JP3066710U - Video deck - Google Patents

Abstract

(57) [Summary] [Problem] To display a tape in consideration of a predetermined offset amount, and to perform a stop operation while a user or the like refers to a travel amount including the offset amount, so that a tape position to be actually stopped is required. However, there was a problem that the stop operation could not be performed. When stopping high-speed fast-forward, a tape position at the time of a stop operation is stored in a RAM, decelerated and stopped based on a predetermined deceleration pattern.
Since the positioning process of rewinding to the tape position stored in the tape is executed, stress applied to the video tape at the time of deceleration stop can be avoided, and the tape can be accurately positioned at the tape position at the time of the stop operation. It becomes possible.

Description

[Detailed description of the invention]

[0001]

[Technical field to which the invention belongs]

 The present invention relates to a video deck, and more particularly to a video deck that stops a running video tape and positions the tape position at a stop instruction timing.

[0002]

[Prior art]

 Conventionally, in a video deck of this type, when a stop instruction is issued while a video tape is running, the tape feed mechanism is mechanically stopped at the timing of the stop instruction. As such a video deck, there is a technique disclosed in Japanese Patent Application Laid-Open No. 2-146136. The technology disclosed in this publication is to display the running amount or running position of the video tape. When the video tape runs at high speed, the display of the running position is offset by a predetermined amount from the actual running position. . Then, when the operation of stopping the running of the video tape is performed, the change of the display content described above is stopped, the running speed of the video tape is reduced, and the video tape is run by the predetermined offset amount. Has been stopped from.

[0003]

[Problems to be solved by the invention]

 In the conventional video deck described above, the former video deck damages the videotape to the videotape. Also, the latter VCR is displayed in consideration of the predetermined offset amount, and the user or the like performs the stop operation while referring to the travel amount including this offset amount, so that the tape position where the user really wants to stop is displayed. Therefore, there was a problem that the stopping operation could not be performed.

[0004] The present invention has been made in view of the above problems, and is a video deck capable of accurately stopping a video tape running at a predetermined speed in a predetermined rotation direction at a desired stop position. The purpose is to provide.

[0005]

[Means for Solving the Problems]

 In order to achieve the above object, the invention according to claim 1 includes a tape feeding means for causing the video tape to run at a predetermined speed in a predetermined rotation direction at a rapid speed, and a stop instruction when stopping the running video tape. And a tape position detecting means for detecting the tape position of the video tape when the stop instruction is output, when the stop instruction output by the tape feed stop instruction means is input. When the stop instruction output by the tape feed stop instruction means is input, the tape feed means is controlled to decelerate and stop the video tape running at a predetermined speed from the tape position. Tape feed control means for executing positioning to the tape position while feeding the video tape to the tape position. .

In the invention according to claim 1 configured as described above, when the video tape mounted on the recording / reproducing mechanism is fast-forwarding at a predetermined speed and in a predetermined rotation direction, this running is performed. To provide a video deck capable of performing positioning control when a stop instruction is given when stopping, without giving stress to the video tape at the tape position at the time the stop instruction is given. In performing such positioning control, the tape feed speed is such that a video tape mounted on a recording / reproducing mechanism or the like is fast-forwarded in a predetermined rotation direction at a predetermined speed. The fast-forward indicates a mode in which the video tape travels, and may be fast-forward in the unwinding direction or fast-forward in the rewinding direction. Here, when stopping the running video tape, the tape feed stop instructing means outputs a stop instruction. When a stop instruction is output from the tape feed stop instruction means, the tape position detection means inputs the stop instruction and detects the tape position of the video tape at the time when the stop instruction is output. When the above-mentioned stop instruction is output, the tape feed control means inputs this stop instruction and controls the tape feed means. In this control, the video tape running at a predetermined speed is decelerated and stopped from the tape position, and after the deceleration and stopped, the video tape is sent to the tape position and the positioning control is executed at this tape position. That is, the video tape is decelerated and stopped by the predetermined deceleration pattern at the timing when the stop instruction is output, so that the video tape can be stopped without giving any stress. Furthermore, since the video tape is fed and positioned from the tape position stopped at the tape position at this timing, it is possible to secure the tape position where the above stop instruction was output.

