JPH0321988B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a rotating head type magnetic recording and reproducing device that converts information signals into digital signals and records and reproduces them on a magnetic tape by scanning diagonally or perpendicularly with a rotating head, and a recording and reproducing method thereof. In particular, it concerns improvements in data interleaving.

A rotating head type PCM magnetic recording/reproducing device converts an audio signal into a digital signal and records and/or reproduces it on a magnetic tape using a rotating head, and an error correction code is generally used in this type of device. The purpose of the error correction code is to correct errors in data that occur during recording and reproduction of magnetic tape, and to reproduce high-quality audio signals. However,
If the number of errors exceeds the correction capability and cannot be corrected, correction processing such as interpolation by taking the average value of previous and subsequent data is performed. Furthermore, errors on magnetic tape are often burst errors, and in order to improve the performance of error correction codes, interleaving processing is performed to disperse error data. As mentioned above, when an error cannot be corrected, a correction process is performed, and an effective method using a simple circuit is average value interpolation. In order to perform average value interpolation, the data before and after must be correct data. Therefore, when interleaving is performed, the data of the odd sample group and the data of the even sample group are separated as much as possible.

Figures 1 and 2 show the conventional rotating head type.
FIG. 3 is a diagram showing a magnetization pattern recorded on a magnetic tape by a PCM magnetic recording/reproducing device.

In the following explanation, a two-head helical scan rotating head type PCM recording and reproducing apparatus will be considered as an example.

In FIGS. 1 and 2, the data consists of two channels, channels A and B, and is divided into an even sample group a and an odd sample group b.
That is, a in A+B indicates an even number of samples of only the A channel and the B channel. Further, S indicates the head scanning direction, and D indicates the tape running direction.
The amount of interleaving is often determined by considering the error burst length and the correction ability of the error correction code. As shown in Figure 1, even sample group a and odd sample group b are There are things that are lined up with , or things that are the opposite.

In FIG. 2, one scanning section is equally divided and an even sample group a and an odd sample group b are arranged.

When such interleaving is performed, when one head becomes momentarily clogged with magnetic powder that has fallen off, in other words, when the reproduction signal from one head is lost, continuous Since errors occur in the data, it is impossible to interpolate the average value, and audible noise is generated.

The present invention has been made in view of the above-mentioned conventional problems, and it divides a digital information signal consisting of a plurality of channels into each channel, and further divides the samples in each channel into an odd sample group and an even sample group, and By arranging odd and even sample groups of channels for each scan and recording and reproducing them at positions separated in the scanning direction of the head, it is possible to prevent head clogging and to avoid tape running with a certain width in the tape width direction. It is an object of the present invention to provide a rotating head type magnetic recording/reproducing device and a recording/reproducing method therefor which generates less noise even when a direction error occurs.

FIG. 3 is a diagram of a magnetization pattern on a tape recorded by a rotating head type PCM magnetic recording/reproducing apparatus according to an embodiment of the present invention. As shown in the figure, the feature of interleaving by the rotating head type magnetic recording/reproducing apparatus of the present invention is that the even-numbered sample data group and the odd-numbered sample data group of the same channel are scanned at different positions with respect to the scanning direction of the head. It is to allocate it to. By arranging them in this way, even if the signal from one of the two heads is lost due to head clogging as described above, at least either the even sample group or the odd sample group within the same channel will be lost. Since a signal is always obtained for one or the other, consecutive sampling errors do not occur. Furthermore, even for burst errors in the tape running direction with a certain width from the edge of the tape, signals from either the even sample group or the odd sample group within the same channel can be obtained up to half the tape width. Therefore, consecutive sample errors do not occur within the same channel.

FIG. 4 is a diagram showing another example of the magnetic pattern. In this example as well, the even-numbered sample group and the odd-numbered sample group of the same channel are arranged for each scan and at positions separated from each other in the scanning direction, making it possible to cope with signal loss similar to the example of FIG. 3.

Next, a rotating head type PCM magnetic recording and reproducing apparatus for recording and reproducing magnetic patterns as described above will be explained. FIG. 5 is a schematic block diagram of one embodiment of the present invention. The structure and operation of an embodiment of the present invention will be described with reference to FIG.

The recording system includes a two-channel input terminal 1, a low-pass filter (LPF) 2 for band limitation, an analog-digital (A/D) conversion circuit 3 for converting analog signals into digital signals, and a digital signal converter 3. A memory circuit 4 for temporary storage, an encoding circuit 5 for adding a code for error correction or error detection to a digital signal, a modulation circuit 6 for modulating the encoded digital signal, and a recording amplifier 7.
, a first switch 8 for selecting a head, and heads 9 and 10.

