KR790000848B1 - Information signal recording method - Google Patents

Abstract

A method of recording a television sig. having line and field intervals in substantially circular record tracks on a rotatable record disc, was comprised of pulse modulating the video inform. in each line interval of the television sig., generating pilot carrier sig. during at least a portion of each line interval of the television sig., repeatedly scanning successive scan lines across the width of one of the substantially circular record tracks recording pulse modulated video inform. in each of the scan lines to be recorded, and a gen. pilot carrier sig..

Description

Information signal recording method

1 to 19 are diagrams showing respective parts of the recording and reproducing system including the embodiment of the present invention.

1 is a plan view showing an example of a recording disk which is a recording medium.

2 is an enlarged plan view of a part of the recording track and a waveform diagram of a video signal corresponding to the recording track.

3, 4 and 5 are enlarged and enlarged cross sectional views of different portions of the recording track, respectively.

6 is a manufacturing process chart of the recording disc.

7 is a schematic diagram showing an example of a recording apparatus.

8 is a pattern diagram showing a signal configuration recorded on a recording disc.

9 is a schematic diagram showing a part of another example of the recording apparatus.

FIG. 10 is a plan view showing an optical beam scanning disk of the recording apparatus of FIG.

11 is a system diagram showing an example of a playback apparatus.

FIG. 12 is a plan view showing an arrangement relationship between a light beam scanning disk and a recording disk of the playback apparatus of FIG.

FIG. 13 is an enlarged plan view showing an optical beam scanning disc of the reproducing apparatus of FIG.

14 is an enlarged plan view of a part of the optical beam scanning disc of the reproducing apparatus of FIG.

FIG. 15 is a system diagram showing a specific configuration of a video signal demodulation circuit of the playback apparatus of FIG.

FIG. 16 is a system diagram showing a specific configuration of an audio signal demodulation circuit of the playback apparatus of FIG.

Fig. 17 is a sectional view showing another part of the optical beam scanning disc used in the reproducing apparatus.

Fig. 18 is a plan view showing another example of the light beam scanning disc used in the reproducing apparatus.

FIG. 19 is an enlarged plan view of a portion of an optical beam scanning disc of FIG. 18; FIG.

The present invention relates to a method for recording a very suitable information signal applied to recording a broadband information signal such as a video signal.

The recording of video signals such as television signals is most commonly recorded magnetically using magnetic tape as a recording medium.

However, it is a drawback that zigzag tapes are difficult to live on the way, are inconvenient to handle, difficult to reproduce in large quantities, and complicated and expensive to record and reproduce.

In order to eliminate such defects, various methods of recording video signals have been proposed in which a recording disc as a recording medium can be used to form a spiral recording track. The example method is briefly described below.

A spiral recording track is formed on a recording disk whose surface is mirror-finished, and a row of rows is formed along the extending direction of the recording track. The depth and width are constant, but the length and distance are changing according to the level of the video signal. In this case, one frame of the television signal is recorded on one track of the recording track.

In order to reproduce the signal from the recording disk recorded in this way, the recording disk is rotated at a high speed (1,500 R. P. M) so that the recording track is scanned with an optical beam such as a laser beam according to the extension direction to detect the reflected light.

However, in such a recording method, the recording density of the information signal is not very high for the recording medium, and therefore, when a wideband information signal such as a video signal is recorded on the recording disc, it is difficult to record a sufficient long time.

In addition, since the recording disc must be rotated at high speed, it is very difficult to control the rotation speed and control the tracking by the light beam of the recording track.

In light of this, the present invention can record information signals such as video signals with a high recording density on the recording disk, and at the same time reduce the rotation speed of the recording disk, and also control the rotation control and playback tracking control of the recording disk during playback. We would like to propose an information signal recording method that can be easily done.

In the information signal recording method of the present invention, a spiral or circular recording track is formed on the recording disc, and the time-side modulation signal of the information signal to be recorded is scanned and recorded on the recording track in a direction crossing the extension direction. will be.

Next, an embodiment of the present invention will be described with reference to the drawings. The entire information signal recording and reproducing system including the embodiment will be described separately. First, the recording medium will be described as follows.

As the recording medium, as shown in FIG. 1, a recording disc (1 ilto diameter 30 cm) D is used. This recording disc D is roughly the same as today's voice record board, except that it has a metal oxide film coated on the same material (synthetic resin such as vinyl chloride) as the voice record plate and coated on it to protect it. The point is mirror finish.

