DE4008114A1 - RECORDING MEDIA PLAYER - Google Patents

Description

The invention relates to a playback device for a Recording medium to the recording medium, e.g. Legs Video disc or a digital audio disc (CD).

A system has been proposed in which image information is recorded and reproduced from the subcode form on a digital audio disc with a diameter of 12 cm (hereinafter referred to as compact disc (CD)). The subcode is formed from 8 subcode bits , and which form the subcode of the bit groups are divided into 8 channels, each designated by the letters P, Q, R, S, T, U, V and W. In the method in which the image information is recorded in subcode form and reproduced, data corresponding to the image information is configured so that a symbol is formed by 6 bits of the channels R through W inclusive of the 8 bits forming the subcode, and 98 symbols are treated as one block as in Fig. 1 Two of the 98 symbols are used as a sync signal, and 24 symbols obtained by dividing the remaining 96 symbols by four are treated as a minimal data unit, ie a "pack", which inst image processing.

In particular, this shows (later referred to as symbol 0) first symbol out of the 24 symbols one of different Operating modes (modes). A symbol following this symbol 0 1 forms "instruction", which indicates the type of instruction shows. Form symbols 2 and 3 that follow symbol 1 a "parity Q" i.e. an error correction code. The pa the following symbols 4 to 19 inclusive form a Data field and contain information such as color information. Finally, symbols 20 through 23 inclusive the data field a parity P, which is an error correction code to protect the information in the "pack".  

There are four modes of operation namely the "zero mode", the "line graphics mode" the "TV graphics mode" art "and the" user mode ". The" zero mode "is provided for a case when no operation for pictures the display screen is required, i.e. if the original image is to be maintained, and therefore all data is in the "Pack" in this mode 0.

The "line graphic mode" is provided for such a case that a liquid crystal display is provided on the front surface of the player, and this display gives explanations of a piece of music, for example. As shown in Fig. 2, a laterally elongated image area is formed by pixels arranged in 288 columns and 24 rows. In other words, each row contains 288 pixels and each column contains 24 pixels. The term "pixel" stands for the smallest display element of an image, and generally the image processing is carried out using image construction elements called "fonts", each consisting of pixels divided into 6 columns and 12 lines.

The number of "fonts" that operate in the "line graphics art "can be displayed is 48 in the lateral direction and in column direction 2, and this area is called "screen area che ". To create a scroll function will create a line of "fonts" at the top and bottom outer edge and the right and left side edge of the Screen area added and so an image area with 50 "fonts" in the row direction and four "fonts" in the column direction det. The subcode is formed so that the image processing is carried out in that a memory with addresses be is used, which corresponds to the pixels in the image area chen. In addition, the area outside the "screen Reichs "referred to as the" border ".  

The "TV graphics mode" is a mode for displaying images on the screen, and an image is formed as shown in FIG. 3 by pixels arranged in 192 rows and 288 columns. The number of "fonts" that can be displayed in the "TV graphics mode" is 48 in the row direction and 16 in the column direction. Also in this "TV graphics mode", the subcode is formed so that the image processing is carried out using a memory with addresses that correspond to each pixel in an image area with 50 "fonts" in the row direction and 18 "fonts" in Column direction, created by adding a row of "fonts" at the top and bottom, as well as on the right and left outer edge of the "screen area".

There is an In as instructions for image processing structure to fill the entire image area with a be agreed color, an instruction to draw a picture in a "font" on the screen using two different ones colors, an instruction to move the whole picture up or to the side etc.

Also included in the groups forming the subcode 8 bits each of the Q bits forming the Q channel information according to the track length to a specific location each Information date from the beginning of the program area of the CD is recorded and form address time data as the Position data representing the recording position is used can be. On the other hand, they form the channel P. P-bits of data including information related to one Pause between two pieces of music.

In the case of the above-described system for recording and reproducing image information as a subcode, up to 19 image channels can be assigned. In particular, an instruction "write font foreground / background" with a structure according to FIG. 4 is used in the "TV graphics mode". This is an instruction for writing font data of symbols 8 to 19 inclusive at positions with a row address defined by symbol 6 and a column address defined by symbol 7. For the pixels whose font data is "0", a color is assigned a color number determined by the "color 0" as the background color. For the pixels with font data "1", a color of the color defined by the color number "Color 1" is assigned as the foreground color. At the same time, sub-picture channels can be designated by using 4 bits of channels R and S of symbols 4 and 5. This allows up to 16 picture channels to be assigned to who. For example, 16 types of images are previously recorded on a disk and a desired image channel can be selected on the playback side at the time of playback using this image channel designation scheme.

In addition, the 16 colors denoted by the color numbers "0" to "15" are set by an instruction "Load CLUT color 0 to color 15 (CLUT = color look-up table)." The instruction "Load CLUT color 0 to color 15" is an instruction with a structure according to FIG. 5, which sets the contents of a color call table which determines the colors of the previously set color numbers or foreground / background color numbers. It is necessary to designate a total of 16 colors. However, since 4 bits are used for each value of RGB (red, green, blue) to designate a color, two symbols are required to set a color. That is why up to 8 colors are determined by a "pack". Under these circumstances, this instruction is divided into two instructions, each assigning 8 colors to the first half and 8 colors to the second half.