[0007] Various modes can be considered for the mode in which the tape feeding means runs the video tape. As a preferred example of applying such positioning control, the invention according to claim 2 is directed to the video deck according to claim 1, wherein the tape feeding means uses a video tape mounted on a recording / reproducing mechanism. It is configured to run at high speed rapid traverse. In the invention according to claim 2 configured as described above, the tape feeding means runs the video tape mounted on the recording / reproducing mechanism at high speed and fast forward. When stopping the high-speed and fast-forward, the tape position detecting means detects the tape position at the timing when the stop instruction is output by the tape-feed stop instructing means, and the tape-feed controlling means decelerates the high-speed fast-forward by the stop instruction. At the same time, the tape is rewound to the tape position and the positioning control is executed.

In another preferred embodiment, the invention according to claim 3 is a video deck according to claim 1 or 2, wherein the tape feeding means is mounted on a recording / reproducing mechanism. The video tape is run at high speed rewind. In the invention according to claim 3 configured as described above, the tape feeding means runs the video tape mounted on the recording / reproducing mechanism at high speed rewind. When stopping the high-speed rewinding, the tape position detecting means detects the tape position at the timing when the stop instruction is output by the tape feeding stop instructing means. Is decelerated and stopped, and the tape is rewound to the tape position to execute positioning control.

When the tape feed control means obtains the tape position detected by the tape position detection means and performs positioning control, it is preferable that the tape position be stored in a memory or the like. Therefore, the invention according to claim 4 is the video deck according to any one of claims 1 to 3, wherein the tape position detecting means stores the detected tape position in a predetermined storage area, and The feed control means reads the tape position stored in the storage area and executes a predetermined control. In the invention according to claim 4 configured as described above, the tape position detecting means stores the detected tape position in a predetermined storage area. Then, the tape feed control means executes the positioning by reading the tape position stored in this storage area after the video tape is decelerated and stopped, and sending the video tape to this tape position.

In the above-described positioning control, various methods for managing the position of the tape can be considered. As a simple method for managing the tape position, the invention according to claim 5 is a video deck according to any one of claims 1 to 4, wherein the tape feeding means is used for running a video tape. In addition to counting the control signal and instructing the tape position to travel, the tape position detecting means acquires the count value and detects the tape position when the stop instruction is output. In the invention according to claim 5, the tape feeding means counts a control signal recorded in a predetermined area of the video tape when the video tape runs, and determines a tape position of the video tape. Is detected. That is, the travel distance of the running of the video tape is managed by the total of the control signals. Then, when a stop instruction is output, the tape position detecting means obtains the counter value and detects the tape position, and the tape feed control means decelerates and stops, and then performs rewinding at the timing when the stop instruction is output. Positioning is performed by sending the video tape back until the counter value of.

When the tape feeding control means performs the positioning control, if the speed at which the tape is fed is low, overrun can be prevented when the tape is stopped, so that the positioning can be more accurately realized. As an example of such a low speed, the invention according to claim 6 is a video deck according to any one of claims 1 to 5, wherein the tape feed control means controls the tape feed speed to be lower than a predetermined speed by the tape feed means. The configuration is such that positioning control is performed at a relatively low predetermined speed. In the invention according to claim 6 configured as described above, the tape feed control means executes the positioning control at a predetermined speed relatively lower than the predetermined speed of the tape feed means. In other words, if the speed is set lower than the tape running speed of the tape feeding means, it is possible to realize the stop of the video tape with higher accuracy than when stopping the running of the video tape by the tape feeding means.

[0012] Various types of deceleration patterns can be considered when the tape feed control means decelerates and stops the video tape run by the tape feed means. As an example, the invention according to claim 7 is a video deck according to any one of claims 1 to 6, wherein the tape feed control means is irrespective of the running speed of the video tape in the tape feed means. In this configuration, the tape is decelerated and stopped so that the amount of tape travel sent during deceleration and stop is substantially the same. In the invention according to claim 7 configured as described above, the tape feed control means is configured to make the tape running amount fed at the time of deceleration stop substantially equal regardless of the running speed of the video tape at the tape feed means. Decelerate and stop. In such a case, the length of the video tape fed by the tape feed control means to the tape position detected by the tape position detection means is always constant, so that more accurate positioning control can be realized.