The recording disc D has a central hole 1, and a spiral recording track T is formed on the surface of which is wound several times. An example of the width of the recording track T is 0.95 mm, and adjacent recording tracks are in contact with each other (there may be a gap therebetween, of course). For convenience of explanation, the radial direction R and the circumferential direction of the recording disc D are θ. The recording disk has a syringe lock of signals in the width direction of the recording track T, that is, in the radial direction R of the recording disk.

In Fig. 2, this recording track T is enlarged and displayed. In addition, T and T "represent recording tracks adjacent to the recording tracks T. Since their detailed structures are the same, the drawings are omitted.

The syringe lock is formed by arranging a plurality of spherical convex portions in a row on each one scanning line (radial direction R) and changing the position or length (scanning direction) of the convex portion in the scanning line direction.

The width (for example 1 mu in the direction orthogonal to the scanning direction) and the depth (for example 1 mu) of this groove are substantially constant at the same time.

In this example, the pulse pulse phase modulated signal of the video signal, the rear pilot signal, and the pulse width modulated signal of the audio signal are recorded in the recording track T of the recording disc D. That is, as shown in FIG. 2, the pilot signal recording unit n ₁ , the video signal recording unit m, the reference pilot signal recording unit n _2, and the audio signal recording unit are all directed from the left side to the right side of the drawing on a single scanning line (radius R direction) as shown in FIG. The recording width and recording position of each recording unit are the same on each scanning line parallel to the extending direction of the recording track T.

Each section of the recording track T is enlarged and displayed again in FIG. 3 and FIG. 4 and FIG. 5, where A in the drawings is a plan view, and B in the drawings is a partial sectional view. 3 shows a part of the pilot recording signals n ₁ and n ₂ at the front and rear of the recording track T. FIG. 4 shows a part of the video signal recording unit m. 5 shows a part of the audio signal recording section a. In FIG. 3, the length h _l of the length equal to the scanning direction, i.e., the length of the radial direction θ of the recording disc D, is arranged at equal intervals in parallel to the extending direction of the recording track T, that is, the circumferential direction θ of the recording disc D. Side by side to achieve. In Fig. 4, the position is inclined in the radial direction R by the level of each part of the video signal in each row in the column of the same length as in the case of Fig. 3 and in the circumferential direction?.

FIG. 5, the third, the fourth-degree groove h ₁ than the relatively long length of each part by the level of the audio signal is different for each scanning line direction circumferential groove h ₂ θ has been disposed one line.

Referring again to FIG. 2, the width of the recording track T corresponds to one horizontal period (= 1H) of the NTSC system television signal St, and the video signal portion Sv corresponds to the video signal recording portion m of the recording track T. FIG. The pilot signal portion n ₁ of the recording track T corresponds to the far end of the back signal of the television signal ST, and the rear pilot signal recorder n ₂ corresponds to the middle portion of the horizontal synchronization signal SH at the front porch, and the middle of the horizontal synchronization signal SH is The sound transmission signal recording section a corresponds to the first portion of the back porch from the.

A video signal recording unit and m is the column h ₁凹portion of the video signal, so as the carrier signal of about 4MHz halttaeneun record pulse phase modulation in which blood pulse phase modulated signal is one horizontal interval 63.5μsec circumferential direction θ is the 254 line is blossomed . In FIG. ₂ , f ₁ , f ₂ , f ₃ , and f ₄ represent scan line groups corresponding to the radix and even field of the NTSC television signal, and F ₁ , F ₂ are the odd feed f ₁ , A scanning line group corresponding to a frame composed of f ₂ and even-numbered f ₂ , f ₄ is shown, and the number of scanning lines is 525.

Therefore, the track length for recording signals for one frame should be about 0.53 mm if the width of the ridge is 1 mu.

In such a recording disk D, the one having a diameter of 30 cm enables video signal recording and reproducing for an hour or more.

The adjacent scan line indicated in FIG. 4 may be arranged such that the pulse phase modulated video signal forms 254 consecutive sub-columns.

When such continuous pulse lines are formed, the tracking at the time of reproduction is not necessary for the scan in the width direction of the recording track.