The instruction code for the color of the first half, ie the colors 0 to 7 inclusive, is set to "30" and the instruction code for the color of the second half, ie the colors 8 to 15 inclusive, is set to "31". The mixing of colors for each color number is done as follows. Red color is denoted by 4 bits of the channels R through and finally U of straight symbols which are assigned to the color number. Green color is represented by 4 bits, ie 2 bits of channels V and W after channels R to U including the even symbols, and 2 bits of channels R and S of the odd symbols. Blue color is represented by 4 bits of channels T through W inclusive after channels R and S of the odd symbols. Therefore 2 ⁴ (= 16) types of gray scales can be reached for each color and the generation of 16 ³ (= 4096) colors is possible because three basic colors (RGB) are used. In addition, a gray scale "0000" corresponds to the darkest state and a gray scale "1111" corresponds to the brightest state.

The present invention has been made by the same inventors developed a system on which an FM modulated video format signal in addition to a digital one Record audio signal to which graphics code finally image information can be used accordingly the recording and reproducing system described above ben of image information as a subcode, so that by the Subcode image obtained in the video format signal image received when playing the recording medium can be set. The system is in the JP application P63-46 603 explained.

In order for the FM-modulated video format signal to be displayed and the image represented by the subcode to be displayed on the same screen at the same time, the system of this known application uses a new code, as shown in FIG. 6, as the symbol 0 to be set to designate an additional mode of operation, ie "graphics mode with moving image" in addition to "mode 0", "line graphics mode", "TV graphics mode" and "user mode"", which are also used in the usual method for recording and reproducing image information using the subcode.

The structure of an image in the "graphics mode with moving image" is identical to the "TV graphics mode" and an instruction called "load transparency control panel" is provided in FIG. 7. This instruction "Load transparency control panel" is an instruction to designate the mode of operation for each pixel in the image area. Three modes or modes of operation are designated by this instruction, and these are the "transparent mode", "mixed mode" and the "non-transparent mode". In these three operating modes, different values are selected for the mixing ratio between a video format signal obtained by a subcode and a video format signal which is recorded by a multiplex operation together with the coded information signal including the subcode.

The bits in channels R through W inclusive of each of symbols 4 through 8 and channels R and S of symbol 9 form a series of codes TCB-0 through TCB-15, each of which designates one of the operating modes as later for each group of Pixels explained in more detail, to which one of the colors that are recorded as color number "0" to color number "15" is assigned. Fig. 8 shows the relationship between bit patterns of the codes TCB-0 to TCB-15 and the modes of operation designating the mixing ratio and the mixing ratio in each mode.

A player for the recording medium for playback play a recording medium on which information through recorded the system of the known application described net, is also in JP application P 63-46 603 be wrote. This player for a recording me dium is constructed in such a way that that obtained by the subcode Image signal and the Vi recorded in FM modulation form mixed deformatatsignal and out with a mixing ratio are given according to the graphic codes which the color of each pixel in the display area of the image by the subko de represent.

As for the video format signal recorded on the disc hits, there is a video format signal in PAL video format like also the video format signal in NTSC video format. The number the scan lines are in NTCS format 525, while in PAL format is 625. The number of picture elements in a displayed image of the subcode image is in vertical However, in the direction of 288. In these circumstances, it existed Problem that a relative size of the subcode image with Regarding the image of the video format signal itself in vertical direction differs in cases where the subcode ab image combined with the image of the NTCS format video signal and those in which the subcode image with the image of the PAL format video signal is combined.

In order to solve this problem, a method was examined where the content of the image editing instructions that are to be recorded as a subcode, depending on the Si Signal format of the video format signal have been changed. Ent However, there is again a problem with such a ver drive the number of image editing instructions for the Recording medium must be increased because the PAL format Vi deo signal recorded here with more horizontal scan lines is not.

The present invention is to solve this problem directed, and an object of the invention is a To create a recording medium player in which the relative size of the subcode image is in the vertical direction not depending on the signal format of the video forum matsignals changes that with the FM modulation method was drawn.

To achieve this goal, a recording medium Playback device according to the present invention with a provide the first counting means, the counting value of which is related to the ho Rizontal sync signal of the video format signal in the read out NEN signal changes, and with a second counting means, the Count value changes with a clock signal whose frequency is higher than that of the horizontal sync signal. Depending on Signal format of the video format signal is the supply of the horizontal sync signal to the first counting means periodically locked for a length of time that of the numerical differences limit of the horizontal scan lines of the two types of video format signals corresponds, with a predetermined period rate. After the graphic code from the coded Infor Mation signal pulled out in the read signal and again has been stored in a memory, the graphic code se read out from memory in the order of Addresses by the output signals of the first and the second counting means are designated. An image signal is ent generated according to the read graphic code and to the Vi mixed format signal.

