JP3598554B2 - Digital video signal recording device and reproducing device - Google Patents

Description

[0001]
[Industrial applications]
The present invention particularly relates to a digital video signal recording apparatus for recording a composite color video signal transmitted in a letterbox format, such as ED-TV2 or PALplus, which sends a signal for enhancing resolution to a non-screen portion or a main screen portion. About.
[0002]
[Prior art]
2. Description of the Related Art In recent years, a broadcasting system, such as an EDTV-2 system or a PALplus system, which achieves high image quality and a wide screen while maintaining compatibility with television signals of the NTSC system and the PAL system has been proposed. That is, in the current NTSC system and PAL system, the aspect ratio is 4: 3. On the other hand, the aspect ratio of the wide screen is 16: 9 or 14: 9, and the screen is horizontally longer than the current screen. The EDTV-2 system and the PALplus system are designed so that when a 16: 9 wide screen is projected on a television receiver, the image quality can be improved and the current 4: 3 television can be projected. It is.
[0003]
These EDTV-2 system and PALplus system are based on letter box type screens. In the letterbox type, as shown in FIG. 21, a screen is projected at the center, and the upper and lower sides of the screen are blank. For example, in the case of the NTSC system, a video signal is placed on 360 lines at the center of the screen, and the upper and lower 60 lines are blank. As a result, a 16: 9 horizontally long screen is formed.
[0004]
In the case of EDTV-2, as shown in FIG._TAnd V_HThe signal is multiplexed and H_HThe signals are multiplexed. V_TThe signal is a vertical time high-frequency component that is lost in the process of interlacing when transmitting an image signal photographed in double-speed non-interlace by interlacing. V_HThe signal is a vertical luminance high frequency component that is lost when a 16: 9 image signal is converted to a letterbox type. In other words, if the transmission is performed in the letterbox type, the number of scanning lines is reduced from 480 to 360 in the NTSC system, and the vertical resolution is reduced to about 3/4. V_HThe signal reinforces the vertical luminance high frequency component lost at this time. H_HThe signal is a horizontal luminance high frequency component of 4.2 MHz to 6 MHz. H_HThe signal is frequency-shifted and multiplexed to a blow-hole in the main screen.
[0005]
In the case of EDTV-2, as shown in FIG. 23, NRZ signals (B1 to B4) indicating the aspect ratio are provided on the lines 22 and 285,_T, V_H, H_HAn identification signal indicating the presence or absence of each signal component (modulated by the color subcarrier, and the V_T, V_H, H_HIs identified), and a confirmation signal of 2.04 MHz for identifying EDTV-2 is provided at the end.
[0006]
In the case of the PALplus system, as shown in FIG. 24, helper signals for reinforcing the vertical resolution are multiplexed above and below the screen of the letter box. In the case of the PALplus system, as shown in FIG. 25, a line 23 is provided with a WSS (Wide Screen Signaling) signal indicating the aspect ratio and the presence / absence of a helper signal. In the latter half, a reference burst signal of a subcarrier frequency (4.43 MHz) is provided. Further, a reference signal indicating the level of 100% white is sent to a line 623.
[0007]
In order to prepare for such EDTV-2 or PALplus broadcasting, the applicant of the present application has proposed a digital VTR of a compression recording system capable of recording an EDTV-2 or PALplus signal. .
[0008]
In other words, when the ED-TV2 signal is recorded by the digital VTR of the compression recording system by the digital VTR of the compression recording system, the V signals sent to the non-screen portions above and below the screen._TAnd V_HThe signal is treated and recorded as a luminance signal. H on the main screen_HThe signal is decoded, multiplexed with the luminance signal of the main screen, and recorded. The aspect ratio information of the lines 22, 285 is unchanged, and the identification signal is decoded, and the information is stored as VAUX data (video preliminary data).
[0009]
When recording a PALplus video signal, a helper signal sent to a non-screen portion above and below a screen is demodulated, treated as a luminance signal, and recorded. The WSS signal on line 23 is extracted from the PALplus signal, and the data of the WSS signal is stored as VAUX data.
[0010]
By the way, in a digital VTR, only an effective screen is extracted and compression-coded, and data in a vertical blanking period and a horizontal blanking period are dropped. In the digital VTR of the compression system as described above, in the case of the NTSC system (525-60 system), as shown in FIG. 26, the effective lines are the lines 23 to 262 in the field 1 and the lines 285 to 524 in the field 2. It is defined as. In the case of the PAL system (625-50 system), as shown in FIG. 27, lines 23 to 310 in field 1 and lines 335 to 622 in field 2 are defined as effective lines.
[0011]
When the effective lines are determined in this manner, in the case of the NTSC system (525-60 system), the image signals of the lines 22 and 263 and 0.5H and the line 525 are lost, and in the case of the PAL system, , The image signal of 0.5H on the line 623 is lost. However, these lost image signals are hidden at the top and bottom of the screen in the current 4: 3 aspect ratio television system, so that there is no practical problem.
[0012]
[Problems to be solved by the invention]
However, if an effective line is set as described above, the line 285 becomes an effective line in the case of the EDTV-2 system. A signal indicating the aspect ratio of EDTV-2, an identification signal indicating the presence or absence of each signal component, and a confirmation signal of 2.04 MHz (FIG. 23) are sent to this line 285.
[0013]
In the case of the PALplus system, the line 23 is an effective line. The line 23 receives a WSS signal (FIG. 25) indicating the aspect ratio and the presence / absence of a helper signal, and a reference signal.
[0014]
As described above, when the line 285 of EDTV-2 or the line 23 of the PALplus method is in the effective screen, the following problem occurs.
[0015]
First, the signal on the line 285 of EDTV-2 and the signal on the line 23 of PALplus include a signal related to a subcarrier. These signals are recorded as a chroma signal component on a digital VTR. In a compression type digital VTR, recording is performed at 4: 1: 1 or 4: 2: 0, and the amount of information allocated to a chroma signal is small. If these signals are recorded as a chroma signal, they are converted to an original chroma signal. And the color reproducibility is significantly deteriorated.
[0016]
Further, these lines include NRZ signals. Since the NRZ signal contains a wide range of frequency components from DC to very high frequencies, the compression effect by DCT is small. As a result, a coarse quantization table is used at the time of quantization, and the image quality deteriorates.