Such signal recording in the recording disc D may be directly performed on the material recording disc. However, since it is not mass-produced, it is better to make a recording disc (stamper) in advance and duplicate a plurality of recording discs D from the recording disc. . This recording disc creation method is described in FIG. 6 shows one surface of the photoresist layer 5 on the locker layer 4 of the locker disk 2 having the locker layer 4 on the aluminum substrate 3 as shown in FIG. To adhere to the formation. Next, as shown in FIG. 6C, the photoresist layer 5 is light-emitted in a predetermined pattern with a light beam such as leisure light or electron beam as described later. The developed photoresist layer 5 is subjected to development to obtain a cured photoresist layer 5 having a plurality of grooves, such as a pattern of recording track T, to be obtained as shown in FIG. have. On this photoresist layer 5, a metal mech layer having a predetermined thickness is formed. When the rocker disc 2 of FIG. 6d is peeled from this metal mech layer, the stamper 6 as shown in FIG. 6e is obtained.

A large number of recording discs D can be made by heat-pressing a recording disc such as vinyl chloride to this stamper 6 and mirror-finished as described above.

Next, with reference to the recording apparatus of FIG. 7, the light emitting method according to the signal to be recorded on the photoresist layer 5 of the rocker master 2 in the process of FIG. Recording method). In Fig. 7 (2) is the rocker disc, which is placed on the turntable (8). (9) is a cathode ray gun which generates an electron beam for luminescing the photoresist layer (5) of the rocker disc (2), (10) records this electron beam on the rocker disc (2) Deflection coil for deflecting by the width of the track (for example 0.95 mm). The signal recording by the light emission of the rocker layer 2 of the locker disc 2 forms a spiral recording track from the outer circumference to the inner circumference and at the same time makes the recording speed in the extending direction of the recording track constant. To this end, the cathode gun 9 and the deflection coil 10 are fixed, and the turntable 8 is gradually moved in the direction of the arrow 12 in the state shown in the drawing, and at the same time, the rotation speed of the turntable 8 is coexisted with the movement. You need to speed up slowly. Referring to the driving means 13 of the turntable 8 for this purpose, the tire 14 is brought into contact with the rear surface of the turntable 8 and the tire 14 is driven by the motor 15 at a constant speed (eg, a line). Speed is 15mm / sec).

On the other hand, the turntable 8 is attached to the moving body 16 with the roller 16a so as to be freely rotated by the shaft 8a. A worm is made in the shaft 8a of the turntable 8, and a worm gear 18 that is matched with the worm is provided, and the worm gear 18 is screwed into the toothed screw 19. The toothed screw 19 is normally fixed, but is rotated by the motor 20 when the turntable 8 is returned to its original position. In this turntable driving means 13, the tire 14 is rotated by the motor 15, whereby the turntable 8 is rotated. Due to the rotation of the turntable 8, the worm wheel 18 is rotated so that the moving body 16 moves in the direction of the arrow 12 together with the turntable 8.

Further, as the turntable 8 moves in the direction of the arrow 12, the rotation speed of the turntable 8 gradually increases to increase. The range of the rotational speed is 1.03-3.0R in the case of a locker disc of 30 cm in diameter (but can be used for recording up to 10 cm in inner circumference). P. M. In other words, the recording speed in the extending direction of the recording track is constant. Further, when the turntable 8 moves in the direction of the arrow 12 and the light recording of the rocker disc 2 by the electron beam is completed, the feeder screw 19 is rotated by the motor 20 to rotate the upper body 16. With the turntable 8, it moves quickly in the opposite direction to the arrow 12. At this time, the tire 14 is removed from the turntable 8.

Next, a description will be given of a recording circuit system required for recording a signal in the rocker layer of the rocker master 2, and in FIG. 7, reference numeral 22 denotes this recording circuit system, and reference numeral 22a denotes a video signal. Denotes the audio signal recording circuit system. First, when the video signal recording circuit system 22a is described, tv is a composite video signal to be recorded (the input terminal of the television signal, and the composite video signal supplied to the input terminal tv is supplied to the synchronization signal removing circuit 25. The horizontal synchronizing signal, the front porch and the back porch are removed so that only the feed video signal is taken out and supplied to the pulse modulation circuit 26. In this case, the pulse modulation circuit 26 is a pulse phase modulation circuit. Reference numeral 27 denotes a carrier oscillator for supplying a carrier signal to the pulse modulation circuit 26, and a pulse oscillator with an oscillation frequency of 4 MHz in consideration of the bandwidth of the video signal. It is locked by the horizontal synchronizing signal separated from the video signal by the synchronizing signal separation circuit 28. From this pulse modulation circuit 26, the carrier oscillator 27 is as shown in FIG. The rear pilot signals Sn ₁ and Sn ₂ are obtained every one horizontal period (= 1H).

Next, with reference to the audio signal recording circuit system 22b, ta is an audio signal input terminal, to which an audio signal associated with the video signal is supplied, and this audio signal is supplied to the gate circuit 30 to supply the video signal. It is sampled with the horizontal frequency of. Numeral 31 denotes a circuit for forming the gate circuit for controlling the gate circuit 30, in which a horizontal synchronization signal separated from the composite video signal has a predetermined phase thereto and a gate signal for each predetermined time width is generated. The audio signal sampled by the gate circuit 30 is supplied to the pulse modulation circuit 33. The audio signal band of the pulse width modulation circuit output from the pulse modulation circuit 33 is about 7.5KH. This pulse modulation circuit 33 is a pulse width modulation circuit.

Reference numeral 34 denotes a carrier oscillator for supplying a carrier signal to the pulse modulation circuit 33, which is a pulse oscillator having an oscillation frequency of horizontal frequency (= 15.75 KHz). The carrier oscillator 34 is locked by a horizontal synchronization signal separated from the composite video signal.

The outputs of both pulse modulation circuits 26, 33 are supplied to the switching circuit (or addition circuit) 35, and the output thereof is supplied to the cathode sun 9.

The signals supplied to the cathode light 9 are all pilot signal Sn ₁ , the pulsed phase modulated signal Sm of the video signal, the rear pilot signal Sn, and the audio signal within the one horizontal period (= 1H) as shown in FIG. 8. A continuous portion of a signal consisting of the pulse width modulated signal Sa (in this case, 1H minute) is obtained. The electron beam is modulated by the signal supplied to the cathode ray 9.

Next, with reference to FIG. 9, the recording apparatus in the case where the rocker disc 2 is illuminated by the light beam, in particular the leisure light, will be described with reference to FIG. 9. Most of the recording circuits 22 of FIG. Parts corresponding to 7 degrees are denoted by the same reference symbols and redundant descriptions are omitted.

개로 이 경우의 광비임 주사원반(39)의 회전수는 5,400R. P. M인 것이다. 이 광비임 주사원반(39)은 유리원반 비스마스의 엷은 증착막을 피착한 것을 모우터(40)에 부착하고, 레이저광의 펄스가공에 의해서 소공(42)이 천설되어 있다.Numeral 37 denotes a laser oscillator, in which the laser light is switched by the optical modulator (by a crystallite or the like) 38 by the recording circuit system 22. The optical signal is modulated by the output signal of (35), and the optically modulated laser light is converted by the optical beam scanning disk 39 into an optical beam which is deflected on the lacquer disk 2 by the width of the recording track. By the beam, the lacquer layer of the lacquer disk 2 is polished. The optical beam scanning disk 39 is a disk having a plurality of small pores 42 arranged at equal intervals on the circumference (a center of rotation and concentricity) as shown in FIG. By rotating at a constant speed. The pitch from the small holes 42 of the optical beam scanning disk 39 is approximately equal to the width of the recording track, and its diameter is about 1.5 mu. The number of the small holes 42 is the number of an integer number of 525 of the NTSC-type television signal horizontal scan line, for example.

In this case, the rotation speed of the optical beam scanning disk 39 is 5,400 RPM. The light beam scanning disk 39 is attached to the motor 40 by depositing a thin vapor deposition film of a glass disk, and a small hole 42 is laid by pulse processing of laser light.

Next, a method of reproducing the recording medium, that is, the recording disc, recorded as described above will be described.

11 shows an example of a playback apparatus. In this reproducing apparatus, the recording track T of the recording disc D is scanned in the width direction, that is, in the radial direction R by a light beam, for example, a laser beam, to optically detect the ridges h ₁ and h ₂ .