[0013] As another example, the invention according to claim 8 is a video deck according to any one of claims 1 to 7, wherein the tape feed control means is provided by the tape feed means. Is decelerated and stopped by a deceleration time substantially proportional to the running speed of the video tape. In the invention according to claim 8 configured as described above, the tape feed control means performs deceleration stop in substantially proportion to the running speed of the video tape in the tape feed means. In such a case, when the video tape is run at a high speed by the tape feed means, the tape feed control means makes the deceleration time longer to stop the deceleration, so that the stress applied to the video tape at the time of the deceleration stop can be reduced. Become.

[0014]

[Effect of the invention]

 As described above, according to the present invention, when stopping a video tape running at a predetermined speed in a predetermined rotation direction at a rapid traverse, the video tape can be accurately positioned at a desired stop position without applying stress to the video tape. A VCR that can be stopped can be provided. Further, according to the invention of claim 2, it is possible to stop the video tape that is fast-forwarding at a desired stop position. Further, according to the invention of claim 3, it is possible to stop the video tape that is rewinding at a high speed at a desired stop position. Furthermore, according to the invention of claim 4, since the tape position is stored in the predetermined storage area, it is possible to realize the positioning control by a simple method.

Furthermore, according to the invention of claim 5, it is possible to recognize the running position of the video tape by a simple method. Furthermore, according to the invention of claim 6, since positioning control is performed at a speed relatively lower than the tape feeding speed, more accurate positioning can be realized. Furthermore, according to the invention of claim 7, the length of the video tape traveling at the time of deceleration stop is substantially the same regardless of the traveling speed at the time of tape feeding, so that positioning can be simplified. . Furthermore, according to the invention of claim 8, since the tape is stopped by the deceleration time substantially proportional to the running speed in the tape feed, the tape can be stopped without giving any stress to the video tape even when the tape feed is high speed. Becomes possible.

[0016]

[Embodiment of the invention]

 Hereinafter, embodiments of the present invention will be described with reference to the drawings. FIG. 1 is a schematic block diagram showing a televideo to which a video deck according to an embodiment of the present invention is applied. In FIG. 1, a tuner 10 is instructed by a microcomputer 20 for a tuning frequency, receives a television broadcast wave via an antenna 11, and outputs an intermediate frequency signal. The intermediate frequency signal is supplied to a one-chip IC (1 chip IC) 30 that controls the entire television receiving function. Further, the tuner 10 is directly connected to the microcomputer 20, and the video unit 40 and the one-chip IC 30 are connected to the microcomputer 20 via the IIC bus 50. The entire televideo is being controlled. A RAM 60 is connected to the IIC bus 50, and the microcomputer 20 allows the user to operate the operation panel 70 or a remote control, or a remote control system 80 including a light emitting element and a light receiving element. When a predetermined operation such as a stop operation is performed, a predetermined function can be executed based on the operation, while appropriately storing operation contents or predetermined control data in the RAM 21.

The video unit 40 controls the drive of the servo motor while receiving the extraction signal from the sensor in the video mechanism section 41, and controls the video tape feed mechanism 41a to feed the tape such as the high-speed fast-forward and rewind described above. Feed control is being performed. The video unit 40 transmits and receives a head signal by using the video head 41b of the video mechanism unit 41, and executes recording and reproduction of the mounted video tape.

The video unit 40 is provided with a composite video output terminal 42 and an audio output terminal 43, and outputs a playback signal from the video output terminal 42 and the audio output terminal 43 during video playback. I do. Here, the video unit 40 is only required to be able to reproduce the video signal recorded on the video tape together with its synchronizing signal. Even if it is not necessarily a composite video signal, the RGB primary color signal and the synchronizing signal may be used. May be output separately. Further, the on-screen display circuit 90 displays the operation contents of the operation panel 70 or the remote control system 80 by the user under the control of the microcomputer 20. Accordingly, the user can perform a predetermined operation such as a reservation setting of a recording in accordance with the contents displayed by the on-screen display circuit 90. The counter circuit 100 is connected to the IIC bus 50, and inputs a video tape control signal detected by the video unit 30 when high-speed fast-forward or rewind is operated on the operation panel 70 or the remote control system 80. Then, in order to detect the tape feed position, the counter is incremented every time a control signal is input. Therefore, the running amount of the tape can be determined from this counter value. On the other hand, when a high-speed fast-forward or rewind stop operation is performed from the operation panel 70 or the like, the counter value at that time is stored in the RAM 60 under the control of the microcomputer 20.