[0017]
Further, when a signal indicating the presence / absence of a signal for enhancing the aspect ratio and resolution stored in the VAUX is added at the time of reproduction, if the line to be inserted is set as an effective line, it is used during recording and reproduction. Due to the clock phase shift, the EDTV-2 decoder and the PALplus decoder may mix not only the data restored from the VAUX data but also the data compressed and recorded and expanded / reproduced as a real screen in a shifted position. There is a possibility of malfunction.
[0018]
SUMMARY OF THE INVENTION It is therefore an object of the present invention to provide a digital video signal recording apparatus which prevents deterioration of image quality when an EDTV-2 signal or a PALplus signal is recorded.
[0019]
[Means for Solving the Problems]
The present inventionMeans for inputting a composite color video signal, which is transmitted in a letterbox format and in which a signal for enhancing resolution is multiplexed in a no-screen portion and an identification signal is included in a predetermined line,
A luminance signal from the input composite color video signal, and, while generating a component color video signal consisting of a color difference signal, processing means to treat a signal that reinforces the resolution of the non-screen part as a luminance signal,
Means for decoding an identification signal sent to a predetermined line;
Means for fixing the luminance signal of a predetermined line including the identification signal at a predetermined level, among the component color video signals composed of the luminance signal and the color difference signal,
Means for extracting valid information from a component color video signal comprising a luminance signal and a color difference signal;
Means for compression-coding a component color video signal consisting of a luminance signal extracted as valid information and a color difference signal,
Means for generating preliminary data based on the identification signal sent to the predetermined line,
Means for adding preliminary data generated based on an identification signal sent to a predetermined line to a component color video signal composed of a compression-coded luminance signal and a color difference signal,
Means for recording, on a recording medium, a component color video signal composed of a compression-coded luminance signal to which preliminary data has been added, and a color difference signal;
Equipped withIt is a digital video signal recording device.
[0020]
The present inventionA component color video signal composed of a luminance signal and a color difference signal from a composite color video signal transmitted in a letterbox format, in which a signal for enhancing resolution is multiplexed in a non-screen portion and an identification signal is included in a predetermined line. And process the signal that reinforces the resolution of the non-screen part as a luminance signal,
Preliminary data is generated based on an identification signal sent to a predetermined line and including information indicating a letterbox format aspect ratio, and the identification signal is included in a component color video signal including a luminance signal and a color difference signal. Fixed the luminance signal of a given line at a given level,
A component color video signal composed of a luminance signal extracted as valid information and a color difference signal is compression-encoded, and the generated preliminary data is converted to a component color video signal composed of a compression-encoded luminance signal and a color difference signal. Add
In a digital video signal reproducing apparatus for reproducing a recording medium on which a component color video signal composed of a compression-coded luminance signal to which preliminary data is added and a color difference signal is recorded,
Means for reproducing a component color video signal from a recording medium;
Means for performing decompression processing on the reproduced compression-encoded component color video signal to generate a component color video signal including a luminance signal and a color difference signal;
Spare dataDecrypts the decrypted dataMeans for generating an identification signal from
Component color video signal to composite color video signalconversionAnd remove the offset of the no-screen part of the luminance signal,
Signal that enhances resolutionButMultiplexingLuminance signalMeans for inserting the generated identification signal into a predetermined line with respect to the luminance signal of the no-screen portion from which the offset has been removed, and
Digital video signal provided withPlaybackDevice.
[0021]
[Action]
In an EDTV-2 video signal, aspect ratio information, an identification signal, and a confirmation signal are sent to lines 22 and 285. Of the lines 22 and 285, the line 285 is an effective line. When the video signal is compressed and recorded, the signal on the line 285 is fixed to, for example, a pedestal level.
[0022]
In the case of a PALplus video signal, a WSS signal is sent to a line 23. This line 23 is in the effective line. When compressing and recording a video signal, the signal on the line 23 is fixed at, for example, a pedestal level.
[0023]
As described above, when a line to which information indicating an aspect ratio or the like is transmitted is present in an effective screen in EDTV-2 or PALplus, a signal of this line is fixed to, for example, a pedestal level. Thereby, deterioration of image quality can be prevented.
[0024]
【Example】
Embodiments of the present invention will be described in the following order with reference to the drawings.
a. Overall configuration for EDTV-2
b. EDTV-2 recording processing circuit
c. Digital VTR recording system for EDTV-2
d. Digital VTR playback system for EDTV-2
e. EDTV-2 playback processing circuit
f. Overall configuration for PALplus
g. PALplus recording processing circuit
h. Recording system and reproduction system of digital VTR in case of PALplus
i. PALplus playback processing circuit
[0025]
a. Overall configuration for EDTV-2
1 and 2 show an embodiment in the case of recording and reproducing an EDTV-2 signal. In FIG. 1, 1 is a tuner, 2 is an EDTV-2 recording processing circuit, and 3 is a digital VTR. The tuner 1 receives an EDTV-2 signal. EDTV-2 signals include, for example, V_TAnd V_HThe signal is multiplexed and H_HThe signal is multiplexed. Then, signals indicating the aspect ratio and V_T, V_H, H_HAnd an identification signal indicating the presence or absence of each signal component, and a confirmation signal of 2.04 MHz for identifying EDTV-2. The reception signal of the EDTV-2 system is supplied to the EDTV-2 recording processing circuit 2.
[0026]
The EDTV-2 recording processing circuit 2 processes an EDTV-2 signal so that the digital VTR 3 can record an EDTV-2 signal. The EDTV-2 recording processing circuit 2 has an H_HThe signal is decoded, multiplexed with the luminance signal of the main screen section, and the V signals transmitted to the non-screen sections above and below the screen are decoded._TAnd V_HAn offset is added to the signal so that the signal can be recorded as a luminance signal. At the same time, the identification signal sent to the lines 22, 285 is decoded from the EDTV-2 signal, and the aspect ratio, V_T, V_H, H_HOf each signal component is extracted. Since the digital VTR 3 processes at a sampling frequency of 13.5 MHz, it can record up to a band of about 6 MHz. From the EDTV-2 recording processing circuit 2, the component color signals Y, C_R, C_BIs output, and this component color signal is supplied to the digital VTR 2. Also, the aspect ratio, V_T, V_H, H_HIs transmitted to the digital VTR 3.
[0027]
The digital VTR 3 uses the component color signals Y, C_R, C_BIs compressed using DCT and a variable length code, and is recorded on a magnetic tape by a rotating head. When recording an EDTV-2 signal, the aspect ratio and the V_T, V_H, H_H, And the like is provided, and these are stored in the digital VTR 3 as VAUX data. At this time, in this embodiment, H_HSince the signal is decoded and the signal is restored in the 6 MHz band, H_HThe signal is saved as none. When a video signal is recorded by the digital VTR 3, only the effective portion is extracted. Of the lines 22, 285 to which the identification signal and the like are sent, the line 22 is outside the valid line, but the line 285 is inside the valid line. In this embodiment, the signal on line 285 is replaced by a pedestal level signal. As a result, these signals are not recorded as an effective screen, and deterioration of color reproducibility and image quality are prevented.