Reference numeral 45 is a turntable, on which the recording disc D is placed and rotated. Reference numeral 46 denotes a motor 47 which rotates and drives the turntable 45, a capstan attached to a pulley of the motor 46, and the capstan 47 is a turntable. It is indirectly connected to the rim of 45). Reference numeral 48 denotes a servo circuit 49 for controlling the rotation of the motor 46, which is a reference signal oscillator for supplying a reference signal to the servo circuit 48.

Numeral 51 denotes a laser oscillator from which an optical beam, that is, a laser beam, is converted into an optical beam deflected by the optical beam scanning disk d by the optical beam scanning disk d to the extent of the recording track T. Through the 53 and the lens 54, the recording track T of the recording disc D is scanned in the width direction and irradiated.

Reference numeral 56 denotes an optical sensor for detecting the reflected light of the recording disk D of the light beam through the half mirror 53. FIG. 12 shows, in plan view, the recording disk D and the light beam scanning disk d opposed thereto.

In Fig. 13, the light beam scanning disk d is enlarged, and in Fig. 14, the light beam scanning disk d is arranged in a number of small holes P ₀ , P ₁ , P ₂ arranged at equal intervals on the circumference of the center of rotation and concentricity. ,… … It is a disk having a shape, and is rotated constantly by the motor 57.

개로 이 경우의 광비임 주사원반 d의 회전수는 5,400 R. P. M이다.Small pores P ₀ , P ₁ , P ₂ ,... … The pitch of the back is approximately equal to the width of the recording track T, and its diameter is, for example, about 1-1.5 mu. These small pores P ₀ , P ₁ , P ₂ ,. … Is the number of integer quartiles of 525 lines of the horizontal scanning line of the NTSC system television signal.

In this case, the rotation speed of the optical beam scanning disk d is 5,400 RP M.

The diameter of the light beam scanning disk d is about 75 mm. Moreover, the outer diameter of the light beam scanning disk d is preferable because the smaller one does not have the shaking due to the rotation (since the thickness is thin).

The optical beam scanning disk d is attached to the motor 57 by depositing a thin vapor deposition film of bismuth on a glass disk, and forms small pores P ₀ , P ₁ , P ₂ ,... By pulse processing of laser light. … Become a legend.

The laser beam irradiated from the laser oscillator 51 to the optical beam scanning disk d has a length e _{1 in} the circumferential direction of the optical beam scanning disk d when the magnification of the lens 54 is 1 as shown in g of FIG. becomes equal to the width of the radial e ₂ are small hole _{P 0, P 1, P 2} , the width of the recording track ... … It is a light beam that has a slightly larger cross section than.

The laser oscillator 51, the optical capacitor 52, the half mirror 53, the lens 54, the detector 56, and the motor 57 are integrally driven to move toward the center from the outer periphery of the recording disc D. (The drawing about the driving means is omitted).

The optical beam scans the recording track T of the recording disc D so that the linear velocity in the extending direction becomes constant. Therefore, the turntable 45 rotates as the light beam moves from the outer periphery on the recording disc D to the inner circumference. The speed is set to fast.

According to an embodiment of the present invention, the number of revolutions of the turntable 45 is about 0.53 mm because the track distance required to record a video signal of one frame when the light beam is scanning its main part (about 30 cm in diameter) is The main part can record about 1,750 frames, and the frame period is 1 / 30sec, and the rotation speed is about 1R. It becomes P. M.

In this way, when the inner peripheral part (about 10 cm in diameter) is injected, it is about 3.0 R. It becomes P. M.

In this reproducing apparatus, the heat from the holes h ₁ and h ₂ on the scanning line with the recording track T of the recording disk D is scanned by the light beam coming from the small hole P ₀ of the optical beam scanning disk d, and the light from the next small hole P ₁ is scanned. The beam is configured to scan the rows of ridges, h ₁ and h ₂ on the next scan line of the recording track T. In this case, for example, on the surface (mirror surface) of the _recording source D, the light beam is configured to connect the focal points and the focal points on the bottoms of the recesses h ₁ and h ₂ .

For this reason, reflected light is obtained only when this light beam irradiates the surface of the recording disc D, and this is detected by the light sensor 56 by opening the half mirror 53. Then, from the light sensor 56, a reproduction signal of the signal recorded on the recording track T of the recording disc D is obtained, which is supplied to the video signal demodulation circuit 59 and the audio signal demodulation circuit 60 so as to output the respective output terminals ( Video signals and audio signals demodulated respectively at 59a) and 60a are obtained.

