winding radii γ ₁ γ ₂ obtained by measuring the rotation periods T ₁ and T ₂ are inaccurate, and the tape type may be incorrectly determined. Therefore, the method based on the assumption that the tape running speed v is constant as described above may lead to incorrect discrimination of the tape type, so in this invention, the tape running amount F for a given rotation of the reel is measured. It is something. If this tape running amount F is known, γ can be found from 2πγ=F (7). Generally, in a video tape recorder, if it is necessary to keep the tape speed accurately constant during playback operation, the tape is driven by a capstan. The capstan may be driven by a motor via a pulley or belt, or may be driven directly by the motor. In either case, a servo circuit is working to control the tape running speed accurately as described above, and a rotation detection device is connected to the motor so that pulses corresponding to the rotation angle of the motor can be obtained. has been done. The number of rotation detection pulses (FG pulses) obtained from this rotation detection device is exactly proportional to the tape running distance, so by counting the number of pulses during one rotation of the reel, it is possible to determine the circle of the reel. You can find the circumference. The rotation detection pulse generates a pulse having a frequency f when the tape is traveling v, for example. Therefore, when F pulses are obtained, the tape is considered to have moved a distance of v/f·F. (Here, v/f is a constant.) Therefore, if F pulses are obtained per reel rotation, 2πγ=v/f・F (8) From this, the tape winding radius γ can be found. Since the number of pulses F from the rotation detection device is proportional to the running distance of the tape, the tape winding radius γ can be determined without being affected by disturbances in tape running. From equation (8), the winding radii γ ₁ and γ ₂ of the take-up reel and supply reel are calculated as follows: γ ₁ =v/2πf・If the number of rotation detection pulses in one rotation of each reel is F ₁ .F ₂ F ₁ , γ ₂ = v/2πf・F ₂ ......(9) Substituting equation (9) into equation (5), (v/2πf・F ₁ ) ² + (v/2πf・F ₂ ) ² =2R ² +Lod/π ………(10) ∴F ₁ ² +F ₂ ² = (2πf/v) ²・(2R ² +Lod/π)……(
11) holds true. In equation (11), the right side has a unique value depending on the type of tape. The table below shows the total tape length Lo, tape thickness d, reel hub radius R, and rotation for 55 typical types of tapes L500, L370, L250, L165, and L125 used in VTRs known as the so-called Beta standard. For example, if the detection pulse is v=
The right side of equation (11) is calculated and shown when it is made so that f = 360 (Hz) at 20 mm/sec.

〔Effect of the invention〕

As described above, it is possible to provide an automatic cassette discrimination device that can correctly discriminate the tape type without being affected by the tape running speed.

[Brief explanation of drawings]

Figure 1 is a diagram showing the tape winding state of the cassette;
FIG. 2 is a block diagram showing an embodiment of the present invention. 21, 22... Reel rotation detection device, 23, 2
4...Rotating disk, 25...Microcomputer, 27...Motor rotation detection device, 30...Tape, 31...Capstan, 34...Motor.

Claims (1)

[Claims] 1. First and second rotation detection devices that detect the rotations of the tape take-up reel and the supply reel, respectively, and generate pulses proportional to each rotation, and rotate in conjunction with a member that directly drives the tape. determining a predetermined rotation period of each reel based on the pulses obtained from the third rotation detection device and the first and second rotation detection devices, which generate a pulse proportional to the running distance of the tape; means for determining, for each reel, the square value of the number of pulses obtained from the third rotation detection device during the predetermined rotation period of each reel; means for comparing the constant data determined by the sum and stored in the storage means, detecting the constant data closest to the sum value, and determining that the tape used is the type of cassette tape corresponding to the constant data. An automatic cassette discriminating device characterized by comprising: