JPH0969261A - Digital magnetic recording / reproducing device - Google Patents

Abstract

(57) [Abstract] [Purpose] It consists of at least three memory stages arranged in parallel and discards the data even if the detection of the input completion for the frame is delayed, or overwrites the data of the frame where the input is completed. Achieve effective use without destroying the complete data. [Structure] At least three m-frame memories (m is an integer of 1 or more) arranged in parallel, means for distributing data writing to each memory, and data writing and reading for each memory are not the same memory. And means to control it.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an apparatus for recording / reproducing digitized video and audio signals, and more particularly to a digital magnetic recording / reproducing apparatus for effectively utilizing reproduced data.

[0002]

2. Description of the Related Art In recent years, digital VTRs as a digital magnetic recording / reproducing device have been commercialized for broadcasting and business use, and have been developed for home use. In such a digital magnetic recording / reproducing apparatus, digital data obtained by digitizing a video signal and an audio signal is recorded on a recording track inclined in the longitudinal direction on a magnetic tape as data of m frames (m is an integer of 1 or more). Is generally divided into n tracks (n is an integer of 1 or more), a unique track number is provided for each track, and a helical scan system in which a rotary head records and reproduces a signal is generally used.

Hereinafter, a conventional digital magnetic recording / reproducing apparatus with m = 1, n = 5 and track numbers 0 to 4 will be described with reference to the drawings. FIG.
FIG. 1 is a diagram showing a configuration of a conventional digital magnetic recording / reproducing apparatus. In FIG. 2, 1 is a reproduction signal from a magnetic tape, 2 is a track number detection circuit, 3 is a track number output, 4 is an in-track data write end detection circuit, 5 is an in-track data write end track number output, and 6 is a frame. An internal data write end detection circuit, 7 is a frame memory X, 8 is a frame memory Y, 9 is a transfer switch from the frame memory X7 to the frame memory Y8, and 10 is a reproduction output.

During the reproducing operation, the reproduced data from the magnetic tape is taken in, the track number detecting circuit 2 detects the track number, and the track number output 3 is outputted.
Based on the detected track number, the in-track data write end detection circuit 4 attempts to detect the in-track data write end. When the in-track data write end detection circuit 4 detects the end of in-track data write, it outputs the ended track number. The in-frame data write end detection circuit 6 attempts to detect the in-frame data write end according to the running direction of the magnetic tape.

The reproduction signal 1 is written in the frame memory X7 at any time. The output signal is output from the frame memory Y at any time. When the magnetic tape is running in the normal direction,
When the in-track data write end detection circuit 4 finishes reproducing the track number “4” and at the same time the in-frame data write end detection circuit 6 detects the end of frame write, it means that the frame memory X7 has finished writing, and The data write end detection circuit 6 closes the transfer switch 9 from the frame memory X7 to the frame memory Y8, and transfers the data in the frame memory X7 that has been written to the frame memory Y8 at high speed. After that, this operation is repeated to reproduce.

As a technique similar to the above-mentioned conventional example, there is one disclosed in Japanese Patent Laid-Open No. 3-132183.

[0007]

However, the conventional configuration described above has the following problems. In the conventional technique, the memory has a two-stage configuration, and it is necessary to transfer data to the second-stage memory (frame memory Y8) after the first-stage memory (frame memory X7) is full. Also, after reading the memory in the second stage, high-speed transfer from the memory in the first stage to the memory in the second stage is required.
The reading of the second-stage memory starts again. Further, when processing in frame units is required, for example, when performing frame still, etc., the data in the first stage must be transferred to the memory in the second stage after the data for frames has been captured. For example, if the memory of the first stage has only the frames, when the input completion detection for the frames is delayed, there is a memory for writing the data of the next frame although the data of the next frame is input from the magnetic tape. Without doing so, the data is discarded, or the data of the frame that has been input is overwritten and destroyed.

In view of the above problems of the prior art, the present invention is configured by at least three memory stages arranged in parallel and discards data even if the input completion detection for a frame is delayed,
Another object of the present invention is to provide a digital magnetic recording / reproducing apparatus which can be effectively used without overwriting the data of a frame that has been input and without destroying all the data.

[0009]

According to the present invention, at least three m-frame memories arranged in parallel, and means for allocating data writing to at least three memories,
A digital magnetic recording / reproducing apparatus having means for controlling at least three memories so that writing and reading of data do not become the same memory.

[0010]

According to the present invention, with the above-described configuration, at least three memory stages arranged in parallel are used to discard the data even if the detection of the input completion of the frame is delayed, or to convert the data of the frame for which the input is completed. It can be used effectively without overwriting and destroying the complete data.

[0011]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the present invention will be described below with reference to the accompanying drawings. Incidentally, in the configuration diagram of the embodiment, the description of the blocks having the same reference numerals as those in the conventional example will be omitted. FIG. 1 is a diagram showing the configuration of a digital magnetic recording / reproducing apparatus according to an embodiment of the present invention. In FIG. 1, 21 is a frame memory A, 22 is a frame memory B, 23 is a frame memory C, 24 is a frame memory selection circuit, 25 is a write memory selection switch, and 26 is a read memory selection switch.

For convenience of explanation, the digital magnetic recording / reproducing apparatus in this embodiment will be described assuming that one frame is divided into 5 tracks and the track numbers are 0 to 4. That is, similarly to the conventional example, m = 1 and n = 5. During the reproducing operation, the reproduced data from the magnetic tape is taken in, the track number is detected by the track number detecting circuit 2, and the track number output 3 is outputted. Based on the detected track number, the in-track data write end detection circuit 4 attempts to detect the in-track data write end. When the in-track data write end detection circuit 4 detects the end of in-track data write, it outputs the ended track number. The in-frame data write end detection circuit 6 attempts to detect the in-frame data write end according to the running direction of the tape.

Further, the frame memory selection circuit 24 first sets the write memory selection switch 25 so that it can be written in the frame memory A21, and sets the read memory selection switch 26 so that it can be read out from the frame memory C23. If the data of the track number “4” is input after the in-track data write completion detection circuit 4 detects that the reproduction of the track number “3” is completed, the frame memory selection circuit 24 keeps the write memory as before. The selection switch 25 is set so as to be able to write in the frame memory A21, and the data is written in the frame memory A21 where writing is continued.

However, if the data of the track number "3" is input, if the frame memory selection circuit 24 is set so that the write memory selection switch 25 can be written in the frame memory A21 as it is, the writing is already completed. Overwrites where you are doing. At that time, the frame memory selection circuit 24 switches the write memory selection switch 25 from the frame memory A21 to the frame memory B22, so that the data is not stored in the frame memory A21 which is continuously writing and is not in the frame memory C23 which is reading. Write, avoid duplication.

If the data of the track number "0" is input, the frame memory selection circuit 24 similarly
If the write memory selection switch 25 is set to be able to write in the frame memory A21 as it is, it will be overwritten in the place where the writing has already been completed. At that time, the frame memory selection circuit 24 switches the write memory selection switch 25 from the frame memory A21 to the frame memory B22, so that the data is not stored in the frame memory A21 which is continuously writing and is not in the frame memory C23 which is reading. Write, avoid duplication.

Next, when the in-track data write end detection circuit 4 finishes reproducing the track number "4" and at the same time the in-frame data write end detection circuit 6 detects the end of frame write, the frame memory A21 has finished writing. Therefore, the frame memory selection circuit 24
The write memory selection switch 25 is set to the frame memory A2.
Switch from 1 to the frame memory B22. At the same time, the frame memory A21 becomes ready for output when the writing is completed, and the frame memory selection circuit 24 switches the read memory selection switch 26 from the frame memory C23 to the frame memory A21 and outputs data of a new frame.

When the reproduction is further advanced, and the data in the track write end detection circuit 4 detects that the reproduction of the track number "3" is completed again, and the data of the track number "4" is input, the frame memory selection is made. The circuit 24 is
The write memory selection switch 25 is set as it is to be able to write in the frame memory B22, and the data is written in the frame memory B22 where writing is continued.

However, if the data of the track number "3" is input, if the frame memory selection circuit 24 is set so that the write memory selection switch 25 can be written to the frame memory B22 as it is, the writing is already completed. Overwrites where you are doing. At that time, the frame memory selection circuit 24 switches the write memory selection switch 25 from the frame memory B22 to the frame memory C23, and writes data to the frame memory C23 that is not the frame memory B22 that is continuously writing and is not the frame memory A21 that is reading. Write, avoid duplication.