[0028]
FIG. 2 shows the configuration of the reproducing system. In FIG. 2, component color video signals Y and C are output from a digital VTR 5._R, C_BIs output. This component color video signal Y, C_R, C_BIs, as described above, the luminance signal reproduced from the main screen portion is H_HThe signals are multiplexed, and the luminance signal in the non-screen part at the top and bottom of the screen is V_TAnd V_HSignal. This component color video signal Y, C_R, C_BIs supplied to the EDTV-2 reproduction processing circuit 6. Also, from the digital VTR 5, the aspect ratio and the V_T, V_H, H_HAnd data such as the presence or absence of each signal component, and color phase data. These data are supplied to the EDTV-2 reproduction processing circuit 6.
[0029]
The EDTV-2 reproduction processing circuit 6 outputs the V_TAnd V_HRemove signal offset. Furthermore, data of the aspect ratio, V_T, V_H, H_H, And a confirmation signal of 2.04 MHz for identifying EDTV-2, and multiplexes them on line 22 and line 285.
[0030]
The output of the EDTV-2 reproduction processing circuit 6 is supplied to a wide-screen television receiver 7. The television receiver 7 has an EDTV-2 decoder. The television receiver 7 decodes the EDTV-2 signal and displays it on a television screen.
[0031]
In this embodiment, the luminance signal is returned to the 6 MHz band. With a normal composite video input or S input, the 6-MHz band can be transmitted from the digital VTR 3 as it is, so that high image quality can be obtained without any processing.
[0032]
b. EDTV-2 recording processing circuit
FIG. 3 is an example of the EDTV-2 recording processing circuit 2. In FIG. 3, an EDTV-2 signal is supplied to an input terminal 11. The signal from the input terminal 11 is supplied to a three-dimensional Y / C separation circuit 12. The luminance signal Y and the chroma signal C are separated by the three-dimensional Y / C separation circuit 12. At the same time, in the three-dimensional Y / C separation circuit 12, a signal multiplexed in the blow-out hole is taken out,_HThe signal is supplied to the signal demodulation circuit 13. H_HThe signal demodulation circuit 13 multiplexes H_HThe signal is demodulated. This H_HFrom the output of the signal demodulation circuit 13, a high-frequency horizontal luminance component having a frequency of 4.2 to 6 MHz is obtained. This H_HThe output of the signal demodulation circuit 13 is supplied to the addition circuit 14.
[0033]
The Y / C separation circuit 12 outputs a luminance signal Y having a frequency up to 4.2 MHz and a chroma signal C. The luminance signal Y is supplied to the adding circuit 14. The adding circuit 14 adds H to the luminance signal Y up to the frequency of 4.2 MHz._HA high-frequency horizontal luminance component having a frequency of 4.2 to 6 MHz from the signal demodulation circuit 13 is added. The output of the adder circuit 14 is supplied to a terminal 15A of the switch circuit 15. The chroma signal from the Y / C separation circuit 12 is supplied to the switch circuit 16.
[0034]
The signal from the input terminal 11 is supplied to the offset adding circuit 17 and also to the identification signal decoding circuit 18. Further, the synchronization signal in the signal from the input terminal 11 is detected by the synchronization separation circuit 20. The output of the sync separation circuit 20 is supplied to the line decoder 21. The output of the line decoder 21 is supplied to the identification signal decoding circuit 18 and to the switch control circuit 22.
[0035]
The offset adding circuit 17 outputs the V signal sent to the non-image portion so that the signal can be processed as a luminance signal._TAnd V_HThis is to give an offset to the signal. The output of the offset adding circuit 17 is supplied to the terminal 15B of the switch circuit 15.
[0036]
The identification signal detection circuit 18 detects the aspect ratio, V, sent to the lines 22, 285._T, V_H, H_HOf each signal component is detected. The output of the identification signal detection circuit 13 is output from the data output terminal 19. Further, the state of the three-dimensional Y / C separation circuit 12 is set according to the identification signal detected by the identification signal detection circuit 18.
[0037]
The switch control circuit 22 forms a switch control signal for switching between a main screen portion and a non-screen portion. This switch control signal is supplied to the switch circuits 15 and 16. With this switch control signal, the switch circuits 15 and 16 are switched between the main screen and the non-screen.
[0038]
That is, in the main screen portion at the center of the screen, the switch circuit 15 is set to the terminal 15A side, and the switch circuit 16 is turned on. In the upper and lower non-screen portions, the switch circuit 15 is set to the terminal 15B side and the switch circuit 16 is turned off. Therefore, from the switch circuit 15, the horizontal high-frequency component H_HIs output, and in the non-screen portion, the vertical resolution reinforcement signal V to which the offset is added is output._T, V_HIs output. The switch circuit 16 outputs the chroma signal C on the main screen section, and does not output the signal on the non-screen section.
[0039]
The output of the switch circuit 15 is output from the output terminal 23. The output of the switch circuit 16 is supplied to the color demodulation circuit 24. The color demodulation circuit 24 converts the chroma signal C into the color difference signal C_R, C_BIs demodulated. This color difference signal C_R, C_BAre output from the output terminals 25 and 26.
[0040]
c. Digital VTR recording system for EDTV-2
FIG. 4 shows a configuration of a recording system of the digital VTR 3. In FIG. 4, input terminals 31, 32, and 33 have component color video signals Y and C, respectively._R, C_BIs supplied. This component color video signal Y, C_R, C_BIs supplied to the A / D converter 34. The A / D converter 34 outputs the component signals Y, C_R, C_BIs digitized by a sampling clock having a frequency of 13.5 MHz. In the case of the NTSC system, the color difference signal C_R, C_BAre set to 1 and digitized in a so-called 4: 1: 1 manner. The output of the A / D converter 34 is supplied to a masking circuit 38.
[0041]
Further, the input video signal is supplied to the sync separation circuit 35. The synchronization signal is detected by the synchronization separation circuit 35. The output of the sync separation circuit 35 is supplied to a line decoder 36. The output of the line decoder 36 is supplied to a masking signal generation circuit 37. The masking signal generation circuit 37 is supplied from the controller 30 with a signal indicating whether or not the signal is of the EDTV-2 system. The masking signal generating circuit 37 generates a masking signal on line 285 when an EDTV-2 signal is input. This masking signal is supplied to the masking circuit 38.