With the playback device for a recording constructed in this way The counting value of the first counting medium remains perio unchanged during a period corresponding to the Difference in the number of horizontal scan lines of the two Types of video format signals with a predetermined perio  rate, so that the same graphic code repeats can be read. The interpolation is carried out by the read graphic code repeatedly and the subcode Image is drawn in the vertical direction with an expansion factor that extends the numerical difference of the horizontal scan lines of two types of video format signals.

The invention is described below with reference to the drawing exemplified in more detail; in this shows:

Fig. 1 is a diagram of the recording format of sub-code data,

Fig. 2 is a diagram of the image structure in the "Liniengraphik- mode",

Fig. 3 is a diagram of the image structure in the "TV-graphics Be triebsart"

Fig. 4 is a diagram showing the construction of the "write font front ground / background" instruction,

Fig. 5 is a diagram of the instruction "Load color Besetzungsta fel 0 to 7 color"

Fig. 6 is a graph of the existing recording operating modes,

Fig. 7 is a diagram showing the construction of the "load transparency CONT ertafel" instruction,

Fig. 8 is a diagram of a star correspondence between the TCB Bitmu and the mixing ratio,

FIG. 9A to 9C in combination, a block diagram of he inventive playback apparatus (FIG. 9, the unity of the Figs. 9A to 9C)

Fig. 10 is a diagram of the recording areas together a quantitative set plate,

Fig. 11 is a block diagram of a particular embodiment of a video format signal processing circuit 30 in the apparatus of FIG. 9A to 9C,

Fig. 12 is a flowchart of the processing operation in the control system of the device according to FIG. 9A to 9C,

13 is an illustration of images, the processing with the Vorrich according to FIG. 9A to 9C are Fig. Achievable

Fig. 14 is a diagram of an image from achieved by the subcode when the NTSC-format video signal is demodulated in the apparatus of FIGS. 9A to 9C,

FIG. 15A to 15E are timing charts for the operation of parts of the apparatus of FIG. 9A to 9C, and

Fig. 16 is a diagram of an image obtained by the subcode when the PAL format video signal is demodulated by the device of Figs. 9A to 9C.

Embodiments of the method according to the invention and the device according to the invention will now be explained with reference to FIGS .

In FIGS. 9A to 9C and 10, a plate 20 is shown as the voltage Aufzeich medium. As shown, the composite plate 20 has a first, inner area 20 a (later called CD area), in which a digital audio signal is recorded with the subcode, for example containing image information, and a second recording area 20 b (later called video area) with an FM-modulated video format signal and a superimposed digital audio signal, the subcode including image information being inserted, and the superimposition being carried out by a frequency division multiplex system. Since the video format signal higher Frequenzkomponen th contains as the PCM signal, it is necessary to run the disc at a higher speed when the signals are recorded b in the video area 20, drawing than the signal on the CD region 20 a. It is therefore of course necessary to let the disc run during playback of the video area 20 b at a higher speed than during playback of the CD area 20 a, even during playback. The speed of the disc during playback of the CD area 20 a is a few 100 rpm, while the speed during playback of the video area is 2000 and a few 100 rpm when playing the innermost edge of this area and 1000 plus a few 100 rpm when playing the outermost scope of this area is, so that the speed during the video area playback is extremely high.

In the introductory or header sections of the CD area 20 a and the video area 20 b, a lead-in area is provided, in which index codes are recorded as subcodes, which relate to the content recorded in the respective area, for example first and second code groups which are formed in accordance with each area by repeating index codes which respectively denote the start and end times of small sections which together form each area. In addition, index codes of the audio lead-in area contain disc type information which indicates whether the disc itself is a composite disc or another disc.

The disk 20 is driven by a spindle motor 21 as shown in FIG. 9A, and information recorded thereon is read out by means of a pickup 22 . The pickup 22 contains an optical system with a laser diode, an objective lens and photodetectors, a focus actuator for driving the objective lens in the direction of its optical axis with respect to the information recording surface of the plate 20 , a track actuation for driving the beam spot emitted by the pickup 22 (information detection point) bezüg Lich the recording tracks in the radial direction of the disc, etc. The transducer 22 sits on a slider 23 which is movable in ra dialer direction of the disc by a direct drive of a transmission mechanism 25 , which in turn has a slider motor 24 as a driving force source and from a combination of racks and pinions is built up. An RF (radio frequency) signal output by the pickup 22 is supplied to a video format signal demodulation and processing circuit 30 and a demodulation and processing circuit 31 for coded information via an RF amplifier 26 .

The video format signal demodulation and processing circuit 30 includes a demodulator circuit which, for. B. demodulates the RF signal and converts it into a video format signal, and a memory which stores and configures the video format signal after its digitalization, either one of the video format output signals by the demodulator circuit or the failure of the memory according to a change output a video format signal read out to a system control. The video format signal output by the video format signal demodulating and processing circuit 30 is supplied to a video switch 33 . In addition, the video format signal demodulation and processing circuit 30 is further provided with a separation circuit which separately separates a horizontal sync signal h, a vertical sync signal v and control data C from the demodulated video signal, and the separated horizontal and vertical sync signals h and v as well as the control data c are supplied to the respective parts such as the system controller 32 .