Two channels of analog signals, L and R, are input to input terminal 1, and each is passed through low-pass filter 2.
Bandwidth is limited by The output of the low-pass filter 2 is given to an A/D conversion circuit 3 and converted into digital signals W _Lo and W _Ro . Here, n indicates the sampling order, and the analog signals of the two channels L and R are sampled sequentially, and W _L0 , W _R0 ,
The digital signals of both channels are output alternately as W _L1 , W _R1 , W _L2 , W _R2 , . . . . These digital signals W _Lo and W _Ro are applied to the memory circuit 4 and sequentially written into the memory by a memory address control circuit (not shown) included in the memory circuit 4. This memory address control will be described in detail later. An encoding circuit 5 provided in association with the memory circuit reads the necessary samples in the memory, generates a correction code, and writes this to the memory. The digital signal and correction code are then sequentially read out by the aforementioned memory address control circuit. The read digital signal is input to a modulation circuit 7, converted into data suitable for recording on a magnetic tape, amplified by a recording amplifier 7, and then sent to a second switch via a first changeover switch 8.
The information is recorded on the magnetic tape by two heads 9 and 10. The first changeover switch 8 is used to switch the circuit connected to the head during recording and playback.

Next, the configuration of the reproduction system and its operation will be explained. The reproduction system includes heads 9 and 10, a second switch 11, a reproduction amplifier 12, a demodulation circuit 13 for demodulating the reproduced digital signal, and a memory circuit 1 for temporarily storing the demodulated digital signal.
4, and a decoding circuit 15 that performs error correction and error detection.
and a digital-to-analog conversion circuit 16 that converts the decoded digital signal into an analog signal.
It is composed of a low-pass filter 17 and a two-channel output terminal 18. two heads 9 and 1
The signal read from 0 is applied to the second changeover switch 11 via the first changeover switch 8.

This second changeover switch 11 is for applying the output signals of the heads 9 and 10 to the reproduction amplifier 12 as one signal system. The reproduced digital signal is amplified by a reproduction amplifier 12 and then sent to a demodulation circuit 13.
The digital signal is then returned to the digital signal before being modulated, and is then provided to the memory circuit 14. The memory circuit 14 writes this digital signal. A decoding circuit 15 provided in association with the memory circuit 14 reads necessary samples from the memory and performs error correction and detection. The corrected samples in the memory are sequentially read out from the memory by the aforementioned memory address control circuit, applied to the D/A conversion circuit 16, converted to an analog signal, band-limited by the low-pass filter 17, and sent to the output terminal. It is output from 18.

Note that the clock generation circuit 19 provides necessary clock pulses to each section of the recording system and reproduction system.

Next, in connection with the memory circuits 4 and 14 shown in FIG. 5, a means for performing data interleaving as described above used in the rotating head type PCM magnetic recording/reproducing apparatus of the present invention will be specifically explained in one embodiment. . FIG. 6 shows memory address states that allow such data interleaving. In the figure, the number of samples recorded in two scans is 32 samples each for both the L and R channels. Further, the numbers in the horizontal direction indicate memory addresses in column units (hereinafter referred to as frame addresses), and the numbers in the vertical direction indicate memory addresses in units of rows (hereinafter referred to as sample addresses). In the recording system, as mentioned above,
The samples that are A/D converted and sent sequentially as W _L0 , W _R0 , W _L1 , W _R1 , etc. are stored in the memory while controlling the addresses by the memory address control circuit so that they become the array shown in the figure. write to. In other words, the sample address is set to 0, and the frame addresses are set to 0, 8, 12, 4, etc., and the writing is performed sequentially, and the frame address becomes 7, and W _R7
After writing the sample, the sample address is updated by 1, and writing is performed sequentially while controlling the frame address again. In this way, 4
The samples are arranged in a matrix of ×16,
At this time, the even sample group and the odd sample group of each channel have already been separated.