In this configuration, when the user of the video deck instructs high-speed fast-forward or rewind of the mounted video tape by using the operation panel 50 or the remote control system 60, the microcomputer 20 detects these. Then, the microcomputer 20 causes the video unit 30 to perform high-speed fast-forward or rewind of the video tape mounted on the video mechanism unit 31 from the tape position where the video head 31b is currently located. Here, when the user uses the operation panel 50 or the remote control system 60 to perform an operation to stop high-speed fast forward or rewind, the microcomputer 20 outputs a deceleration stop command to the video unit 30 and the video unit 30 The video tape is decelerated and stopped based on a predetermined deceleration pattern. In such a case, based on the counter value of the counter circuit 100 stored in the RAM 21 as the tape position at the time of output of the deceleration command, the microcomputer 20 sends the video tape to the tape position indicated by the counter value after the deceleration stop. When the high-speed fast-forward or rewind operation is stopped, the tape position is controlled.

Therefore, in the present embodiment, a high-speed fast-forward or rewind stop instruction is issued to the microcomputer 20 by a predetermined operation, so that the operation panel 70 or the remote control system 80 constitutes a tape-feed stop instruction means. . In addition, the microcomputer 20 and the video unit 40 constitute a tape feeding means because the video unit 40 is controlled at a predetermined speed at the time of high-speed fast-forward or rewind to perform high-speed fast-forward. In addition, the counter circuit 100 is operated and counted in response to high-speed fast-forward or rewind, and the counter value of the counter circuit 100 is stored in the RAM 21 as a tape position in response to a stop instruction. And the RAM 21 constitute a tape position detecting means. The video unit 40 is controlled based on the counter value stored in the RAM 21 to execute the positioning control, so that the microcomputer 20 and the video unit 40 constitute a tape feed control unit.

Here, the video output terminal 42 and the audio output terminal 43 are connected to the video input terminal 31 and the audio input terminal 32 of the one-chip IC 30. The one-chip IC 30 performs general television broadcast image receiving processing based on the intermediate frequency signal input from the tuner 10, and can output RGB primary color drive signals for video. Of course, based on this, the output of the deflection signal is performed, and the detection and demodulation of the audio signal are also performed at the same time. The one-chip IC 30 can switch between a television and a video as an input source. When the television is used as an input source, the one-chip IC 30 detects and demodulates a video intermediate frequency signal and performs demodulation based on an audio intermediate frequency signal. Although a video signal and an audio signal are generated, the subsequent steps are common to the case where video is used as an input source. For video, the video is adjusted and then converted to RGB primary color drive signals.

FIG. 2 is a diagram showing a concept of a case where the video tape being fast-forwarded is decelerated and stopped, and then the positioning is controlled to a predetermined tape position. In the figure, the upward feed direction on the vertical axis indicates the speed in the direction in which the video tape advances, and the speed V1 indicates the feed speed when high-speed fast forward is performed. The downward direction of the vertical axis indicates the speed in the direction in which the video tape is returned, and the speed V2 indicates the rewind speed when rewinding the video tape that has been decelerated and stopped. By setting the speed V2 to be lower than V1, it is possible to improve the stop accuracy compared to the deceleration stop from the speed V1, so that the effect of the positioning control process can be further enhanced. .

On the other hand, the horizontal axis indicates time. Time t1 indicates the time at which the operation of the high-speed fast-forward operation is performed from the operation panel 70 or the remote control system 80. At this time t1, the microcomputer 20 controls the video unit 40, and the tape feed mechanism 41a of the video mechanism unit 41 executes fast forward of the video tape. Then, it is gradually accelerated at a high speed and is fast-forwarded at the speed V1. Here, when the operation panel 70 or the remote control system 80 operates to stop the high-speed fast-forward at the time t2, the high-speed fast-forward is decelerated toward the time t3. Then, it stops at time t3. The amount of video tape traveled from the start of deceleration at time t2 to the stop at time t3 is defined as S1. Next, the video unit 30 is controlled by the microcomputer 20 from the time t3, and the tape feed mechanism 41a of the video mechanism unit 41 executes rewinding at the speed V2. Assuming that the amount of video tape by rewinding at this speed V2 is S2, when the above-described S1 and S2 match, when rewinding is stopped, high-speed fast-forwarding is stopped at the timing when the stop operation is performed at time t2. As a result, the user of this VCR can stop high-speed fast-forward at the desired tape position.