On the other hand, the demodulation and processing circuit 31 for coded information is provided with a selector switch 35 which changes its switch position according to the area to be played (CD area or video area) while playing a composite disc. The selector switch 35 is set to a position during playback of the CD area and to a position b during playback of the video area, and the change is carried out in response to a change command that the system controller 32 issues. In the composite disc, its speed changes extremely between the CD area and the video area, and the PCM audio signal is, for example, an EFM signal (Eight to Fourteen Modulation = 8:14 modulation). In the video area, the EFM signal has a detrimental effect on the low-frequency component of the video signal treated by the FM modulation process if the digital signal is directly superimposed on the FM video signal at the time of recording. Therefore, the digital signal, ie the EFM signal, is recorded at a level which is several 10 db lower than the video carrier level, although the degree of modulation of the EFM and video signals is almost the same. This means that both the amplitude and the frequency characteristic of a reproduced EFM signal are different in the case of CD area playback or video area playback. However, a common demodulation system is used for CD area playback and video area playback. This is made possible by switching signal processing systems for the EFM signals played in the CD area or the video area.

In particular, during the reproduction of the CD area, the reproduced RF signal is an EFM signal which is subjected to frequency characteristic compensation by an equalization circuit 36 having a predetermined equalization characteristic and is amplified by an amplifier 37 with a predetermined amplification factor. On the other hand, during the reproduction of the video area, the reproduced RF signal is an FM video signal which is combined with an EFM signal. The EFM signal is separated by an EFM signal isolating circuit 38 , which consists of a low-pass filter, etc., and then subjected to frequency response compensation by an equalizing circuit 39 having a different equalizing characteristic than the equalizing circuit 36 , then in an amplifier 40 to be amplified, which has a higher gain than the amplifier 37 . In this way, an EFM signal is derived, the frequency response and amplitude are almost the same as the EFM signal obtained during the CD range playback.

During the playback of a CD disc, the selector switch 35 is held in position a.

The playback EFM signal selected by the selector switch 35 is supplied to an EFM demodulation circuit 42 which performs the demodulation process to obtain PCM data which is digital data including, for example, time-multiplied audio information for left and right channels, and the like Subcode. The digital data containing audio information output by this EFM demodulation circuit 42 is supplied to a deinterleaving and interpolation circuit 43 . The deinterleaving and interpolation circuit 43 is designed so that together with the RAM 44 it restores the order of digital data which have been rearranged during recording by the deinterleaving process, in turn sends it to an error correction circuit 45 and the interpolation of the erroneous data into the output data of the error correction circuit 45 by, for example, the average value interpolation method when a correction incapacity signal is output. The error correction circuit 45 is designed to perform the error correction process using the CIRC (Cross Interleave Reed Solomon Code) and to supply the digital data to the deinterleaving and interpolation circuit 43 , or the digital data to the deinterleaving and interpolation circuit 43 together with the correction speed signal if error correction is not possible.

The data output from the deinterleaving and interpolation circuit 43 are supplied to a D / A (digital / analog) converter circuit 46 . The D / A converter circuit 46 contains a de-multiplexer which separates the digital data of the audio information for the left channel from that for the right channel, which was combined by the time multiplexing, and thus reproduces audio signals for the left and right channel. After their unnecessary components in TPF (low pass filters) 47 and 48 have been removed, the reproduced audio signals for the left and right channels are applied to the audio output terminals OUT ₁ and OUT ₂ via amplifiers 49 and 50, respectively.

Code at the output by the EFM demodulation circuit 42 Sub are two bits of the channels P and Q control position to the Control panel 32 out, and 6 bits of the channels R to W are ge leads to a de-interleave and error correction circuit 52, in which the Deinterleaving the 6 bits of channels R through W and error correction using parity Q and P are performed. Output data of the deinterleaving and error correction circuit 52 are supplied to an operating mode / instruction decoder 53 . The mode / instruction decoder 53 is designed to decode the mode represented by the 3 bits of channels R through T in symbol 0 of each pack, and the mode represented by the 3 bits of channels U through W of symbol 0 of each pack , and the instruction represented by the 6 bits of channels R through W in symbol 1 of each pack, and each part for signals indicative of the mode of operation and the instruction.

Furthermore, the output data of the deinterleaving and error correction circuit 52 is supplied to an image storage device 55 . The image storage device 55 contains 16 RAM 56 a to 56 p with addresses that correspond to all pixels in an image with 50 "fonts" × 18 "fonts" in the row or column direction, and 4 data bits can be stored in each address , and a memory control circuit 57 for acquiring data indicating the color number of each pixel in each image channel in the output data of the deinterleaving and error correction circuit 52 by using the mode and the instruction indicated by the output of the mode / instruction decoder 53 are and write the same in the corresponding addresses of the RAM 56 a to 56 p and for reading out the memory content of a RAM 56 a to 56 p corresponding to the image channel, which is denoted by a date d by the key actuation in an operating part 60 , by reading out Address data designated addresses.