This matrix of samples is encoded by the encoding circuit shown in FIG. 5, but the encoding is not the subject matter of the present invention and will therefore be omitted. Here, the error correction words are C _Lo ,
C _Ro is used. Reading from memory is vertical 4
One frame consists of a sample and one word of error correction word, and is sequentially transmitted in frame units. That is,
The frame address is set to 0, the sample addresses are sequentially updated as 0, 1, 2, . . . , and when the error correction word is transmitted at 4, the frame address is updated by 1 and sent out in the same manner. Data up to frame address 7 is included in one scan, and the entire memory data is completed in two scans. The data transmitted in this way becomes the pattern shown in Figure 3 on the tape, and as mentioned above,
Even if a scan signal is missing or a burst error occurs in the tape running direction of half the width of the tape from the tape edge, continuous sample errors do not occur, and it is possible to correct the average value interpolation. A magnetization pattern such as that shown in FIG. 4 can be obtained by appropriately changing the address control for writing samples into the memory described above.

In addition, although the above description shows an example of two channels, the same applies to multiple channels. Figure 7 shows the state of the magnetic tape pattern in the case of four channels A, B, C, and D. In this case as well, as in the case of two channels, there is a loss of signal in one scan, and the tape width from the tape edge. Even if a burst error occurs in the tape running direction half of the time, continuous sample errors do not occur in each channel and average value interpolation is possible.

Furthermore, although the above example describes a device that targets audio signals, it can also be used for devices that target signals for which correction by mean value interpolation is effective, such as image signals. It goes without saying that the method can also be applied to methods other than the PCM method.

〔Effect of the invention〕

As described above, according to the rotating head type magnetic recording/reproducing device and its recording/reproducing method according to the present invention,
Divide the samples of multiple channels into an even sample group and an odd sample group for each channel, and
The configuration is such that the data of the even sample group and the odd sample group of the same channel are distributed for each scan, and are recorded at positions apart from each other in the scanning direction. Even burst errors in the tape running direction, which have a large width, can be easily corrected by mean value interpolation, which has the effect of improving the S/N of reproduced sound or images.

[Brief explanation of the drawing]

1 and 2 are state diagrams of magnetization patterns of conventional examples, FIGS. 3 and 4 are state diagrams of magnetization patterns according to an embodiment of the present invention, and FIG. 5 is a schematic block diagram of an embodiment of the present invention. 6 is a memory state diagram according to one embodiment of the present invention, and FIG. 7 is a magnetization pattern state diagram according to another embodiment of the present invention. In the figure, 1 is an input terminal, 2 is a low-pass filter, 3 is an A/D conversion circuit, 4 is a memory circuit, and 5
is an encoding circuit, 6 is a modulation circuit, 7 is a storage amplifier,
8 is a first changeover switch, 9 and 10 are heads, 11 is a second changeover switch, 12 is a reproduction amplifier, 13 is a demodulation circuit, 14 is a memory circuit, 15 is a decoding circuit, 16 is a D/A conversion circuit, 17 is a low-pass filter, 18 is an output terminal, and 19 is a clock generation circuit. Note that the same reference numerals in the figures indicate the same or equivalent parts.

Claims (1)