[0042]
When an EDTV-2 signal is input by the masking circuit 38, the signal on the line 285 is masked to a predetermined value (for example, a value 16 indicating a pedestal level).
[0043]
The output of the masking circuit 38 is supplied to a valid information extracting circuit 39. In the effective information extracting circuit 39, data outside the effective screen, such as a vertical blanking period and a horizontal blanking period, is dropped, and only data within the effective screen is extracted. Here, the effective lines are 23 lines to 262 lines of field 1 and 285 lines to 524 lines of field 2. In EDTV-2, data of aspect ratio, V_T, V_H, H_HAn identification signal indicating the presence or absence of each signal component and a confirmation signal of 2.04 MHz for identifying EDTV-2 are multiplexed on the line 22 and the line 285. No, so it is removed here. Line 285 is within the active line, but has been switched to pedestal level by masking circuit 38.
[0044]
The output of the effective information extraction circuit 39 is supplied to a blocking and shuffling circuit 40. Blocking and shuffling circuit 40 blocks the data into (8 × 8) blocks, and the compression is averaged over the entire screen, and data is intensively lost due to clogging of the head or damage to the tape. Shuffling is performed to prevent the
[0045]
The output of the blocking and shuffling circuit 40 is supplied to the compression circuit 41. The compression circuit 41 compresses video data by DCT transform and variable length coding. That is, the compression circuit 41 uses a DCT transform circuit, a quantizer for quantizing the DCT-transformed data, an estimator for estimating the total code amount and determining an optimal quantizer, and a two-dimensional Huffman code. And a variable length encoding circuit for compressing the data. The compression circuit 41 converts the data in the (8 × 8) time domain into coefficient data in the (8 × 8) frequency domain, which is quantized and subjected to variable length coding.
[0046]
The output of the compression circuit 41 is supplied to the framing circuit 42. In the framing circuit 42, video data is packed in a predetermined sync block according to a predetermined rule. The output of the framing circuit 42 is supplied to the VAUX adding circuit 43.
[0047]
VAUX data is supplied from the VAUX generation circuit 44 to the VAUX addition circuit 43. The VAUX generating circuit 44 receives VAUX data from the controller 30. The video data to which the VAUX data has been added by the VAUX adding circuit 43 is supplied to the multiplexer 45.
[0048]
The terminal 46 receives the aspect ratio data and identification signal data (V_T, V_H, H_H, Etc.), and color phase information. The VAUX data generated from the VAUX generating circuit 44 includes these data.
[0049]
Specifically, the VAUX is provided with a TR pack (header 66h) shown in FIG. 12, and the data of the identification signal is recorded in this TR pack. The aspect ratio information is recorded as a DISP (Display Select Mode) of a VAUX source control pack (header PC0 = 61h). The color phase information is recorded as a CLF (Color Frame Identification Code) of the VAUX source pack (header PC0 = 60h).
[0050]
The input terminal 47 is supplied with an audio signal. This audio signal is supplied to the A / D converter 48. The audio signal is digitized by the A / D converter 48. This audio signal is supplied to the audio signal processing circuit 49. In the audio processing circuit 49, audio data is packed in a predetermined sync block. The output of the audio signal processing circuit 49 is supplied to the AAUX adding circuit 50.
[0051]
The AAUX addition circuit 50 is supplied with AAUX data from the AAUX generation circuit 51 under the control of the controller 30. The AAUX adding circuit 50 adds AAUX data to the audio data. The audio data to which the AAUX data is added is supplied to the multiplexer circuit 45.
[0052]
The subcode is generated by the subcode generation circuit 52. The subcode data is used for a high-speed search. This subcode data is supplied to the multiplexer circuit 45.
[0053]
The multiplexer circuit 45 switches between video data, audio data, and subcode data. The output of the multiplexer circuit 45 is supplied to the error correction encoding circuit 54. The error correction encoding circuit 54 adds an error correction code to the recording data. The output of the error correction coding circuit 54 is supplied to a channel code 55. In the channel coder 55, the recording data is subjected to 24/25 conversion. Here, a coding process of a partial response class 4 suitable for digital recording is further performed. The output of the channel coder 55 is supplied to a head 56 via a recording amplifier (not shown).
[0054]
Tracks are formed in the video track as shown in FIG. At the beginning of each track, an ITI area is provided, followed by an audio area, a video area, and a subcode area. The ITI area is a timing block for reliably performing post-recording, and is used to accurately perform positioning when post-writing and rewriting data written in an area thereafter. Audio data is recorded in the audio area. In the video area, compressed video data is recorded. The subcode area is used for high-speed search. When recording NTSC data, one video frame is recorded on 10 tracks.
[0055]
FIGS. 6 and 7 show the structure of data in the audio area. As shown in FIG. 6, one sync block is composed of 90 bytes. The first five bytes of the data part are pre-sync and post-sync, and the data part is 77 bytes (72 bytes of audio data and 5 bytes of AAUX). The data part is protected by a horizontal parity C1 (8 bytes) and a vertical parity C2 (5 sync blocks). As shown in FIG. 7, 14 sync blocks are arranged per track. The first five bytes of the data part are for AAUX. One pack is composed of these 5 bytes.
[0056]
FIGS. 8 and 9 show the structure of data in the video area. One sync block in the video area is composed of 90 bytes. The first five bytes of the data part are pre-sync and post-sync, and the data part is 77 bytes. As shown in FIGS. 8 and 9, the data is protected by a horizontal parity C1 (8 bytes) and a vertical parity C2 (11 sync blocks).
[0057]
FIG. 9 shows 149 sync blocks of a video sector arranged vertically. As shown in FIG. 9, the upper two sync blocks and the two sync blocks immediately before the C2 parity are reserved for VAUX. Video data other than for VAUX and C2 parity is stored. In FIG. 9, 135 sync blocks at the center are storage areas for video signals. In the figure, BUF0 to BUF26 indicate buffering units, respectively. One buffering unit includes five sync blocks, and one track includes 27 buffering units. In one video frame and 10 tracks, there are 270 buffering units. That is, an area effective as an image is extracted from the image data of one frame, and is sampled and collected to form 270 groups. One group is one buffering unit.