Read clocks are applied to the memory control circuit 57 from a read clock generation circuit 10 , and the read address data are supplied to the memory control circuit 57 from counters 11 and 12 . The reading clock generation circuit 10 is constructed so that it uses the horizontal and vertical sync signals, for example, to detect a first time interval that is somewhat shorter than a 1H time length, excluding the horizontal return time (blanking time), and a second Time interval corresponding to a 288H time length in the middle of a vertical sync section excluding the vertical retrace time, and as reading clocks creates clocks that are output from a clock generation circuit 13 only during the first and second time intervals, the circuit 13 later be described. Clock signals output from the clock generating circuit 13 are applied to a clock input terminal of the counter 12 . The horizontal sync signal h is applied to the clock generator circuit 13 . The clock generator circuit 13 , for example, consists of a phase-locked loop PLL, and is designed such that it is synchronized with the horizontal sync signal and clock signals with a frequency N (where N is an integer equal to or greater than 2) × the frequency of the horizontal sync signal h generated. In addition, the horizontal sync signal is applied to the reset input terminal of the counter 12 .

At the clock input terminal of the counter 11 , an output signal of an AND gate 14 (logical product) is applied. The horizontal sync signal h is applied to one of the two input terminals of the AND gate 14 . At the other input terminal of the AND gate 14 , an output signal from a modulo 6 counter 16 is applied via a switch 15 . The horizontal sync signal h is applied to a clock input terminal of the modulo 6 counter 16 . The modulo 6 counter is designed so that it only gives an output signal of low level when its count value is "5". An output signal of a signal format detection circuit 17 is applied to a control input terminal of the switch 15 . The Signalfor mat detection circuit 17 is constructed, for example, so that it counts the number of horizontal scanning lines by a counter that counts with the horizontal sync signal h and is reset by the vertical sync signal v and the signal format of that Video format signal demodulation and processing circuit 30 output signal he knows using the counted number of horizontal scanning lines. The detection circuit 17 generates a high level signal as a signal format detection signal when the video signal is of PAL format and a low level signal as a signal format detection signal when the video signal is of NTCS format. The vertical sync signal v is applied to a reset input of the counter 11 .

The output data of the counters 11 and 12 are supplied to the memory control circuit 57 as a high-order bit group or a low-order bit group of the read address data.

The data output of the image storage device 55 is fed to a color table 15 (from now on referred to as CLUT = color look-up table). The CLUT 58 is configured to designate the instruction "Load CLUT color 0 to color 7" and the instruction "Load CLUT color 8 to color 15" from the output data of the deinterleaving and error correction circuit 52 according to the mode and the instruction by the output of the mode / instruction decoder 53 , and holds the color data corresponding to each color number and is designed to select and output the color data of the color number designated by the data read out from the image memory 55 .

The output data of this CLUT 58 consist of three data, each of which represents the level of one of the R, G, B color signals using four bits. The three-data output signal of the CLUT 58 , which indicate the levels of the R, G and B color signals, are applied to a D / A converter circuit 61 , 62 and 63 and converted into analog signals. Output signals of these D / A converter circuits 61 to 63 are supplied to an analog / video converter circuit 65 . The analog / video converter circuit 65 is designed, for example, so that it thereby forms a video signal in NTCS format or PAL format that a luminance signal is obtained and two color difference signals by the output signals of the D / A converter circuits 61 to 63 , A color carrier signal is generated in that the two color difference signals are processed in accordance with the output signal of the signal format detection circuit 17 , the color carrier signal and the luminance signal are combined by summation and sync signals are added. Through this analog / video converter circuit 65 , the output signals of the D / A converter circuits 61 to 63 are converted into a video signal and then passed on.

In addition, the output data of the deinterleaving and error correction circuit 52 are also fed to a transparency control panel 66 (referred to as TCT = transparency control table from here on). The TCT 66 is configured to detect a "load TCT" instruction in the output data of the deinterleaving and error correction circuit 52 according to the mode and the instruction indicated by the output of the mode / instruction decoder 53 , transparency control bits TCB- Hold 0 to TCB-15 and output one of the held TCB-0 to TCB-15 according to a color number indicated by the data read out from the image storage device 55 .

The output signal of the TCT 66 is supplied to a video switch 33 as a control signal. In addition to the output signal of the TCT 66 , the video format signal obtained from the subcode and output by the analog / video converter circuit 65 and the video format signal output by the video format signal demodulating and processing circuit 30 are applied to the video switch 33 .