In addition, the specific structure of these demodulation circuits 59 and 60 is mentioned later. In addition, part of the output of the video signal demodulation circuit 59 is supplied to the synchronous separation circuit 62 so that the vertical synchronization signal is separated and supplied to the sub circuit 48 so that the reference signal from the reference signal oscillator 49 can be obtained. And a servo is formed so that the linear velocity is constant so that the signal reproduction and the rotation of the recording disc D are synchronized.

Next, referring to FIG. 15, the video signal demodulation circuit 59 will be described as an input terminal, and as described above, the same signal as in FIG. 8 is supplied to the limiter circuit 65. As shown in FIG. And the detection circuit 66 are supplied. The detection circuit 66 is an envelope detection circuit consisting of a diode and a band pass filter, and the output of the detection circuit 66 is supplied to the waveform shaping circuit 67 to be waveform shaped to obtain a horizontal synchronous signal.

The outputs of the limiter circuit 65 are respectively supplied to the gate circuits 69 and 70 for emitting the pilot signal Sn ₁ and the rear pilot signal Sn ₂ , respectively.

The gate signals supplied to these gate circuits 69 and 70 are made by the gate signal generation circuit 71 by the obtained horizontal synchronization signal. Reference numeral 73 denotes a synchronous detection circuit to which the output of the limiter circuit 65 is supplied so that the video signal is detected. However, the carrier signal of the pulsed phase modulated signal Sm of the video signal used for the detection is made by the following method. will be.

That is, the variable frequency oscillator 75 is provided so that all the pilot signals Sn ₁ obtained from the gate circuit 69 are supplied to the variable frequency oscillator 75 so that the oscillator output is forcibly locked in the phase of all the pilot signals (especially injector lock). Will be

However, the phase is out of phase while scanning. That is, since the frequency is not determined, the phase comparator 76 is set again so that in the phase comparator 76, the output of the variable frequency oscillator 75 and the output of the gate circuit 70, the rear pilot signal Sn _2, are mutually different. The phase is compared, the comparison output is supplied to the variable frequency oscillator 75, and frequency control of the variable frequency oscillator 75 is performed.

Then, the output of the variable frequency oscillator 75 is supplied to the synchronous detection circuit 73 through the phase shifter 77 having a 90 ° angle.

The phase-detected video signal that is the output of the synchronous detection circuit 73 is supplied to the addition circuit 79 through the low pass filter 78, and the horizontal synchronous signal from the waveform shaping circuit 67 is added thereto. Thus, the composite video signal is obtained at the output terminal 59a.

According to this construction method, since all phases are controlled by the pilot and frequency is controlled by the rear pilot signal, the initial phase of the carrier signal from the variable frequency oscillator 75 may be changed even if the pore spacing provided in the scanning disk is slightly different. The over-generated frequency can be combined with the delivery (carrier) signal of the pulsed phase modulated signal, thereby providing accurate synchronization detection.

Next, the voice signal demodulation circuit 60 will be described with reference to FIG. 60b is an input terminal, to which a signal as in FIG. 8 described above is supplied, which is supplied to a gate circuit 81 which emits a pulse width modulated signal Sa of an audio signal.

The signal supplied to this gate circuit 81 is produced by the horizontal synchronizing signal from the waveform circuit 67 of FIG. 13 in the gate signal forming circuit 82. As shown in FIG. 60c is an input terminal of the horizontal synchronization signal. The output of the gate circuit 81 is supplied to the demodulation circuit 84 through the waveform shaping circuit 83.

This demodulation circuit 84 is a pulse demodulation circuit. The demodulated audio signal obtained at the output side of the demodulation circuit 84 is obtained at the output terminal through the low pass filter 85.

Next, a description will be given of modifications of the above-described parts of the information signal recording and reproducing system, which are not formed on the recording track T spiral of the recording disk D but as a plurality of concentric circles.

Of the signals recorded on the recording disk D, both the front and rear pilot signals are irrelevant.