[0058]
For each buffering unit, data compression is attempted by DCT transformation, quantization, variable-length coding, and the like, and it is evaluated whether the amount of generated code is equal to or less than target data. Then, a quantization step in which the amount of generated data is equal to or smaller than the target is determined, and actual encoding is performed using this quantization step. Then, the generated encoded data is packed into one buffering unit and five sync blocks.
[0059]
FIG. 10 shows the data structure of the subcode area. The subcode area is composed of 12 sync blocks as shown in FIG. One sync block is 12 bytes, and is shorter than one sync block in the video area and the audio area. This is to enable a high-speed search. A 1-byte pre-sync and a post-sync are provided at the beginning of one sync block. Subsequently, three bytes of ID data consisting of ID0 and ID1 and IDP which is a parity for ID0 and ID1 are added. Next, a 5-byte main data area is provided, and a 2-byte parity is added. The main data area stores time code, recording date, etc., necessary for high-speed search.
[0060]
As shown in FIGS. 10C and 10D, ID0 is provided with an F / R flag for detecting an address during a high-speed search. Subsequently, as shown in FIG. 10C, in the sync block numbers SB0 and SB6, an application ID (API3) indicating the data structure of the subcode is arranged, and an absolute track number is arranged so as to straddle the next ID1. You. For the other sync block numbers, as shown in FIG. 11D, an F / R flag is provided, followed by an index ID, a skip ID, and a photo picture ID. Is provided. ID1 is provided with an absolute track number and a sync number.
[0061]
The spare data AAUX in the audio area, the spare data VAUX in the video area, the subcode data, and the data (not shown) of the cassette with memory are described in a common pack structure as shown in FIG. The pack is basically composed of 5 bytes (PC0 to PC4), with the first byte being a header and the remaining 4 bytes being data.
[0062]
The header is divided into upper 4 bits and lower 4 bits, and is divided into two layers, and can be further extended to a lower layer by data bit assignment. With this layering, the contents of the pack are clearly organized and its expansion is also prepared. The upper and lower headers are used to prepare 256 spaces together with the contents of the pack as a pack header table. Using this, each area is described. The pack structure has a basic structure of 5 bytes, with the exception of a variable length when characters are described in a cassette with memory.
[0063]
FIG. 12 shows the configuration of a VAUX TR pack in which an identification signal is stored. In the TR pack, the header byte PC0 is set to “66h”. The data type (DATA TYPE) is 4 bits and distinguishes various signals. This data type (DATA TYPE) is defined as follows.
[0064]
0000 = VBID
0001 = WSS
0010 = EDTV-2 in 22 lines
0011 = EDTV-2 in 285 lines
0100 = No Information
Other = undefined
[0065]
When the EDTV-2 signal is recorded in this TR pack, as described above, the data of the identification signal of the line 22 and the line 285 is stored. The data portion is prepared for 28 bits. Then, data is packed in order with the one closer to the horizontal synchronization signal being the LSB.
[0066]
FIG. 13 shows a configuration of a VAUX source pack in which color phase information is stored. In the source pack, the header byte PC0 is set to “60h”. The PC 1 stores a color frame identification code (CLF). The color frame identification code (CLF) is defined in the 525/60 system as follows.
[0067]
00 = color frame A
01 = color frame B
Others are reserved
[0068]
In the 625/50 system, it is defined as follows.
00 = first and second fields
01 = third and fourth fields
10 is the fifth and sixth fields
11 = 7th and 8th fields
[0069]
FIG. 14 shows the configuration of a VAUX source control pack in which aspect ratio information is stored. In the source control pack, the header byte PC0 is set to “61h”. The PC 2 is provided with a display select mode (DISP). The display select mode (DISP) defines the aspect ratio as follows.
[0070]
000 = 4: 3 normal
001 = 4: 3 letter box
010 = 16: 9
[0071]
d. Digital VTR playback system for EDTV-2
FIG. 15 shows an example of the configuration of the reproduction system 5 of the digital VTR. In FIG. 15, the reproduction signal of the head 61 is supplied to a channel decoder 62 via a reproduction amplifier (not shown). The reproduction signal is demodulated by the channel decoder 62. The output of the channel decoder 62 is supplied to an error correction circuit 63. The error correction circuit 63 performs an error correction process. The output of the error correction circuit 63 is supplied to the demultiplexer 64.
[0072]
The demultiplexer 64 separates the reproduction data of the audio area, the reproduction data of the video area, and the reproduction data of the subcode area.
[0073]
The reproduction data of the audio area is supplied to the audio processing circuit 67. AAUX data in the reproduction data of the audio area is detected by the AAUX decoding circuit 68. The AAUX data is supplied to the controller 60. The audio processing circuit 67 performs processing such as time axis conversion and interpolation. The output of the audio processing circuit 67 is supplied to the D / A converter 70. The output of the D / A converter 70 is output from the output terminal 71.
[0074]
The reproduction data of the video area is supplied to the deframe circuit 65. Further, VAUX data in the reproduction data of the video area is detected by the VAUX decoding circuit 66. This VAUX data is supplied to the controller 60.
[0075]
From the VAUX TR pack, data of the identification signals of the lines 22 and 285 is obtained. Color phase information can be obtained from the VAUX source pack. Also, aspect information can be obtained from the VAUX source control pack. These pieces of information are output from the data output terminal 79 and sent to the EDTV-2 reproduction processing circuit 6 (FIG. 6).
[0076]
The reproduced data in the subcode area is detected by the subcode decoding circuit 69. This subcode data is supplied to the controller 60.
[0077]
The output of the deframe circuit 65 is supplied to the expansion circuit 72. The expansion circuit 72 converts the compressed and recorded video signal into the original time domain video signal by decoding the variable length code and inverse DCT. The output of the decompression circuit 72 is supplied to a deshuffling and deblocking circuit 73. From the deshuffling and deblocking circuit 73, the reproduced component color video signals Y, C_RC_BIs obtained. The reproduced component color video signals Y, C_RC_BIs supplied to the information adding circuit 74. The information adding circuit 74 adds a horizontal synchronizing signal, a vertical synchronizing signal, and the like. The output of the information adding circuit 74 is supplied to a D / A converter 75. The output of the D / A converter 75 is output from output terminals 76, 77, 78.
[0078]
In the case of reproducing an EDTV-2 video signal, in this embodiment, in addition to the luminance signal up to a frequency of 4.2 MHz, the reproduced luminance signal Y of the main screen portion has a high frequency of 4.2 to 6 MHz. A luminance component is added. Further, the reproduced luminance signal Y of the non-screen portion is represented by V to which an offset is added._TAnd V_HSignal. From the data output terminal 79, aspect ratio information, color phase information, V_T, V_H, H_HOf each signal component is extracted. Since the line 22 for arranging the identification signal and the like is outside the effective screen, it is at the pedestal level. The line 285 is within the effective screen, but has been switched to the pedestal level by the masking circuit 38 of the recording system of the VTR.