In the video switch 33 , the video signal obtained from the subcode is passed to a stationary contact X of a changeover switch 68 , and also to the stationary contact y via a resistor R ₁ . No connection is made to a stationary contact z of the changeover switch 68 . The changeover switch 68 is designed such that it optionally outputs one of the signals present at its stationary contacts x, y, z by moving its movable contact u in contact with one of the stationary contacts x, y, z accordingly one of the TCT 66th output control signal brings. The video signal output from the video format signal demodulation and processing circuit 30 is fed directly to a stationary contact z of a changeover switch 69 and also via a resistor R _{2 to} its stationary contact y. No connection is made to a stationary contact x of the changeover switch 69 . The changeover switch 69 , like the changeover switch 68 , is designed to bring its movable contact u into contact with one of its stationary contacts x, y, z in accordance with the control signal. The movable contacts u, u of the changeover switches 68 and 69 are connected to one another. A resistor R ₃ is connected between a common connection point J of the movable contacts u, u and ground. A mixed signal of the video signal obtained from the subcode and the video signal output from the video format signal demodulation and processing circuit 30 is derived at the common junction J. When the movable contacts u, u of the changeover switches 68 and 69 are in contact with the respective stationary contacts x, the mixing ratio of the video signal obtained from the subcode is 100%, and the mixing ratio is reduced to 0% when the moving contacts u , u are in contact with the stationary contacts z, z. On the other hand, when the movable contacts z, z are in contact with the stationary contacts y, y, the mixing ratio M is determined by the resistors R ₁ and R ₂ and the resistance value of the resistors R ₁ and R ₂ is designed so that M has a value owns between 20% and 80%. The signal derived at the common junction J is applied to a video output terminal OUT ₃ .

A position sensor 70 is provided near the path of movement of the transducer 22 in the radial direction of the disk and serves to detect when the beam spot emitted by the transducer 22 reaches a location corresponding to the vicinity of the boundary between the CD and video areas of the composite disk has to generate a detection signal. By generating this detection signal, it can be detected that the pickup 22 has reached the video area. The position sensor 70 can have a known structure, for example it can be an optical sensor. The Erfassungssi outputted by the position sensor 70 gnal the system controller 32 is supplied.

The system controller 32 comprises a microcomputer consisting of a processor, a read-only or read-out memory ROM, a random access memory RAM, etc. The system controller 32 is supplied with various signals and information, such as the horizontal sync signal h, the vertical sync signal v and the control data c, the P-channel and Q-channel bits in that EFM demodulation circuit 42 output subcode, the disk map information from the operation section 60 indicating whether the disk to be played is a CD or a composite disk, and a mode map information from the operation section 60 indicating whether the area to be played back is only that CD area or the video area, or CD and video area together when playing a composite disc. In this system controller 32 , the processor processes the input signals in accordance with programs previously stored in the ROM and performs the control operation for each part of the video format signal demodulation and processing circuit 30 , the selector switch 35 , a drive controller (not shown) At the drive of the spindle motor 21 , the drive circuit 71 to drive the slide motor and the display part 72nd

FIG. 12 shows a block diagram of a particular circuit structure of the video format signal demodulation and processing circuit 30 . As shown, the RF signal from the RF amplifier 26 is demodulated in a demodulator circuit 75 , then a time base correction circuit 76 and a separation circuit 77 are supplied. In the separation circuit 77 , the horizontal sync signal h, the vertical sync signal v and the control data c contained in the video format signal are extracted. The time base correction circuit 76 is composed of, for example, a variable delay element, which may be a CCD (Charge Coupled Device) element, and is designed so that the element's delay amount according to a control signal from the time base control circuit 78 will be changed. The time base control circuit 78 is designed so that it outputs a signal as a control signal which corresponds to a phase difference between an oscillation signal and the reduced signal of a crystal loszillators (VCO) 79 , which is synchronous with the horizontal sync on the separating circuit 77 , for example Signal oscillates, and the horizontal sync signal and the color burst signal of the video signal, which are passed through the time base correction circuit 76 . For special interpretation, attention is drawn, for example, to JP-A-P 56-1 02 182.

The video signal processed by the time base correction is applied to an input of a selector switch 80 and also leads to an A / D converter 82 via a TPF (low-pass filter) 81 . In the A / D converter 82 , the video signal is sampled at intervals of a predetermined length of time, and the samples thus obtained are in turn converted into digital data. The output data of the A / D converter 82 is supplied to a video memory 83 which consists of a RAM (random access memory), etc. A memory having a capacity for storing video information of at least the length of one picture is taken as the video memory 83 . Address and mode controls of this video memory 83 are effected by a memory control circuit 84 . The memory control circuit 84 is designed to perform control operations for sequentially reading data written at each address of the video memory 83 , corresponding to one clock from a reference clock generator circuit 85 , and rewriting the contents of each Addresses of the video memory 83 as a function of a write enable signal b output by the system controller 32 . The data read out from the video memory 83 are converted into an analog signal in a D / A converter (digital / analog converter) 86 and fed to the selector switch 82 as a second input signal by a TPF 87 . The selector switch 80 is normally held in position a so that it optionally outputs the video signal which is supplied directly from the time base correction circuit 76 , and is switched to a position b in response to a change command from the system controller 32 , to selectively output the video signal processed by the video memory 83 .

The operation of the processor in system controller 32 according to the design described will now be described in particular with reference to the flow chart in FIG. 12.

It is assumed that a composite plate is in the play position. When a start command is issued from the operating part 60 in this state, the processor sends a drive command to the motor drive circuit 71 so that the slider motor 84 is driven to move the receiving part 22 to an inner circumferential position (step S 1 ). When it is detected that the receiving part 22 has reached the innermost circumferential position, which can be done with a (not shown) detector circuit of conventional design, the processor initiates a focusing operation of the receiving part 22 and reads index code information that is in an audio Introductory area is recorded in the innermost circumferential area of the plate (step S 2 ). The processor then detects on the basis of the information read out whether or not the inserted disk is a composite disk (step S 3 ). If it is detected that the inserted disc is a CD, the operation goes directly to a CD playback mode in step S 4 and a play mode is continuously executed unless a command has been issued, for example, for the programmed music selection mode. Since the play mode in the CD play mode itself is well known, further explanation need not be given here.