When the data of the track number "0" is input, the frame memory selection circuit 24 similarly
If the write memory selection switch 25 is set so as to be able to write to the frame memory B22 as it is, it will be overwritten at a place where writing has already been completed. At that time, the frame memory selection circuit 24 switches the write memory selection switch 25 from the frame memory B22 to the frame memory C23, and writes data to the frame memory B22 that is not the frame memory B22 that is continuously writing and is not the frame memory A21 that is reading. Write, avoid duplication.

Next, when the in-track data write end detection circuit 4 finishes reproducing the track number "4" and at the same time the in-frame data write end detection circuit 6 detects the end of frame write, the frame memory B22 has finished writing. Therefore, the frame memory selection circuit 24
Set the write memory selection switch 25 to the frame memory B2.
Switch from 2 to the frame memory C23. At the same time, the frame memory B22 becomes ready for output when the writing is completed, and the frame memory selection circuit 24 switches the read memory selection switch 26 from the frame memory A21 to the frame memory B22 to output the data of a new frame.

By repeating the above operation, the frame memory A2
1, the frame memory B22 and the frame memory C23 are circulated, and two memories are always allocated for input and one memory for output, and they are not overlapped. Further, the memory selection means for writing divides the five track numbers into 0, 1, 2 and 3, 4 in the forward direction of the magnetic tape, and when the track number output 3 becomes "3" or more, 0, In 1 and 2, data is written in a frame memory that is not a frame memory that is continuously writing and is not a reading frame memory, and 3 and 4 is written in a frame memory that is continuously writing, and five track numbers are set to 0 in the reverse direction. 1 and 2,
If it is divided into 3 and 4, and the track number output 3 becomes "1" or less, in 2 and 3 and 4, the data is written in the frame memory which is not the frame memory which is continuously writing and the frame memory which is not being read, 0 and 1 may be written in the frame memory in which writing is continued.

Further, the read memory selection means may be switched after waiting for the timing on the output side after the in-frame data write end detection circuit 6 detects the end of frame write. As described above, according to the digital magnetic recording / reproducing apparatus of this embodiment, the frame memories are switched by the frame memory selection circuit 24 by using the track numbers of the input / output of the in-tracking data write detection circuit 4, and thus the same. Data can be written to memory without duplication of data. Further, since at least three frame memories are provided, high-speed transfer between memories is not required for output.

In this embodiment, one frame (m
Although the case where (1) is divided into 5 tracks (n = 5) has been described, it can be easily inferred that other numbers may be used as long as m and n are integers of 1 or more. In addition, although the case where the number of frame memories is three is described in the present embodiment, the number of frame memories is three.
It may be more than one, or one memory capable of simultaneous input and output may be separated into three or more in the address space.

[0024]

As described above, according to the present invention, means for allocating data writing to at least three m-frame memories (m is an integer of 1 or more) arranged in parallel and data writing to at least three memories. By providing a means for controlling the writing and reading of data in at least three memories so that the same memory is not used, the input data is not discarded or overwritten with the input completed data and is reproduced. Data can be effectively used, and the memory does not have to have a two-stage structure,
There is no need for high-speed transfer from the first stage to the second stage, a low-speed general-purpose DRAM can be configured, and power consumption can be reduced because transfer is not performed. In addition, at least three m-frame memories arranged in parallel are used as one large-capacity DRAM.
If it is realized, it becomes advantageous in terms of mounting area and cost, and its practical effect is great.

[Brief description of drawings]

FIG. 1 is a block diagram of a digital magnetic recording / reproducing apparatus according to an embodiment of the present invention.

FIG. 2 is a block diagram of a conventional digital magnetic recording / reproducing apparatus.

[Explanation of symbols]

 1 reproduction signal from magnetic tape 2 track number detection circuit 3 track number output 4 in-track data writing end detection circuit 5 in-track data writing end track number output 6 in-frame data writing end detection circuit 10 reproduction output 21 frame memory A 22 frames Memory B 23 Frame memory C 24 Frame memory selection circuit 25 Write memory selection switch 26 Read memory selection switch

 ─────────────────────────────────────────────────── ─── Continuation of front page (72) Inventor Masashi Sato 1006 Kadoma, Kadoma City, Osaka Prefecture Matsushita Electric Industrial Co., Ltd.