[0079]
e. EDTV-2 playback processing circuit
FIG. 16 shows the configuration of the EDTV-2 reproduction processing circuit 6. In FIG. 16, a reproduced luminance signal Y is supplied to an input terminal 81, and a reproduced chrominance signal C is supplied to input terminals 82 and 83._R, C_BIs supplied. Also, the aspect ratio information, color phase information, V_T, V_H, H_HIs given.
[0080]
The reproduction luminance signal from the input terminal 81 is supplied to the switch circuit 85, and a synchronization signal of the input signal is detected by the synchronization separation circuit 86. Reproduction color difference signal C from input terminals 82 and 83_R, C_BIs supplied to the modulation circuit 90. In the modulation circuit 90, the color difference signal C_R, C_B, A chroma signal C is formed. The output of the modulation circuit 90 is supplied to the switch circuit 91.
[0081]
The output of the sync separation circuit 86 is supplied to the line decoder 87. The line decoder 87 decodes the number of lines. The output of the line decoder 87 is supplied to a switch control circuit 88 and also to an identification signal generation circuit 89. The switch control circuit 88 forms a switch control signal for switching between a main screen portion and a non-screen portion. This switch control signal is supplied to the switch circuits 85 and 91. The switch circuits 85 and 91 are switched between the main screen and the non-screen by the switch control signal. That is, in the main screen portion at the center of the screen, the switch circuit 85 is set to the terminal 85A side, and the switch circuit 91 is turned on. In the upper and lower non-screen portions, the switch circuit 85 is set to the terminal 85B side and the switch circuit 91 is turned off.
[0082]
In the main screen portion, the switch circuit 85 is set on the terminal 85A side, and a signal from the input terminal 81 is supplied to the addition circuit 95 via the switch circuit 85. In the main screen, the switch circuit 91 is turned on. For this reason, the chroma signal C is supplied from the modulation circuit 90 to the addition circuit 95. The luminance signal Y and the chroma signal C are combined by the adder circuit 95. The output of the addition circuit 95 is supplied to the addition circuit 97.
[0083]
In the non-screen portion, the switch circuit 85 is set to the terminal 85B side, and the signal from the input terminal 81 is supplied to the offset removing circuit 96. In the offset removing circuit 96, the offset is removed. The output of the offset removing circuit 96 is supplied to the adding circuit 97. The output of the adding circuit 97 is supplied to the adding circuit 98.
[0084]
Data from the data input terminal 84 is supplied to the identification signal generation circuit 89. The output of the line decoder 87 is supplied to the identification signal generation circuit 89. The identification signal generating circuit 89 generates the signals of the lines 22 and 285. That is, the identification signal generation circuit 89 outputs the NRZ signal indicating the aspect ratio and the V_T, V_H, H_H, An identification signal indicating the presence or absence of each signal component, and a 2.04 MHz confirmation signal for identifying EDTV-2. This signal is supplied to the adding circuit 98.
[0085]
The NRZ signal indicating the aspect ratio and the V_T, V_H, H_HAnd an identification signal indicating the presence or absence of each signal component, and a 2.04 MHz confirmation signal for identifying EDTV-2. As described above, when signals are added to the lines 22 and 285, the reproduced signals on the lines 22 and 285 are at the pedestal level, so that data can be added without error. The output of the adding circuit 98 is taken out from the output terminal 99.
[0086]
The signal output in this manner is a signal of the EDTV-2 system. Therefore, if the signal is supplied to an EDTV-2 compatible television receiver, a high-quality reproduction screen with a wide screen can be enjoyed.
[0087]
f. Overall configuration in the case of PALplu
Next, the case of the PALplus system will be described. FIGS. 17 and 18 show an embodiment in which a signal of the PALplus system is recorded.
[0088]
In FIG. 17, 101 is a tuner, 102 is a PALpus recording processing circuit, and 103 is a digital VTR. The tuner 101 receives a PALplus signal. A helper signal for reinforcing the vertical resolution is multiplexed on the PALplus signal at the top and bottom of the screen. In the case of the PALplus method, a line 23 is provided with a WSS (Wide Screen Signaling) signal indicating the aspect ratio and the presence or absence of a helper signal. (4.43 MHz) reference burst signal is provided. Further, a reference signal indicating the level of 100% white is sent to a line 623. The PALplus received signal is supplied to the PALplus recording processing circuit 102.
[0089]
The PALplus recording processing circuit 102 processes a PALplus signal so that the digital VTR 103 can record. This PALplus signal processing 102 decodes a helper signal sent to a non-screen part above and below the screen, adds an offset, and records the helper signal as a luminance signal. At the same time, it decodes the WSS signal sent to the line 23 from the PALplus signal, and sends to the digital VTR 103 information such as aspect ratio information and information indicating the presence or absence of a helper signal.
[0090]
The digital VTR 103 uses component color signals Y, C_R, C_BIs compressed using DCT and a variable length code, and is recorded on a magnetic tape by a rotating head. When recording a PALplus signal, data such as an aspect ratio and the presence or absence of a helper signal are given, and these are recorded as VAUX data of the digital VTR 103. When a video signal is recorded by the digital VTR 103, only an effective part is extracted. The line 23 to which the WSS signal is sent is within the valid line. In this embodiment, the signal on the line 23 is replaced with a pedestal level signal. As a result, these signals are not recorded as an effective screen, and deterioration of color reproducibility and image quality are prevented.
[0091]
FIG. 18 shows the configuration of the reproduction system. In FIG. 18, component color video signals Y and C are output from a digital VTR 105._R, C_BIs output. This component color video signal Y, C_R, C_BIs supplied to the PALplus reproduction processing circuit 106. From the VAUX data, the digital VTR 105 outputs data indicating the presence or absence of a helper signal and the aspect ratio. These data are supplied to the PALplus reproduction processing circuit 106.
[0092]
The PALplus reproduction processing circuit 106 removes the offset of the helper signal in the non-screen part and modulates it. Further, it generates aspect ratio data, a WSS signal indicating presence / absence of a helper signal, and a reference signal, and multiplexes them on a line 23.
[0093]
The output of the PALplus reproduction processing circuit 106 is supplied to a wide-screen television receiver 107. The television receiver 107 includes a PALplus decoder. The television receiver 107 decodes the EDTV-2 signal and displays it on the television screen.