If it is detected in step S 3 that the inserted disk is a composite disk, the processor immediately accelerates the slider motor 21 to a maximum speed for the video area (step S 5 ). At the same time, the processor moves the receiving part 22 at a high speed toward the outer periphery of the plate by driving the slider motor 24 at a high speed (step S 6 ). If it is detected after these operations that the recording part 22 has reached the video area by the detection signal from the position detector 70 (step S 7 ), the processor starts the playback operation of the video area (step S 8 ).

During the playback of the video area, the processor executes the control operation to write the video information of at least one picture (or field) taken from the disc into the video memory 83 . This video information to be ascribed may be, for example, the first information in the video area, or may be designated by an address assignment by the key operation of the actuating part 60 .

If it is detected that the reproduction of the video area has expired, which occurs in step S 9 , the processor slows down the spindle motor 21 to the maximum speed for the CD area (step S 10 ). At the same time, the processor controls the slide motor 24 at high speed in order to move the receiving part 22 at high speed (step S 11 ) to the first circumferential position. If it is detected (in step S 12 ) that the receiving part 22 has reached the innermost circumferential position, which is achieved by the detection output of the aforementioned detector switch (not shown), the processor starts the reproducing operation of the CD area (step S 13 ). At the same time, the selector 80 in the video format signal demodulation and processing circuit 30 is switched to the position b by the processor, thereby selecting and outputting the video information which was written into the video memory 83 during the video area playback. This shows a still image while the CD area is playing. When the completion of the CD area reproduction is detected, by reading the information from the audio output line is detected (step S 14 ), the processor initiates the drive of the slider motor 24 to move the receiving part 22 to its initial position (step S 15 ) to move if there is no other actuation command. Furthermore, the disc is ejected by a loading mechanism (not shown in the drawing), which completes the playback operation.

In the operation sequence just described, the reproduction of information recorded in the CD area of the composite disc is carried out in steps S 10 through S 14 after playing information recorded in the video area in steps S 1 through S inclusive 9 .

When the instructions "Load CLUT color 0 to color 7 inclusive" and "Load CLUT color 8 to color 15 inclusive" are decoded by the mode / instruction decoder 53 during video area playback, the data of associated 16 colors becomes 4096 Colors held in the CLUT 58 .

By decoding the instruction "write font foreground / background" the image data of 16 channels are stored in sequence in RAM 56 a to 56 p in image memory 55 . When a data area of image data of the 16 channels is addressed by pressing a key in the operating part 60 , the image data of the designated channel are sequentially output from the image memory 55 and in turn sent to the CLUT 58 . Through this operation, color data of a color number designated by the image data is then output from the CLUT 58 . A video format signal based on this color data is output from the analog / video converter circuit 65 and supplied to the video switch 33 .

If the "load TCT" instruction is decoded in this state, the transparency control bits TCB-0 to TCB-15, each corresponding to each color number, will be held in the TCT 66 . Among the bits TCB-0 to TCB-15 that are held, the color number corresponding to the one indicated by the data read out from the image memory 55 is selectively output from the TCT 66 , and the mixing ratio in the video switch 33 is designated by the output signal of the TCT 66 . Thus, for each pixel, the mixing ratio between the video signal output from the analog / video converter circuit 65 and the video signal output from the video format signal demodulation and processing circuit 30 is controlled. As a result, a combination of images as shown in Fig. 13 becomes possible. Specifically, the mixing ratio is set to 100% for a section corresponding to each pixel outside an area D of an image A due to the video format output from the video format signal demodulating and processing circuit 30, and to 0% for a section corresponding to each Corresponds to pixels within the range D. On the other hand, the mixing ratio is set to 0% for a section corresponding to each pixel outside an area D 'of an image B due to the video format output signal from the analog / video converter circuit 65, and to 100% for a section corresponding to each pixel within the area D. 'Of the image B. Then an image C can be formed by combining the portion of the image A outside the area D and the portion of the image B within the area D'.

In this way, it is possible to compose an image in which a heading, a music title or an explanation of a scene obtained from the subcode can be inserted into a moving image obtained by the video format signal recorded in the video area , or in a still image that was targeted by the video memory 83 .

When the video format signal is demodulated in NTCS format, the signal format detection signal is low to turn off the switch 15 . The horizontal sync signal h is thus continuously fed to the counter 11 . The count value of the counter 11 is changed sequentially by the pulses which form the horizontal sync signal h, so that the one of the RAM 56 a to 56 p in the image memory 55 inscribed image data corresponding to the designated channel are read out sequentially. Accordingly, as shown in Fig. 14, an image by the subcode is displayed in a display area P _{S of} the subcode image within the display area P _{N of} the image by the NTCS format video format signal. In particular, the image data for one scanning line are among those in address groups A ₁ ∼A ₇ . . ., which correspond to each scan line in the display area P _S , are read out sequentially once, and the image of the subcode is displayed in the display area P _S.