Claims (6)

[Claims] 1. Digital data obtained by digitizing a video signal and an audio signal are recorded on a recording track inclined in the longitudinal direction on a magnetic tape, and m frames (m is an integer of 1 or more) of n tracks (n is 1). In a helical scan type digital magnetic recording / reproducing apparatus in which a track is uniquely assigned to each track and a signal is recorded / reproduced by a rotary head, at least three m-frame memories are arranged in parallel. A means for detecting the track number in the reproduction data, a means for detecting the completion of inputting the data in the track on the magnetic tape by using the means for detecting the track number, and a means for detecting the completion of inputting the data in the track By using the means for holding the number of the input completed track detected in 1. and the means for detecting the input completion of the data in the track Digital magnetic recording / reproducing, characterized by having means for detecting completion of input of data in m frames on the magnetic tape, and means for allocating writing of data to the at least three memories by using results of the respective means. apparatus. 2. A pointer for selecting which one of at least three m-frame memories is to be used,
Regarding the means for allocating the writing of data to the at least three memories, the pointer is set to m on the magnetic tape.
Proceeding with the detection of the input completion of the data in the frame, using the pointer to select two memories from the memories of at least three m frames, and using the means for holding the detected input completion track number, the forward direction is used. For, regarding the data on the magnetic tape, the data of the track number from 0 to the completion of input is written to the other memory which has not been written so far, otherwise it is written to the memory which has been written so far, and in the opposite direction. Writes the data of the track number from the input completion to n on the magnetic tape to another memory that has not been written until now,
2. The digital magnetic recording / reproducing apparatus according to claim 1, wherein the memory is written in the memory which has been written until then. 3. A pointer for selecting which one of at least three m-frame memories is to be used,
Regarding the means for allocating the writing of data to the at least three memories, the pointer is set to m on the magnetic tape.
When the input completion of the data in the frame is detected, two pointers are selected from the memories of at least three m frames by using the pointer, and the track number is n-a (where a is In the area of a <n / 2), the data of the tracks whose track numbers are n-a or more is written in the memory that has been written so far, and the data of the tracks whose track numbers are n-a or less is selected another. When writing to the memory and playing backward,
In the area where the track number is nb (where b is an integer of b> n / 2), the data of the tracks whose track number is nb or less is written in the memory that has been written so far, and the track number is nb. 2. The digital magnetic recording / reproducing apparatus according to claim 1, wherein the data of the above tracks is written in another selected memory. 4. Digital data obtained by digitizing a video signal and an audio signal are recorded on a recording track inclined in the longitudinal direction on a magnetic tape, and m frames (m is an integer of 1 or more) of n tracks (n is 1). In a helical scan type digital magnetic recording / reproducing apparatus in which a track is uniquely assigned to each track and a signal is recorded / reproduced by a rotary head, at least three m-frame memories are arranged in parallel. A means for detecting the track number in the reproduction data, a means for detecting the completion of inputting the data in the track on the magnetic tape by using the means for detecting the track number, and a means for detecting the completion of inputting the data in the track By using the means for holding the number of the input completed track detected in 1. and the means for detecting the input completion of the data in the track Means for detecting completion of input of data in m frames on the magnetic tape and means for controlling writing and reading of data in the at least three memories by using results of the respective means so as not to be the same memory. A digital magnetic recording / reproducing apparatus characterized by having. 5. A pointer for selecting which one of at least three m-frame memories is to be used,
Regarding a means for controlling writing and reading of data in the same memory, the pointer is advanced by detection of completion of input of data in m frames on the magnetic tape, and the pointer is used to store at least three m frames of memory. Two memories are used for writing and the remaining one is for reading. When the input completion of the data in m frames is detected, the memory that has finished writing is switched to the reading memory and the memory that has been read until then is replaced. 5. The digital magnetic recording / reproducing apparatus according to claim 4, wherein switching is performed for writing, and then at least three memories are sequentially switched based on the pointer. 6. A pointer for selecting which one of at least three m-frame memories is to be used,
Regarding the means for controlling the writing and reading of the data not to be in the same memory, the pointer is advanced by the detection completion of the input of the data in m frames on the magnetic tape,
Using the pointer, two memories are written out of at least three m-frame memories, and the remaining one is used for reading, the input completion of the data in the m-frame is detected, and the reading memory is read. If so, the memory that has finished writing is switched to the memory for reading, the memory that has been read until then is switched to the memory for writing, and thereafter at least three memories are sequentially switched based on the pointer. The digital magnetic recording / reproducing apparatus according to claim 4.