[0094]
g. PALplus recording processing circuit
FIG. 19 is an example of the PALplus recording processing circuit 102. In FIG. 19, a PALplus signal is supplied to an input terminal 111. The signal from the input terminal 111 is supplied to the Y / C separation circuit 112. The luminance signal Y and the chroma signal C are separated by the Y / C separation circuit 112. The luminance signal Y from the Y / C separation circuit 112 is supplied to a terminal 114A of the switch circuit 114. The chroma signal from the Y / C separation circuit 112 is supplied to the switch circuit 120.
[0095]
The signal from the input terminal 111 is supplied to the helper signal demodulation circuit 113 and also to the WSSS signal decoding circuit 116. Further, the synchronization signal in the signal from the input terminal 111 is detected by the synchronization separation circuit 117. The output of the sync separation circuit 117 is supplied to the line decoder 118. The output of the line decoder 118 is supplied to the WSS signal decoding circuit 116 and to the switch control circuit 119.
[0096]
The helper signal demodulation circuit 113 demodulates the helper signal. The output of the helper signal demodulation circuit 113 is supplied to the offset adding circuit 115. The offset adding circuit 115 gives an offset to the demodulated helper signal so that it can be processed as a luminance signal. The output of the offset adding circuit 115 is supplied to a terminal 114B of the switch circuit 114.
[0097]
The WSS signal detection circuit 116 detects the WSS signal sent to the line 23. The output of the WSS signal detection circuit 116 is output from the data output terminal 125.
[0098]
The switch control circuit 119 forms a switch control signal for switching between a main screen portion and a non-screen portion. This switch control signal is supplied to the switch circuits 114 and 120. With this switch control signal, the switch circuits 114 and 120 are switched between the main screen and the non-screen.
[0099]
That is, in the main screen portion at the center of the screen, the switch circuit 114 is set to the terminal 114A side, and the switch circuit 120 is turned on. In the upper and lower non-screen portions, the switch circuit 114 is set to the terminal 114B side, and the switch circuit 120 is turned off. Therefore, the luminance signal Y is output from the switch circuit 114 in the main screen portion, and a helper signal to which an offset is added is output in the non-screen portion. The switch circuit 120 outputs the chroma signal C on the main screen portion, and does not output the signal on the non-screen portion.
[0100]
The output of the switch circuit 114 is output from the output terminal 122. The output of the switch circuit 120 is supplied to the color demodulation circuit 121. The color demodulation circuit 121 converts the chroma signal C into the color difference signal C_R, C_BIs demodulated. This color difference signal C_R, C_BAre output from the output terminals 123 and 124.
[0101]
h. Recording system and reproduction system of digital VTR in case of PALplus
The configuration of the digital VTRs 103 and 105 for recording / reproducing a PALplus signal is the same as that for recording the EDTV-2 signal described above. However, when recording a PALplus signal, the A / D converter 34 in FIG. 4 digitizes the component color video signal at 4: 2: 0. Further, a masking signal is generated from the masking signal generation circuit 37 on the line 23, and the WSS signal on the line 23 is replaced with a pedestal level signal. Then, one video frame is recorded on 12 tracks. Further, WSS data is recorded in the VAUX TR pack, and aspect ratio information is recorded in the VAUX source control pack.
[0102]
i. PALplus playback processing circuit
FIG. 20 shows the configuration of the PALplus reproduction processing circuit 106. In FIG. 20, a reproduced luminance signal Y is supplied to an input terminal 131, and a reproduced color difference signal C is supplied to input terminals 132 and 133._R, C_BIs supplied. The data input terminal 134 is supplied with aspect ratio information and data on the presence or absence of a helper signal.
[0103]
The reproduction luminance signal from the input terminal 131 is supplied to the switch circuit 135, and a synchronization signal of the input signal is detected by the synchronization separation circuit 136. Reproduction color difference signal C from input terminals 132 and 133_R, C_BIs supplied to the modulation circuit 140. In the modulation circuit 140, the color difference signal C_R, C_BTo form a chroma signal C. The output of the modulation circuit 140 is supplied to the switch circuit 141.
[0104]
The output of the sync separation circuit 136 is supplied to a line decoder 137. The line decoder 137 decodes the number of lines. The output of the line decoder 137 is supplied to the switch control circuit 138 and to the WSS signal generation circuit 139. The switch control circuit 138 forms a switch control signal for switching between a main screen portion and a non-screen portion. This switch control signal is supplied to the switch circuits 135 and 141. The switch circuits 135 and 141 are switched between the main screen and the non-screen by the switch control signal. That is, in the main screen portion at the center of the screen, the switch circuit 135 is set to the terminal 135A side and the switch circuit 141 is turned on. In the upper and lower non-screen portions, the switch circuit 135 is set to the terminal 135B side, and the switch circuit 141 is turned off.
[0105]
In the main screen portion, the switch circuit 135 is set on the terminal 135A side, and a signal from the input terminal 131 is supplied to the addition circuit 142 via the switch circuit 135. In the main screen, the switch circuit 141 is on. For this reason, the chroma signal C is supplied from the modulation circuit 140 to the addition circuit 142. The addition circuit 142 combines the luminance signal and the chroma signal. The output of the addition circuit 142 is supplied to the addition circuit 143.
[0106]
In the non-screen portion, a helper signal is supplied to the input terminal 131. This helper signal is supplied to the offset removing circuit 144 via the switch circuit 135. In the offset removing circuit 144, the offset is removed. The output of the offset removal circuit 144 is supplied to the modulation circuit 145. The modulation circuit 145 modulates the helper signal. The output of the modulation circuit 145 is supplied to the addition circuit 143.
[0107]
Data from the data input terminal 134 is supplied to the WSS signal generation circuit 139. The output of the line decoder 137 is supplied to the WSS signal generation circuit 139. WSS signal generation circuit 139 generates a WSS signal on line 23. This signal is supplied to the adding circuit 146.
[0108]
The WSS signal is added to the line 23 by the adding circuit 146. When a signal is added to the line 23, since the reproduced signal on the line 23 is at the pedestal level, data can be added without error. The output of the adding circuit 146 is taken out from the output terminal 147. Since the signal output in this manner is a PALplus signal, if it is supplied to the PALplus-compatible television receiver 107, it is possible to enjoy a wide-screen, high-quality reproduction screen.