[Scope of Claims] 1. In a rotary head type magnetic recording/reproducing device that records and reproduces digital signals of two channels, first and second, while forming diagonal tracks on a recording medium, The samples for two channels are separated into even-numbered samples and odd-numbered samples for each channel.
All the samples for the two channels are the first and second channels.
The even-numbered samples and the odd-numbered samples of the same channel are respectively recorded on different tracks of the two tracks and at positions separated in the longitudinal direction of the tracks. a signal processing means for supplying said digital signal to said signal processing means; a recording means for sequentially recording said signals supplied from said signal processing means on said recording medium so as to form said track; and a track recorded on said recording medium. a reproduction means for scanning and reproducing two channels of digital signals; and a reproduction signal processing means for rearranging the sample order of the digital signals reproduced by the reproduction means into the original sample order for each channel in units of two tracks. , each track has at least a first region located in the front half in the longitudinal direction of the track from near the center of the track, and a second region located in the rear half, and either the even numbered or odd numbered samples of the first channel. recording and reproducing one of the samples in a first area of the first track, and recording either the even-numbered or odd-numbered samples of the second channel in a second area of the first track; the other one of the even-numbered or odd-numbered samples of the second channel is collectively recorded and played back in the first area of the second track, and the other one of the even-numbered or odd-numbered samples of the first channel is 1. A rotating head type magnetic recording/reproducing apparatus characterized in that one of the two is recorded and reproduced in a second area of a second track. 2. Even samples of the first channel are placed in the first area of the first track, and odd samples of the second channel are placed in the first area of the first track.
a second region of the track, an even number of samples of the second channel is added to the second region of the track;
the odd samples of the first channel in the first region of the track;
2. A rotating head type magnetic recording/reproducing apparatus according to claim 1, wherein recording is performed in a second area of a track. 3. Even samples of the first channel are placed in the first area of the first track, and even samples of the second channel are placed in the first area of the first track.
Odd samples of the second channel are added to the second region of the track.
the odd samples of the first channel in the first region of the track;
2. A rotating head type magnetic recording/reproducing apparatus according to claim 1, wherein recording is performed in a second area of a track. 4. The signal processing means includes an encoding means for generating a redundant signal for error control from a digital signal included in one track, and includes the redundant signal in the same track as the digital signal that generated the redundant signal. A rotating head type magnetic recording/reproducing apparatus according to claim 2 or 3, characterized in that recording is performed as follows. 5 even samples of the first channel from the first region of the first track; odd samples of the second channel from the first region;
From a second region of the track, even samples of the second channel are added to the second channel.
From the first region of the track, the odd samples of the first channel are transferred to the second channel.
2. A rotary head type magnetic recording and reproducing apparatus as claimed in claim 1, characterized in that reproduction is performed from the second area of the track. 6 even samples of the first channel from the first region of the first track; and even samples of the second channel from the first region.
From a second region of the track, odd samples of the second channel are added to the second channel.
From the first region of the track, the odd samples of the first channel are transferred to the second channel.
2. A rotary head type magnetic recording and reproducing apparatus as claimed in claim 1, characterized in that reproduction is performed from the second area of the track. 7. The reproduced signal processing means includes a decoding means for detecting and correcting errors in the digital signal using the reproduced redundant signal for error control, and decoding is performed in units of signals for one track. A rotating head type magnetic recording/reproducing apparatus according to claim 5 or 6. 8 A rotating head type magnetic recording device that records digital signals of two channels, first and second, while forming diagonal tracks on a recording medium, and records samples of two channels input within a unit time. Separating each channel into even-numbered input samples and odd-numbered input samples, and all the samples for the two channels are arranged in the first and second two tracks,
signal processing means for supplying the digital signal so that even-numbered samples and odd-numbered samples of the same channel are respectively recorded on different tracks of the two tracks and at positions separated in the longitudinal direction of the tracks; and recording means for sequentially recording the signals supplied from the signal processing means on the recording medium so as to form the tracks, each track being located in the front half in the longitudinal direction of the track from near the center of the track. at least a first area located in the second half of the track, and a second area located in the latter half of the track, and either the even-numbered or odd-numbered samples of the first channel are collectively recorded in the first area of the first track; Either the even-numbered or odd-numbered samples of the second channel are recorded in a second area of the first track, and the other one of the even-numbered or odd-numbered samples of the second channel is recorded in the second area of the first track. The sample is recorded in a concentrated manner in a first area of a track, and the other one of the even-numbered or odd-numbered samples of the first channel is recorded in a consolidated manner in a second area of a second track. Rotating head magnetic recording device. 9. Even samples of the first channel are placed in the first area of the first track, and odd samples of the second channel are placed in the first area of the first track.
a second region of the track, an even number of samples of the second channel is added to the second region of the track;
the odd samples of the first channel in the first region of the track;
9. A rotating head type magnetic recording device according to claim 8, wherein recording is performed in a second area of a track. 10 Even samples of the first channel are placed in the first area of the first track, and even samples of the second channel are placed in the first area of the first track.
Odd samples of the second channel are added to the second region of the track.
the odd samples of the first channel in the first region of the track;