The video signal recorded on the recording disc D may be a pulse width modulated signal thereof. However, the pulsed phase modulated signal method is well suited for wideband transmission. In the reproducing apparatus of FIG. 11, if the incident angle of the light beam scanning to the recording disc D is set to 90 ° and the half mirror 53 is not provided on the path of the incident light, the incident light can be effectively used for scanning the recording disc D. have. When the deformation of the light beam scanning disk is explained with reference to FIG. 17, it can be seen that in this example, the light beam scanning disk d is provided with the lens 54 in FIG.

That is, the lens 91 is integrally formed or formed separately on one surface of the transparent disk 90 such as glass, and the light shielding layer 92 is formed on the other surface at the same time and at the position corresponding to the lens 91 of the secondary light shielding layer. Small pores 93 are formed. Thus, these pores 93 and the lens 91 are formed in each of the pores P ₀ , P ₁ , P ₂ ,... … Arranged in response.

To make the optical beam scanning disc d of FIG. 17, it is as follows. In other words, the transparent disk 90 having the lens 91 formed thereon deposits a photosensitive film on the other surface, and rotates the transparent disk 90 at a constant rotational speed so that light from the pin hole by the optical processing apparatus is transferred to the lens 91. Projection exposure is carried out on the corresponding photoresist film, and then the photoresist film is inverted to form a light shielding layer 92 having small pores 93. In this case, even if the position of the transparent disc 90 of the lens 91 is slightly incorrect, the position of the small holes 93 formed in the light shielding layer 92 can be easily adjusted to the position of the lens 91.

In addition, the optical system also becomes simple (that is, since a relay lens or the like is not necessary) and the small holes 93 of the light shielding layer 92 need not be made too small (for example, a diameter of 5 mu), so that the laser beams are disposed in the small holes 93. The loss due to diffraction also decreases.

The above-mentioned optical beam scanning disk d is for reproducing the video signal recorded on the recording disk D as it is. The optical beam scanning disk to reproduce the video signal as a still image will be described with reference to FIGS. 18 and 19. FIG. . d 'denotes this optical beam scanning disk and includes pores P ₀ , P ₁ , P ₂ ,. … In Fig. 13, the optical beam scanning disk d is the same as the small hole (so that the general reproduction of the video signal is possible), but the small holes P ₀ , P ₁ , P ₂ ,. … On the inner side of the circumference of the pores on the surface of the pores also P ₀ ', P ₁ ', P ₂ ',… … Is installed.

These pores P ₀ ', P ₁ ', P ₂ ',... … The pitches of are all approximately equal to the width of the recording track T of the recording disc D. These pores P ₀ ', P ₁ ', P ₂ ',... … The number of frames is equal to the number of 525 scan lines per frame of NTSC television signal. When the still image is reproduced, the turntable 45 on which the recording disc D is placed is placed in a stationary state, but the optical beam scanning disc d 'is rotated at a rotation speed of 1,800 RPM. In addition, the laser beam from the laser oscillator 51. In this case, the 19 degrees and the light beam scanning the disc d 'length in the circumferential direction e ₁ is equal to the width of the recording track T width e ₂ in the radial direction of the steps in Pore P ₀ ′, P ₁ ′, P ₂ ′,... … A cross section of the smallest size that can cover all of the is sufficient.

In the case of still picture reproduction, the structure of the reproduction device or the like is the same as that of the normal reproduction described above. According to the present invention, a spiral or circular recording track is formed on the recording disc, and the time-side modulated signal of the information signal to be recorded is injected into the recording track by one division and interlocked in the direction intersecting the extension direction. It is possible to record the information signal of the video signal at a high recording density on the disc, and at the same time, to lower the recording disc rotation speed and to facilitate the recording disc rotation control and the reproduction tracking control during reproduction. In the above example, in the case where the recording pattern is formed as a recording pattern for the recording disc, various patterns such as different mechanical shapes, magnetization patterns, electrostatic patterns, optical shade patterns, capacitance patterns, and the like are possible.

The time-side modulated signal of the information signal can be any of a variety of pulsed modulated signals or other modulated signals. In addition, the direction of the syringe lock is possible not only in the width direction of the recording track but also in the direction crossing the extending direction. The information signals recorded on the recording disc are not limited to video signals, but various information signals such as audio signals and data signals can be used.

Claims (1)

As shown in the drawing and described in the main text, a spiral or circular recording track is formed on the recording disc, and the information signal to be recorded is temporally modulated and scanned one by one in a direction crossing the recording track with respect to its extension direction. An information signal recording method characterized by recording.

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