In the present embodiment, the counter circuit 100 counts the amount of video tape S1 that has traveled from the start of deceleration at time t2 and the amount of video tape S2 that runs by rewinding from the start of high-speed fast-forward at time t1. Adopt a configuration to detect by counter value. That is, the counter value is incremented in proportion to the running amount of the video tape from time t1 to time t3, the counter value is saved at time t2 when the stop operation is performed, and the counter value is saved when rewinding from time t3. The counter value is decremented and the rewinding is stopped at the time of coincidence, that is, at time t4, to execute positioning.

Further, in the present embodiment, as shown in FIG. 2, a configuration has been described in which high-speed fast-forward is decelerated and stopped, and rewinding and positioning are performed after stopping. Of course, in the case where high-speed rewind is decelerated and stopped. However, it is needless to say that the positioning method according to the present invention can be applied.

Further, in the present embodiment, as shown in FIG. 2, a configuration is adopted in which deceleration is stopped from a predetermined high-speed fast-forward speed and rewinding is performed to execute positioning. Alternatively, it is needless to say that the present invention can be applied to a configuration in which the return speed is decelerated and stopped, and as shown in FIG. 3, the deceleration pattern, that is, the deceleration rate (in the figure, (Indicated by the slope at the time of deceleration) may be made variable. In such a case, the amount of video tape S1a running from the start of deceleration from the speed V1a to the stop is the same as the amount of video tape S1b running from the start of deceleration from the speed V1b lower than the speed V1a to the stop. In this manner, the amount of video tape S2 to be rewound from the times t3a and t3b can be made the same for each speed V1a and V1b, thereby simplifying the positioning process. become.

Of course, as shown in FIG. 4, a deceleration pattern, that is, a deceleration rate (indicated by a gradient at the time of deceleration in the figure) may be constant according to each feed speed. In such a case, the amount of video tape S1a traveling from the start of deceleration from the speed V1a to the stop is larger than the amount of video tape S1b traveling from the start of deceleration from the speed V1b lower than the speed V1a to the stop. Therefore, the video tape amount S2 to be rewound from time t3a, t3b is controlled to be S2a, S2b corresponding to each speed V1a, V1b. Therefore, when the speed is relatively high, the time from the start of deceleration to the stop is relatively long, so that the higher the speed, the less the stress at the time of stopping the video tape which becomes larger. Make it possible.

Next, the processing content of the high-speed fast-forward stop control processing executed by the microcomputer 20 or the like is shown in the flowchart of FIG. In the figure, when the user of the VCR performs a fast forward operation on the operation panel 70 or the remote control system 80, the fast forward of the video tape mounted on the recording / reproducing mechanism is executed (step S100). Then, when the user performs the operation of stopping the high-speed fast-forward, the high-speed fast-forward is decelerated at a predetermined deceleration rate, stopped, and ended (step S200). When the high-speed fast-forward is completed, predetermined rewinding is performed, and the tape is positioned at the tape position at the time when the stop operation is performed (step S300). This allows the user to secure the tape position at the desired stop timing.

Hereinafter, detailed processing contents of each processing of steps S100 to S300 will be described. First, the processing content of the high-speed fast-forward processing in step S100 is shown in the flowchart of FIG. In the figure, when a fast forward operation is performed on the operation panel 70 or the remote control system 80, the microcomputer 20 detects this operation instruction (step S105). Then, the counter value included in the counter circuit 100 is initialized, that is, set to 0 (step S110). When the initialization of the counter value is completed, a high-speed fast-forward instruction is notified to the video unit 40, and the video unit 40 receiving this notification controls the tape feed mechanism 41a of the video mechanism unit 41 to perform the high-speed fast-forward. It starts (step S115). When the fast forward is started, the counter circuit 100 increments the counter value (step S120). This increment is performed until the operation of stopping the high-speed fast-forward by the operation panel 70 or the remote control system 80 (step S125). The increment of the counter value is executed in accordance with the high-speed / fast-forward feed speed.

Next, the processing content of the deceleration stop processing in step S200 is shown in the flowchart of FIG. In the figure, when there is a stop operation for high-speed fast-forward, the microcomputer 20 reads the counter value at the time of detecting the stop operation from the counter circuit 100 (step S205) and stores it in the RAM 21 (step S210). Then, the video tape is started to be decelerated based on the deceleration pattern shown in FIGS. 2 to 4 (step S215). During the deceleration, the counter value at the time when the stop operation is detected is incremented at intervals corresponding to the deceleration speed that changes appropriately (step S220). This increment is executed until deceleration stops (step S225).