[0109]
【The invention's effect】
According to the present invention, in the EDTV-2 video signal, the aspect ratio information, the identification signal, and the confirmation signal are sent to the lines 22, 285. Of the lines 22 and 285, the line 285 is an effective line. When the video signal is compressed and recorded, the signal on the line 285 is fixed to, for example, a pedestal level. In the case of a PALplus video signal, a WSS signal is sent to a line 23. This line 23 is in the effective line. When compressing and recording a video signal, the signal on the line 23 is fixed at, for example, a pedestal level. As described above, when a line to which information indicating an aspect ratio or the like is transmitted is present in an effective screen in EDTV-2 or PALplus, a signal of this line is fixed to, for example, a pedestal level. Thereby, deterioration of image quality can be prevented.
[Brief description of the drawings]
FIG. 1 is a block diagram used for explaining a case where an EDTV-2 signal is recorded.
FIG. 2 is a block diagram used for explaining a case of reproducing an EDTV-2 signal.
FIG. 3 is a block diagram of an example of an EDTV-2 recording processing circuit.
FIG. 4 is a block diagram of a recording system of a digital VTR to which the present invention is applied.
FIG. 5 is a schematic diagram used for describing a track configuration in a digital VTR to which the present invention is applied.
FIG. 6 is a schematic diagram used for describing audio data in a digital VTR to which the present invention is applied.
FIG. 7 is a schematic diagram used for describing audio data in a digital VTR to which the present invention is applied.
FIG. 8 is a schematic diagram used for describing video data in a digital VTR to which the present invention is applied.
FIG. 9 is a schematic diagram used for describing video data in a digital VTR to which the present invention is applied.
FIG. 10 is a schematic diagram used for describing subcode data in a digital VTR to which the present invention is applied.
FIG. 11 is a schematic diagram used for describing a pack structure.
FIG. 12 is a schematic diagram used to describe a pack.
FIG. 13 is a schematic diagram used to describe a pack.
FIG. 14 is a schematic diagram used to describe a pack.
FIG. 15 is a block diagram of a reproduction system of a digital VTR to which the present invention is applied.
FIG. 16 is a block diagram illustrating an example of an EDTV-2 reproduction processing circuit.
FIG. 17 is a block diagram used for describing a case where a PALplus signal is recorded.
FIG. 18 is a block diagram used for describing a case where a PALplus signal is reproduced.
FIG. 19 is a block diagram illustrating an example of a PALplus recording processing circuit.
FIG. 20 is a block diagram illustrating an example of a PALplus reproduction processing circuit.
FIG. 21 is a schematic diagram used for describing a letter box format.
FIG. 22 is a schematic diagram used for describing an EDTV-2 signal.
FIG. 23 is a schematic diagram used for describing an EDTV-2 signal.
FIG. 24 is a schematic diagram used for explaining a PALplus signal.
FIG. 25 is a schematic diagram used for describing a PALplus signal.
FIG. 26 is a schematic diagram used to describe an effective line in the 525/60 system.
FIG. 27 is a schematic diagram used to describe an effective line in the 625/50 system.
[Explanation of symbols]
2 EDTV-2 recording processing circuit
3, 5 Digital VTR
6 EDTV-2 playback processing circuit
38 Masking circuit

Claims (5)

Means for inputting a composite color video signal, which is transmitted in a letterbox format and in which a signal for enhancing resolution is multiplexed in a no-screen portion and an identification signal is included in a predetermined line,
A luminance signal from the input composite color video signal, and a component color video signal composed of a color difference signal, and a means for processing such that a signal for enhancing the resolution of the non-screen portion is treated as a luminance signal;
Means for decoding the identification signal sent to the predetermined line;
Means for fixing the luminance signal of a predetermined line including the identification signal to a predetermined level, among the component color video signals composed of the luminance signal and the color difference signal,
Means for extracting effective information from the component color video signal comprising the luminance signal and the color difference signal,
Means for compression-coding a component color video signal consisting of a luminance signal extracted as the valid information and a color difference signal,
Means for generating preliminary data based on the identification signal sent to the predetermined line,
Means for adding, to the component color video signal composed of the compression-coded luminance signal and the color difference signal, preliminary data generated based on the identification signal sent to the predetermined line,
A digital video signal recording apparatus, comprising: means for recording, on a recording medium, a component color video signal composed of the compression-coded luminance signal to which the spare data has been added and the color difference signal. The composite color video signal transmitted in the letterbox format and multiplexed with a signal for enhancing resolution in a non-screen portion is an EDTV-2 signal, and the predetermined line from which the identification signal is transmitted is a line 22 and a line 22. 2. The digital video signal recording apparatus according to claim 1, wherein the signal of the predetermined line which is 285 and the fixed level is a signal of the line 285. The composite color video signal transmitted in the letterbox format and multiplexed with the signal for enhancing the resolution in the non-screen part is a PALplus signal, the predetermined line from which the identification signal is sent is line 23, 2. The digital video signal recording apparatus according to claim 1, wherein the signal of the predetermined line which is set to the fixed level is a signal of the line 23. 4. The digital video signal recording device according to claim 1, wherein the fixed level is a pedestal level. A component color video signal composed of a luminance signal and a color difference signal from a composite color video signal transmitted in a letterbox format, in which a signal for enhancing resolution is multiplexed in a non-screen portion and an identification signal is included in a predetermined line. And processing so as to treat a signal for enhancing the resolution of the non-screen part as a luminance signal,
Preliminary data is generated based on the identification signal sent to the predetermined line and including the information indicating the aspect ratio of the letterbox format, and the identification signal is output from the component color video signals including the luminance signal and the color difference signal. Is fixed to a predetermined level of the luminance signal of a predetermined line including
A component color video signal composed of a luminance signal extracted as valid information and a color difference signal is compression-encoded, and the above-mentioned auxiliary signal generated into a component color video signal composed of the compression-encoded luminance signal and the color difference signal is compressed. Add data,
In the digital video signal reproducing apparatus for reproducing a recording medium on which a component color video signal composed of the color difference signal and the compression encoded luminance signal to which the preliminary data is added,
Means for reproducing the component color video signal from a recording medium,
Means for performing a decompression process on the reproduced compressed and encoded component color video signal to generate a component color video signal including a luminance signal and a color difference signal;
Means for decoding the spare data and generating the identification signal from the decoded data ;
While converting the component color video signal to a composite color video signal, removing the offset of the non-screen portion of the luminance signal,
The luminance signal of the non-screen portions where the luminance signal signal for reinforcing the resolution is multiplexed with the offset has been removed, the generated the identification signal to comprise a means for insertion into said predetermined line Digital video signal reproducing device.

Images