When the PAL video format signal is demodulated, the signal format detection signal is high, so that the switch 15 turns on. If the count of the modulo-6 counter h 16 shown in Fig. 15B by the horizontal sync signal of Fig. Is changed 15A and the count value of the modulo-6 counter 16 is equal to "5", a low level signal is obtained from the modulo 6 counter 16 is output. The low level signal thus output from the modulo 6 counter 16 is supplied to the AND gate 14 by the switch in the "on" position. This blocks the transfer of the horizontal sync signal h to the counter 11 . The horizontal sync signal h coming to the counter 11 is as shown in Fig. 15D. Thus, the count of the counter 11 periodically becomes equal to the count of 1H before during a 1H period at a periodic rate of 5H.

As a result, the address groups A ₁ ∼A ₇ . . ., Inscribed image data each corresponding to each scan line in the display area P _{S of} the subcode image, which is set in the display area P _{P of} the image by the PAL format video signal, read out sequentially to form a 5H time length. Then, the image data read out 1H before is read out repeatedly during the 1H period, so that the interpolation is carried out by the image data read out repeatedly. With this, the subcode image displayed in the display area P _S is stretched at a rate of 6/5. In this way, the relative size of the sub code image in the vertical direction can be made substantially equal to the relative size in the case where the sub code image is combined with the NTCS format image.

Although the interpolation in the described embodiment by the image data from 1H previously executed, it is also possible to carry out the interpolation in that a Average value between the image data from 1H before and the image data of 1H is taken thereafter.

Furthermore, the general was in the described embodiment Compound disk called "CDV" is declared as a case game of the recording medium on which the subcode carrying image information is recorded. It takes however, it should not be particularly emphasized that the present Invention can also be applied to cases in which as a recording medium for recording the tra subcode other recording media such as e.g. the plate called LDD, i.e. a record on which the FM-mo dulated video signal, the FM modulated audio signal and that digital audio signal in CD format are recorded by Use of frequency division multiplexing.

As previously described, the recording is medium player of the type according to the invention tet that a first counting means, the counting value of which Horizontal sync signal of the video format signal in the read out NEN signal changes, and a second counting means, the Count value changes with clock signals that a higher Fre quenz than the horizontal sync signals, provided and depending on the signal format of the video signal nals the supply of the horizontal sync signal periodically is locked for a length of time that is the difference of Number of horizontal scan lines of the two types of Vi deo signals at certain periodic rates. After the graphic code from the encoded information signal  was extracted, contained in the read signal and is written into memory in order, the graphic code is read out in the address order, the by the output signals of the first and second counters is shown. An image signal corresponding to that Read graphic code is generated and the video format signal added.

Therefore, in the recording medium of the present invention giving device the count value of the first counting means pe periodically left unchanged during the time interval ent speaking the difference in the number of horizontal scanning times len, depending on the predetermined periodic rate the signal format of the video signal. So that the same che graphic code repeatedly read out, and the interpolation executed by the graphic code read out. So that will the subcode image in the vertical direction with an expansion factor ge that is the difference in the number of horizontal scans lines, and the change in the relative size of the Subcode image in the vertical direction depending on that Signal format of the video signal is reliably prevented.

Claims (1)

Device for playing back a recording medium on which, in addition to one of two video format signals with different numbers of horizontal scanning lines and a coded information signal, graphic codes including image information are recorded as subcode of the coded information signal, characterized in that the following are provided:
Reading means ( 22 ) for obtaining signals recorded on the recording medium;
Demodulating means ( 30 ) for demodulating a video format signal component included in a read-out signal obtained by the reading means and for outputting a video format signal;
Signal format detection means ( 17 ) for detecting the signal format of the video signal output from the demodulating means and for generating a format detection signal representative of the detected signal format;
Sync separating means ( 30 ) for separating a horizontal sync signal from the video format signal output from the demodulating means;
clock generating means ( 13 ) for generating a clock signal having a frequency higher than the frequency of the horizontal sync signal;
first counting means ( 11 ) is provided, the count value of which changes with the horizontal sync signal;
second counting means ( 12 ) is provided, the count value of which changes with the clock signal;
blocking means ( 14 ) responsive to the format detection signal is provided to periodically block the supply of the horizontal sync signal to the first counting means ( 11 ) for a length of time corresponding to a difference in the number of horizontal scanning lines of the two video signals at a predetermined periodic rate ;
Extraction means ( 53 ) are provided for extracting the graphic code from the coded information signal contained in the read-out signal;
a memory ( 55 ) is provided;
Memory control means ( 57 ) are provided for sequential writing of the graphic code output by the extracting means into the memory and subsequent sequential readout of the graphic code in the address order, which is indicated by the output signals of the first and second counting means;
an image signal deriving means ( 58 ; 66 ) is provided for deriving an image signal corresponding to the graphic image output signal by means of the memory control means; and
Mixing means ( 33 ) are provided for mixing the image signal with the video signal output by the demodulating means.