9. A rotating head type magnetic recording device according to claim 8, wherein recording is performed in a second area of a track. 11. The signal processing means includes an encoding means for generating a redundant signal for error control from a digital signal included in one track, and the redundant signal is placed in the same track as the digital signal that generated the redundant signal. 11. A rotary head type magnetic recording apparatus according to claim 9 or 10, characterized in that recording is performed so as to include a magnetic field. 12. In a rotating head type magnetic reproducing device that reproduces digital signals of two channels, first and second, while sequentially scanning diagonal tracks formed on a recording medium, each of the tracks is arranged in the first half in the longitudinal direction from near the center. It has at least a first area in the first part and a second area in the latter part, and two channels of samples for a unit time are recorded distributed in each area of the first and second two tracks. A reproducing device, comprising a reproducing means for reproducing a signal while scanning the track, and a digital signal reproduced by the reproducing means as an input, and each digital signal for two tracks, a first and a second track, as a unit. a reproduced signal processing means for rearranging and outputting samples for each channel, reproducing either the even-numbered or odd-numbered samples of the first channel from the first area of the first track; one of the even-numbered or odd-numbered samples of the second channel is reproduced from the second area of the first track, and the other of the even-numbered or odd-numbered samples of the second channel is reproduced from the first area of the second track. A rotary head type magnetic reproducing device characterized in that the other one of the even-numbered or odd-numbered samples of the first channel is reproduced from a second area of a second track, and the sample order is rearranged and output. . 13 even samples of the first channel from the first region of the first track; odd samples of the second channel from the first region;
From a second region of the track, even samples of the second channel are added to the second channel.
From the first region of the track, the odd samples of the first channel are transferred to the second channel.
13. A rotary head type reproducing apparatus as claimed in claim 12, characterized in that the reproducing apparatus reproduces from the second region of the track. 14 even samples of the first channel from the first region of the first track; and even samples of the second channel from the first region of the first track.
From a second region of the track, odd samples of the second channel are added to the second channel.
From the first region of the track, the odd samples of the first channel are transferred to the second channel.
14. A rotary head type reproducing apparatus as claimed in claim 13, characterized in that the reproduction is performed from the second region of the track. 15. The reproduced signal processing means includes a decoding means for detecting and correcting errors in the digital signal using the reproduced redundant signal for error control, and decoding is performed in units of signals for one track. A rotating head type magnetic reproducing device according to claim 13 or 14. 16 A rotating head type magnetic recording system in which digital signals of two channels, first and second, are recorded while forming diagonal tracks on a recording medium, and each track is formed from near the center of the track in the longitudinal direction. It has at least a first region located in the first half and a second region located in the second half, and samples for two channels input within a unit time are divided into even-numbered samples and odd-numbered samples for each channel. The input samples are separated into two channels, and all the samples for the two channels are
arranged in the region of a second two-track, one of the even-numbered or odd-numbered samples of the first channel is placed in the first region of the first track, and the even-numbered or odd-numbered samples of the second channel one of the even-numbered or odd-numbered samples of the second channel is placed in the first region of the second track; one of the even-numbered or odd-numbered samples of the first channel A rotating head type magnetic recording system characterized in that the other side of the sample is recorded in the second area of the second track. 17 The even number samples of the first channel are
the odd samples of the second channel in the first region of the track;
a second region of the track, an even number of samples of the second channel is added to the second region of the track;
the odd samples of the first channel in the first region of the track;
17. The rotating head magnetic recording system according to claim 16, wherein recording is performed in the second area of the track. 18 Even samples of the first channel are placed in the first area of the first track, and even samples of the second channel are placed in the first area of the first track.
Odd samples of the second channel are added to the second region of the track.
the odd samples of the first channel in the first region of the track;
17. The rotating head magnetic recording system according to claim 16, wherein recording is performed in the second area of the track. 19. A redundant signal for error control is generated from one track worth of digital signals to be recorded, and the redundant signal is recorded so as to be included in the same track as the digital signal that generated the redundant signal. A rotating head magnetic recording system according to claim 17 or 18. 20 A rotating head type magnetic reproducing system that reproduces digital signals of two channels, first and second, while sequentially scanning diagonal tracks formed on a recording medium, wherein each track is longer than the center of the track. It has at least a first region in the first half of the direction and a second region in the second half, and the two-channel sample for unit time is the first region,
In a second method for reproducing what is recorded in a distributed manner in each of the areas, either the even-numbered or odd-numbered samples of the first channel are reproduced using the first and second two tracks as a unit. reproducing from a first area of the first track; reproducing either an even or odd sample of a second channel from a second area of the first track; playing the other one of the samples from a first area of the second track; playing the other of the even or odd samples of the first channel from a second area of the second track; for each channel; A rotating head type magnetic reproducing system characterized by rearranging the sample order and outputting it. 21 even samples of the first channel from the first region of the first track; odd samples of the second channel from the first region;
From a second region of the track, even samples of the second channel are added to the second channel.
From the first region of the track, the odd samples of the first channel are transferred to the second channel.
21. A rotary head type reproducing system as claimed in claim 20, characterized in that reproduction is performed from the second area of the track. 22 even samples of the first channel from the first region of the first track; and even samples of the second channel from the first region.
From a second region of the track, odd samples of the second channel are added to the second channel.
From the first region of the track, the odd samples of the first channel are transferred to the second channel.
21. A rotary head type reproducing system as claimed in claim 20, characterized in that reproduction is performed from the second area of the track. 23. The rotary head reproducing magnetic system according to claim 21 or 22, wherein error detection and correction are performed in units of signals for one track.