Next, the processing content of the positioning processing in step S300 is shown in the flowchart of FIG. In the figure, the microcomputer 20 reads, from the counter circuit 100, a counter value C1 that has been incremented from the start of high-speed fast-forward to the stop of deceleration (step S305). Next, the counter value C2 at the start of deceleration stored in the RAM 21 is read (step S310). Then, the video unit 40 is caused to execute the video tape rewinding operation at a predetermined low speed (step S315). At the same time as the rewind operation, the microcomputer 20 decrements the counter value C1 at intervals suitable for the rewind speed (step S320), and determines whether the decremented counter value C1 matches the above-described counter value C2. It is determined whether or not it is (step S325). If they match, it is determined that positioning to the tape position at the time of the stop operation has been completed, and the rewinding operation is stopped (step S335).

As described above, when the high-speed fast-forward is stopped, the tape position at the time of the stop operation is stored in the RAM 21, decelerated and stopped based on a predetermined deceleration pattern, and after stopping, the tape is wound up to the tape position stored in the RAM 21. By executing the positioning processing for returning, it is possible to avoid the stress applied to the video tape at the time of deceleration stop, and it is possible to accurately position the tape at the time when the stop operation was performed.

[Brief description of the drawings]

FIG. 1 is a block diagram of a televideo to which a video deck according to an embodiment of the present invention is applied.

FIG. 2 is a diagram showing a concept of performing high-speed rapid traverse deceleration stop and positioning control.

FIG. 3 is a diagram showing a concept of positioning control.

FIG. 4 is a diagram showing another concept of positioning control.

FIG. 5 is a flowchart showing processing contents of high-speed fast-forward stop control processing.

FIG. 6 is a flowchart showing processing contents of a high-speed fast-forward processing.

FIG. 7 is a flowchart showing processing contents of a deceleration stop processing.

FIG. 8 is a flowchart showing processing contents of a positioning processing.

[Explanation of symbols]

 Reference Signs List 20 microcomputer 30 single chip 31 video input terminal 32 audio input terminal 40 video unit 41 video mechanism 41a tape feed mechanism 41b video head 50 IIC bus 60 RAM 70 operation panel 80 remote control System 90: On-screen display circuit 100: Counter circuit

Claims (8)

[Utility model registration claims] 1. A tape feeding means for causing a video tape to run at a predetermined speed in a predetermined rotational direction at a rapid feed; a tape feeding stop instruction means for outputting a stop instruction when stopping the running video tape; When the stop instruction output by the tape feed stop instruction means is input, the tape position detection means for detecting the tape position of the video tape when the stop instruction is output, and the stop instruction output by the tape feed stop instruction means When input, the tape feed means is controlled to decelerate and stop the video tape running at a predetermined speed from the tape position. After the deceleration and stop, the video tape is sent to the tape position and positioned at the same tape position. And a tape feed control means for performing the following. 2. The video deck according to claim 1, wherein said tape feed means runs a video tape mounted on a recording / reproducing mechanism at high speed and fast forward. 3. The video deck according to claim 1, wherein said tape feeding means runs a video tape mounted on a recording / reproducing mechanism at a high speed rewind. 4. The video deck according to claim 1, wherein said tape position detection means stores the detected tape position in a predetermined storage area, and said tape feed control means A video deck which reads a tape position stored in the storage area and executes a predetermined control. 5. The video deck according to claim 1, wherein said tape feeding means counts a control signal and indicates a position of the running tape when running the video tape. A video deck, wherein the tape position detecting means acquires the count value and detects a tape position when a stop instruction is output. 6. The video deck according to any one of claims 1 to 5, wherein the tape feed control means operates at a predetermined speed relatively lower than a predetermined speed of the tape feed means. A video deck performing the above positioning. 7. The video deck according to any one of claims 1 to 6, wherein the tape feed control means controls the tape at the time of deceleration stop regardless of a running speed of the video tape by the tape feed means. A video deck characterized in that it is decelerated and stopped so that the traveling amount is substantially the same. 8. The video deck according to any one of claims 1 to 6, wherein said tape feed control means decelerates and stops by a deceleration time substantially proportional to a running speed of the video tape at said tape feed means. A VCR, characterized by